IC9H ^HGkBfi He flffl BH9H V IB LIBRARY Brigham Young University COLLECTION on GEOLOGY and ENGINEERING FROM Dr. Albert Clarence Boyle, Jr. acc. 156654 NO. ±M<, ft; v* -x / Digitized by the Internet Archive in 2012 with funding from Brigham Young University http://archive.org/details/geologyoredeposi6667rans V* QE 75 .P76X DEPARTMENT OF THE INTERIOR UNITED STATES GEOLOGICAL SURVEY GEORGE OTIS SMITH, Director Professional Paper 66 THE GEOLOGY AND ORE DEPOSITS OF GOLDFIELD, NEVADA 156654 BY FREDERICK LESLIE RANSOME ASSISTED IN THE FIELD BY W. H. EMMONS and G. H. GARREY WASHINGTON GOVERNMENT PRINTING OFFICE 1009 CONTENTS. Page. Chapter I. — Introduction 13 Field work and acknowledgments 13 Situation of the district 14 Topography 14 History of mining 16 Production 23 Literature 24 Geographic names 26 Chapter II. — Preliminary outline of the geology and ore deposits 27 Chapter III. — Description of the pre-Tertiary rocks 32 Cambrian shale 32 Alaskite and granite 33 Definition 33 Distribution 33 Petrography 33 Geologic relations 34 Age :.. 35 Chapter IV. — Description of the prelacustrine Tertiary igneous rocks 36 Introduction 36 Vindicator rhyolite 37 General character and occurrence 37 Petrography 38 Latite 38 General character and occurrence 38 Petrography 39 Kendall tuff 41 Sandstorm rhyolite 43 General character and occurrence : 43 Petrography , • 44 Morena rhyolite 46 General character and occurrence 46 Petrography .. 46 Milltown andesite 47 Introductory statement 47 Distribution 47 Petrography 47 General character of the formation 47 Hornblende-pyroxene andesite 48 Pyroxene andesite 52 Hornblende-biotite andesite 52 Tuff 53 Basalt 54 Geologic relations 54 Dacite 54 Introductory statement 54 Distribution 55 Petrography 55 Geologic relations 58 Dacite vitrophyre 61 General character and occurrence 61 Petrography 61 Relation to the dacite : 63 3 4 CONTENTS. Chapter IV. — Description of the prelaeustrine Tertiary igneous rocks — Continued. Page. Chispa andesite 64 General character and occurrence , 04 Petrography 64 Andesite dikes 65 Meda rhyolite 65 General character and occurrence 65 Petrography 65 Andesite breccia 65 Chapter V. — Rocks of the lake epoch 66 Introduction 66 Siebert formation 66 Distribution 66 Lithology 66 Thickness 68 Conditions of deposition 68 Stratigraphy 68 Mira basalt 69 Occurrence 69 Petrography 69 Espina breccia 69 Chapter VI. — Postlacustrine Tertiary rocks 70 Introductory statement 70 Pozo formation 70 Spearhead rhyolite 71 Rabbit Spring formation 71 Malpais basalt 72 Chapter VII. — Quaternary deposits 75 Chapter VIII. — Geologic structure 76 Chapter IX. — Geologic history and correlation 86 Introduction 86 Local geologic history 86 Before Tertiary time 86 Tertiary prelaeustrine epoch 88 Lacustrine epoch 89 Postlacustrine history 89 Correlation of the Goldfield rocks with those of the surrounding region 91 Introductory statement 91 Prelaeustrine rocks 92 Lacustrine sediments 95 Tertiary chronology of the western part of the Great Basin 101 The eruptive sequence 105 Tertiary climate 106 Chapter X. — Mineralogy of the district 108 Introduction 108 Notes on the more important minerals associated with the ore deposits 109 Sulphur 109 Gold 110 Copper Ill Bismuthinite '. Ill Galena 112 Sphalerite 112 Cinnabar 113 Chalcopyrite 113 Pyrite 113 Marcasite 114 Tellurides of gold 115 Proustite 116 Polybasite 116 Goldfieldite 116 Enargite 117 Famatinite 118 Cerargyrite 119 CONTENTS. 5 Chapter X. — Mineralogy of the district — Continued. Notes on the more important minerals associated with the ore deposits — Continued. Page, Quartz 120 Bismite 121 Tellurite 123 Massicot 123 Hematite 123 Rutile 124 Diaspore 124 Limonite 125 Calcite 126 Feldspars 126 Epidote 126 Muscovite 127 Kaolinite 127 Barite 127 Gypsum 128 Melanterite 128 Chalcanthite 129 Halotrichite 129 Alunite 129 Jarosite 133 Emmonsite and durdenite 133 Chapter XI. — The mines; a general account of their distribution, development, and operation, including ore treatment 135 Distribution and underground development 135 Mining costs 141 Power 142 Water supply 142 Treatment of the ores 143 Chapter XII.— The ledges 150 Definition 150 Distribution 150- Trend or strike 152 Dip 152: Shape 153 Material and minor structures 155 Chapter XIII.— The pay shoots and ores 158 Distribution 158 Relation to ledges 158 Shape 158 Relation to Assuring 160 Effects of faulting 161 Influence of country rock 163 Mineralogical and chemical character of the sulphide ores 165 Paragenesis 169 Mineralogical character of the oxidized ores • 170 Value of the ores 171 Areal variations in the ores 172 Observed changes in depth 173 Original depth of the ores now visible 174 Age of the deposits 175 Chapter XIV. — Metasomatic processes 176 Types of alteration 176 Comparison of fresh and altered dacite 176 Changes in other rocks 182 The ore-depositing solutions 185 Chapter XV. — Underground water and depth of oxidation 187 Chapter XVI. — Genesis of the deposits 189 Statement of the problem 189 The direct volcanic hypothesis 189 Hypothesis of derivation of the sulphuric acid from the oxidation of pyrite 191 Hypothesis of simultaneous solfatarism and oxidation 193 6 CONTENTS. Chapter XVI. — Genesis of the deposits — Continued. Page. Stages of deposition 195 Summary of genesis 196 Ultimate source of the ore-bearing solutions 197 Present absence of volcanic activity 198 Goldfield type of deposit 199 Chapter. XVII. — Practical conclusions 200 Chapter XVIII. — Detailed descriptions of the mines of the Goldfield Consolidated Mines Company 202 Introduction 202 Red Top mine 202 History 202 Underground workings 202 Geologic relations 203 The ledge 203 The pay shoots 204 Mohawk mine 204 Introduction 204 Underground workings 205 Geologic relations 206 Form and distribution of the ledges 207 Form and distribution of the pay shoots 208 Combination mine 209 History and production 209 Underground workings , 210 Geologic relations 211 Form and distribution of the ledges 211 Material of the ledges 213 Form and distribution of the pay shoots 213 Character of ore 214 Underground water 216 January mine 216 History 216 Underground workings 217 Geologic relations 217 Form of the ledge 217 Material of the ledge 218 Form and distribution of the ore bodies 218 Character of the ore 219 Underground water 220 Jumbo mine 220 History 220 Underground workings 221 The ledge 221 The pay shoots 221 Character of ore ". 222 Mines and prospects operated by lessees 222 Introduction 222 Five Friends lease 222 Mushett lease 223 Mohawk-Red Top lease 224 Consolidated Red Top lease 224 Hazel-Goldfield lease : 224 Other leases 224 Chapter XIX. — Detailed descriptions of the mines of the Florence-Goldfield Mining Company 225 Introduction 225 Florence mine 225 1 1 istory 225 Underground workings 226 Geologic relations 226 Form of the Florence ledge 227 The pay shoots 228 Character of the ore 229 Underground water , 230 CONTENTS. 7 Chapter XIX. — Detailed description of the mines of the Florence-Gold field Mining Company — Continued. Page. Mines operated by lessees 230 Reilly lease 230 Engineers' lease 232 Little Florence lease 233 Rogers Syndicate lease 233 Other leases 234 Chapter XX. — Detailed descriptions of the lesser mines and prospects of the Goldfield group 235 Sandstorm mine 235 Kendall mine 237 Conqueror mine 238 Adams mine , 239 Kewanas mine 239 Goldfield Merger Company's mines 239 Introduction 239 St. Ives mine 240 Codd lease 241 Velvet mine 241 Jumbo-Extension Mining Company's Gold Wedge claim 241 Combination Fraction mines 241 Atlanta group 242 Gold Bar and Victor mines : 242 Blue Bull mine 243 Simmerone mine 244 Lone Star group 244 Commonwealth mine 245 Portland mine 245 Other prospects 245 Chapter XXI. — Detailed descriptions of mines of the Diamondfield group 246 Diamondfield Black Butte Consolidated mine 246 Goldfield-Belmont mine 247 Daisy mine 248 Jumbo Extension (Gold Coin) mine 250 Triangle mine 251 Great Bend mine 251 Index 253 ILLUSTRATIONS. PLATES. Page. Plate I. Topographic map of the Goldfield district In pocket. II. Geologic map of the Goldfield district In pocket. III. Goldfield topography: A, Goldfield; B, Black Butte....: 16 IV. Geologic reconnaissance map of the region adjacent to Goldfield 32 V. A, Columbia Mountain; B, Cambrian shale cut by alaskite, south slope of Columbia Mountain 34 VI. A, Intrusive contact between Morena rhyolite and Cambrian shale, west slope of Columbia Mountain; B, Goldfield 46 VII. Photomicrographs of volcanic rocks 62 VIII. Geologic sections across the Goldfield district 76 IX. Combined plan of the underground workings of the principal mines near Goldfield 136 X. Map showing principal lease blocks in the vicinity of Goldfield 136 XI. A, Malpais Mesa; B, Florence Hill 136 XII. A, View northwest from Florence Hill; B, View east from Florence Hill 136 XIII. A, Sandstorm and Kendall mines; B, View from Morena Ridge eastward to Diamondfield and Black Butte 138 XIV. A, Ledge outcrops in Milltown andesite about 2 miles east of Goldfield; B, Ledge outcrop in dacite between the Blue Bull and Commonwealth mines 150 XV. A, Ledge outcrops east of Black Cap Mountain; B, Ledge outcrops in latite on Banner Mountain 152 XVI. Plans of the principal levels of the January mine, with a diagrammatic section showing relations of ore, ledge matter, and country rock 152 XVII. Sections across the Combination ledge on lines shown on Plate XXXI V 154 XVIII. Plans of levels of the Combination mine 154 XIX. A, Dacitic ledges on ridge near the Commonwealth mine; B, Dacitic ledge near the Blue Bull mine. 156 XX. Ledge structure: A, Veinlets of compact quartz and kaolinite in altered andesite, Goldfield-Belmont mine; B, Sheeted dacite and low-grade ore, Jumbo mine 156 XXI. A, Part of the Sweeney stope in the Florence mine; B, The Hayes-Monnette stope in 1906 160 XXII. A, The "glory hole" of the Combination mine; B, Ledge matter on the 150-foot level of the Florence mine 160 XXIII. Ore structures 164 XXIV. Ore structures 164 XXV. Ore structures 166 XXVI. Photomicrographs of ores 168 XXVII. Photomicrographs of ores 168 XXVIII. Photomicrographs of alunitized rocks 178 XXIX. Photomicrographs showing alteration of dacite 178 XXX. Photomicrographs illustrating alteration of rocks 178 XXXI. Photomicrograph of alunitized rhyolite 184 XXXII. Plan and section of the Red Top mine 202 XXXIII. Plan of the Mohawk mine, showing also the workings of lessees on the Gold Wedge claim 206 XXXIV. Plan of the Combination mine, including the productive part of the January mine 210 XXXV. Plan of the Florence mine, showing also some of the adjacent workings of lessee companies 226 9 FIGURES. Page. Figure 1. Index map showing the position of the Goldfield district 15 2. Plan of the dacite mass near Goldfield 80 3. Section across the Columbia Mountain fault at the Conqueror mine 82 4. Generalized columnar section of the rocks of the Goldfield district 90 5. Columnar section of rocks of southwestern Nevada and eastern California 91 6. Succession of lavas in the Great Basin and at Goldfield 106 7. Characteristeric outlines of quartz phenocrysts in dacite 121 8. Crystal form of bismite from Goldfield 123 9. Spherules of hematite with crystal facets 124 10. Scheme of treatment in the Combination mill 144 11. Scheme of treatment in the new Goldfield Consolidated mill '. . . 147 12. Plan showing distribution of ledges east of Goldfield 151 13. Plan of ledge matter and pay shoots on the 100-foot level of the Florence mine 152 14. Vertical section through an irregular flat ledge in the west wall of the Black Butte tunnel 152 15. Sections across the Mohawk ledge on lines shown on Plate XXXIII 153 16. Sections across the Reilly pay shoot 154 17. Section across the Florence pay shoot near the main shaft 154 18. Plan of the 350-foot level of the Mohawk mine 162 19. Diagram showing the portions of the Goldfield district in which the rocks have undergone extensive alunitic alteration 177 20. Diagram illustrating gains and losses of each chemical constituent in terms of percentage of mass of original fresh dacite 181 21. Geologic plan of the 600-foot level of the Mohawk mine 206 22. Diagram showing relation of the Mohawk ledge to the dacite-latite contact 206 23. Plan of part of the 130-foot level of the Combination mine 211 24. Diagram showing possible plan of the combined January and Combination ledges 212 25. Sketch plan of the workings of the Five Friends lease 223 26. Plan of the workings of the Mushett lease 223 27. Sketch plan of the 420-foot level of the Mohawk Red Top lease 224 28. Diagrammatic section through the Florence mine 226 29. Section through the Kendall mine 237 30. Plan of the St. Ives mine 240 31. Plan of the Gold Bar and Victor mines 243 32. Plan of the workings of the Black Butte mine 246 33. Plan of the workings of the Goldfield-Belmont mine 248 34. Plan and longitudinal projection of the workings on the Daisy group 249 11 • THE GEOLOGY AND ORE DEPOSITS OF GOLDFIELD, NEVADA. By Frederick Leslie Ransome. CHAPTER I. INTRODUCTION. FIELD WORK AND ACKNOWLEDGMENTS. During the summer of 1905 a topographic map of the Goldfield district, on a scale of 2,000 feet to the inch (1:24000), and covering approximately 31 J square miles (82 square kilometers), was made by Mr. William Stranahan, topographer. With this map as a base, detailed geologic work was begun in September of the same year. Messrs. W. H. Emmons and G. H. Garrey assisted in the field work of the first season. In the main, the geologic mapping of that portion of the district lying in Nye County (see PI. II, in pocket) and extending from Blackcap Mountain to Black Butte is the work of Mr. Garrey. The part lying south of a line drawn from Blackcap Mountain to Goldfield and west of the Goldfield-Tonopah freight road (i. e., the southern and western borders of the area) was mapped principally by Mr. Emmons. The field notes of both geologists have been used whenever it was necessary to supplement my own observations with details observed by them in their respective divisions of the field. All the geologic mapping was done with traverse plane tables, each contact being followed and numerous points upon it determined by intersections. A preliminary report a on the district was issued early in 1907 and the greater part of the final report was finished by the end of the same year. The rapid development of the mines during 1906 and 1907, the large number of new ore bodies found, and the important discoveries made at depths not reached when the first field work was brought to a close, rendered it clear that the disadvantage of a few months delay in the publication of final results would be amply compensated for by a second visit to the field and by a study of underground workings opened since the close of the year 1905. Accordingly a supplementary investigation of the district was carried on from June 11 to July 27, 1908. It was found necessary, moreover, in consequence of the many modifications in the cultural features (changes in roads, additional shafts and buildings, etc.) to thoroughly revise the topographic map published in 1906. Mr. W. M. Beaman, topographer, was occupied with this revision during September, October, and part of November, 1908. The assistance rendered us in the course of our investigation by all interested in the develop- ment of the district was hearty and general. It is a pleasure to record gratefully the generous cooperation of Mr. H. P. Henderson, geologist for the Goldfield Consolidated Mining Company, and of our professional colleagues, the local mining engineers, particularly Messrs. E. A. Byler, George B. Church, F. A. Lucy, C. D. Wilkinson, A. E. Barnes, W. Stranahan, F. J. Siebert, and Charles J. Moore. Very helpful also was the active interest of the owners and superintendents of mines. a Ransome, F. L., Preliminary account of Goldfield, Bullfrog, and other mining districts in southern Nevada: Bull. U. S. Geol. Survey No. 303, 1907. 13 14 THE GEOLOGY AND ORE DEPOSITS OF GOLDFIELD, NEVADA. The various chemical tests and the analyses of minerals and rocks recorded in the following pages were made in the chemical laboratory of the Geological Survey by Messrs. George Steiger, W. T. Schaller, and Chase Palmer. A full and representative collection of the rocks and ores of the Goldfield district has been deposited in the National Museum, Washington, D. C., where it may be examined by anyone on application to the curator of geology. It is hoped that arrangements may be made whereby a smaller collection illustrative of this report may be placed on exhibition in Goldfield. All plans of mine workings and all plats of claims accompanying this report have been compiled from the maps of the various companies and are published with their permission. The standard of mine surveying at Goldfield is generally excellent and there is no reason for supposing that any of the maps here utilized are incorrect. The United States Geological Survey does not, however, vouch for their accuracy. SITUATION OF THE DISTRICT. The town of Goldfield, which, with the adjoining settlement of Columbia, has a population estimated at about 15,000, lies near the eastern border of Esmeralda County, in southwestern Nevada. (See fig. 1.) It is about 28 miles (45 kilometers) nearly due south of Tonopah and 7 miles (11 kilometers) a little north of east from the old mining camp of Montezuma. As may be seen from Plate I, the eastern part of the Goldfield district, including Black Butte, lies in Nye County. Three railroads of standard gage enter the district. A branch of the Southern Pacific leaves the main line at Hazen and connects at Mina with the Tonopah and Goldfield Railroad, which enters Goldfield on the north by way of Tonopah and Tonopah Junction. Through trains are run over this route from San Francisco to Goldfield. The Las Vegas and Tonopah Railroad leaves the San Pedro, Los Angeles and Salt Lake Railroad at Las Vegas, Nev., and passes through the Bullfrog district, 60 miles (96.5 kilometers) south-southeast of Goldfield. The Tonopah and Tidewater Railroad branches from the main line of the Santa Fe system at Ludlow, Cal., and reaches Goldfield by way of Death Valley and the Bullfrog district. The northern route affords communication with San Francisco, and particularly with the works of the Selby Smelting and Lead Company where a large part of the Goldfield ore has been treated. The two southern routes give access to Los Angeles and to the smelters of Utah. TOPOGRAPHY. The hills in the vicinity of Goldfield form an irregular group (see PI. I, in pocket), having no definite trend and belonging to no recognized mountain range. On the north, east, and south these hills slope down to broad, undrained sterile basins, each with its characteristic central -playa — a gleaming level plain incrusted with salts, except when an occasional shower has spread a film of water over its surface. The average altitude of the playa floors above sea level in this region is about 5,000 feet (1,524 meters). Such a basin, approximately 10 miles (16 kilometers) in width, separates the Goldfield Hills from Stonewall Mountain, a prominent landmark south- east of the district and visible in Plate XIV, A. A low, broad pass between this basin and one to the north of it connects the Goldfield Hills with the northwest end of the Cactus Range, Cactus Peak being 20 miles (32 kilometers) east-northeast from Goldfield. A similar incon- spicuous divide, about 12 miles (19 kilometers) north-northeast of Goldfield, forms a slight connection between the Goldfield Hills and the hills of the Southern Klondike and Tonopah districts. West of town a basaltic mesa (see PI. II), at this latitude about 4 miles (6.4 kilometers) wide, stretches to the eastern base of Montezuma Peak, which is composed in part of rocks similar to those of the Goldfield district. The old mining settlement of Montezuma lies near the summit of the peak, which is 8,426 feet (2,568 meters) in height and 7 miles (11 kilometers) a little south of west from Goldfield. TOPOGRAPHY. 15 Goldfielcl is situated on the southern rim of one of the typical desert basins of the region, which merges through a low pass 22 miles (35.4 kilometers) north of town into the still larger basin west of Tonopah. (See PI. IV.) This pass, through which the railroad runs from Tono- pah to Goldfield, is between the Lone Mountain Range on the west and the Tonopah Hills on the east. The portion of the Goldfield Hills, which is particularly described in the present paper and which will for convenience be hereafter referred to as the Goldfield district, is shown in the accompanying map (PI. I). The relief in this area ranges from 5,400 feet (1,646 meters) in its Figure 1.— Index map showing the position ot the Goldfield district. northwest corner to 6,635 feet (2,022 meters) on the summit of Preble Mountain, near the southeast corner. The culminating peak of the Goldfield Hills, however, known as Diamond Peak, is just east of the area represented in the map and attains an elevation of nearly 7,000 feet (2,133 meters). A large part of the district may be described as a rolling plateau (see Pis. Ill and VIII), ranging from 5,700 to 5,800 feet (1,737 to 1,768 meters) in general eleva- tion and surmounted by many irregularly distributed peaks and knobs, of which Preble, Black- cap, Vindicator, Banner, and Columbia mountains are conspicuous examples. Not any of these hills are volcanic craters or local volcanic upheavals, as has been asserted in some descriptions 16 THE GEOLOGY AND ORE DEPOSITS OF GOLDFIELD, NEVADA. of the district. They owe their height above the surrounding country merely to the fact that they are composed of material somewhat harder or more durable than the average rock of the region, and have thus succumbed more slowly to the general erosion that has carved the existing relief from a gently domed volcanic series. The superior resistance of the hills is in some cases due to the original character of the rock of which they are composed ; in other cases to a capping of young and fresh lava, but by far the greater number of the smaller knobs that stud the dis- trict, of which Black Butte, Plate III, B, .is an excellent example, are prominent because the rock has been hardened by intense local metamorphism in a manner that will be described in connection with the ore deposits. The fact that much of the district is a rolling plain diversified by rocky knobs has an important bearing in a region where detritus tends to accumulate on all but the steepest slopes. In the Tonopah district, and especially in the Bullfrog district, there is generally a fairly definite line between steep, bare, rocky hills and the. gentle alluvial slopes at their base. At Goldfield, however, the general gradients, as may be seen from Plate VIII, are so slight that detritus accumulates over much of the surface and interferes seriously with attempts to determine the distribution and structure of the underlying rocks. HISTORY OF MINING. At the beginning of the present decade the state of the mining industry in Nevada had so far declined as to appear but a feeble and flickering reminder of past splendor. The output of the great Comstock, a lode which in forty years had yielded about $400,000,000 in gold and silver, had dwindled in 1899 to the relatively paltry sum of $171,677.90; and the whole State in that year produced only $3,740,790 (with silver reckoned at coinage value), nearly half of this coming from Lincoln County, in which the Delamar mine was the only large producer. Eureka, Pioche, Eldorado Canyon, and many places of less note had apparently passed from activity into tradition. With the opening of the year 1900, however, there were signs that some of the older camps were preparing to shake off their dusty lethargy. On the Comstock, particularly, some prog- ress was made in freeing the deep levels from water and the production from this famous lode rose to $700,865. But the one event which transformed a gradual resuscitation of mining, the natural accompaniment of great national prosperity in all other branches of industry, into a movement almost explosive in its energy and suddenness, and resulted in the development of Goldfield, Bullfrog, Manhattan, Wonder, Fairview, and many other new fields, was the dis- covery, in 1900, of the Tonopah deposits by James L. Butler. In 1901 ore to the value of $576,145 was shipped from the Tonopah district, and prospectors were not slow in acting upon this striking demonstration of the fact that the State of Nevada, owing largely to its uncom- promisingly desert character, had hitherto been very inadequately prospected. From Tonopah as a base prospectors scattered over the desert, and as the size and richness of the new bonanzas became known the number of explorers increased. Many of these, as well as prospectors of an earlier generation, must have walked over the low hills which lie east of Montezuma Peak, 24 miles (38.6 kilometers) south of Tonopah. They could scarcely have failed to remark the dark siliceous outcrops, or combs, which are a notable feature of their topography and must have suspected the connection of these with ore deposition. How gold ore of such unprecedented richness, lying so close to the surface in a region of such obvious volcanic and chemical activity, escaped detection when work was in progress at the old camps of Montezuma, Lida, and Silver Peak, is difficult to comprehend. The explanation is probably to be found in the fact that the earlier prospectors were looking for quartz veins of the normal type, particularly for silver- bearing veins, and finding nothing of value in the projecting parts of some of these curious rusty "blowouts" concluded that all were barren and passed on to what seemed more promis- ing localities. The gold pan was not at that time a recognized part of the outfit of a Nevada prospector, and the first attempts to use it at Goldfield were not successful because the pioneers panned the hard quartz broken from the croppings instead of the soft disintegrated material which in this district generally contains the gold. U. S. GEOLOGICAL SURVEY PROFESSIONAL PAPER 66 PLATE III A. GOLDFIELD; FROM POINT NEAR THE OLD BLUE BULL SHAFT. Characteristic ledge outcrops in foreground ; Ma I pa is Mesa behind the town; Montezuma Peak beyond. Looking west. B. BLACK BUTTE; FROM POINT NEAR MCLAUGHLIN'S WELL. A typical knob of ledge matter rising above the general rolling surface. The white dump at the base of the butte marks the portal of the main tunnel. To the right of it, extending obliquely up the slope, are the cuts on the Flat vein. HISTORY OF MINING. 17 It was not until late in 1902 that "float" gold was found on Columbia Mountain by Harry Stimler and William Marsh. After seeking in vain for the source of this gold the two pros- pectors worked northward, and on December 2 of the same year located claims on and near the Sandstorm lode. A brief period of excitement followed their discovery, men thronging into the district on foot and in wagons and automobiles. No important ore bodies were immediately uncovered, however; interest flagged; and all but a few of the more determined or more sanguine prospectors left the district, then known as Grandpa. Stimler and Marsh's original locations appear to have lapsed, the ground being afterwards relocated by others. Among those who remained were A. D. Myers and R. C. Hart, who, on May 24, 1903, located the Combination lode. These two men had been "grubstaked" by eight others and were under contract with their backers to do the assessment work. The early locations south of Columbia Mountain were not based on direct discovery of ore, but were made with the view of securing claims as near as possible to the point at which gold was first found. They were originally speculative holdings merely. Hart soon sold his interest to T. D. Murphy, who, with Myers, began to develop their prop- erty. Their pertinacity was rewarded by the discovery of the Combination ore shoot, and to them and their associates undoubtedly belongs the credit of the real opening of the district. It was at this time (June, 1903) that J. E. Spurr, then studying the geology of Tonopah, paid a hasty visit to the district and published a brief note" on the geology, which was supplemented by a fuller statement6 made after a second visit in November, 1904. In October, 1903, after the existence of ore in the Combination ledge had been proved by a short tunnel, the ground was bonded to the Combination Mines Company for $5,000 in cash and $70,000 to be paid in later instalments. In the following December this company began the shipment of ore. Prospecting was actively resumed over the district in January and February of 1904, and before midsummer rich ore was being shipped from the Jumbo, Florence, and January mines: With the exception of the Combination, all the mines which have attained any importance were first opened and developed by the leasing system, and so near the surface and so rich were many of the ore bodies that numbers of the successful lesses made ample fortunes in a few months or even in a few weeks. The royalties exacted usually ranged from 20 to 30 per cent of the net value of the ore extracted. At one time there were six sets of lessees working through as many shafts on the Jumbo lode. The blocks were from 100 to 300 feet (30.5 to 91.4 meters) in length, the most productive and best known being that generally referred to as the Bowes- Kernick lease. The daily output from all of these workings in August, 1904, was estimated at $10,000, and the total to the expiration of the leases, early in 1905, amounted to considerably more than $1,000,000. Another famous lease was the Sweeney lease on the Florence mine, which expired on January 15, 1905, after a production amounting to $650,000. The Patrick lease on the January mine, probably the first important lease granted in the camp, produced about $500,000. Later, and in some respects more sensational than the leases just mentioned, was that granted to B. J. Reilly and associates on No. 1 block of the Florence ground. This lease, after having been successively abandoned by two earlier holders, was taken up by Reilly and his partners in April, 1905. Ore was found in the following June, but it was not until August that the true richness of the body became apparent. In the short time then available before the expiration of the term, on October 19, 1905, nearly all of the ore which the lease produced was mined and hoisted to the surface. The royalties paid to the Florence-Goldfield Mining Company represent a total output of $475,000. Most accounts, however, give the production as $750,000. Some of this ore was of extraordinary richness, a lot of about 4J tons,c taken out from the bottom of the workings during the last days of the lease, averaging, according to Mr. Frank Oliver, then superintendent of the Florence mine, between $6,000 and $7,000 per ton. a Bull. U. S. Geol. Survey No. 225, 1904, pp. 118-119. b Bull. U. S. Geol. Survey No. 2C0, 1905, pp. 132-139. c The tons referred to in this report are in every case "short tons ' ' of 2,000 pounds. Since the short ton is equivalent to approximately 0.9 metric ton, conversion to the metric units is in most cases unnecessary. 79145— No. 6G— 09 2 18 THE GEOLOGY AND ORE DEPOSITS OF GOLDFIELD, NEVADA. Early in 1905 the district probably contained fully 8,000 people, over two-thirds of whom were in the town of Goldfield. Late in the year, owing to the attractions of Manhattan and other recently opened camps and to a decreasing activity in prospecting, in leasing, and in the various more or less speculative transactions so characteristic of a new mining district, the population had somewhat declined. The completion of a railroad from Tonopah to Goldfield in September, 1905, gave the district a much-needed improvement in transportation, although freight charges were still maintained at unduly high figures. Another important event of the year was the discovery of a large body of rich ore in the Red Top mine, which had not previously been a productive property. On the whole, the year 1905 witnessed a slight ebb in the tide of prosperity, due to many causes. The rapid exhaustion of many of the rich shoots worked by lessees and the failure to immediately find other rich bodies at greater depth aroused forebodings which not even the record of the Reilly lease could allay. The Jumbo mine, after making fortunes for lessees, was involved in litigation and became temporarily unproductive. The bottom level of the Combination mine had been allowed to fill with water and the bottom level of the Florence mine revealed as yet no shipping ore. New camps, particularly Manhattan, were corning into prominence and were drawing men away from Goldfield, which under all these circumstances could not avoid some reaction from the buoyant optimism of the preceding year. The entrance of the Red Top mine into the rank of producers at the close of the year did much to restore confidence, although no one yet realized what extraordinary riches still lay concealed within 250 feet (76 meters) of the surface in the little area of about a quarter of a square mile (0.6 square kilometer) which contained the Red Top, Combination, January, Jumbo, and Florence mines. During the first quarter of 1906 no very important changes took place in the general situation at Goldfield. Several new ore bodies were found and the discovery of rich ore in the Sandstorm between the 100 and 150 foot levels proved encouraging in view of the shallow depth to which stoping had hitherto been restricted in this mine. The development of the Laguna mine, east of the Red Top, was begun, and a few tons of low-grade ore were found by lessees on the Mohawk claim. The various local mills and reduction works were in active operation, including a new Kinkead mill on Columbia Mountain. The Combination mill was working 20 stamps and installing tube mills. In June differences between the mine owners and the miners' union threatened to become acute, being complicated by the introduction into Goldfield of an organization of labor called the Industrial Workers of the World. The latter had declared a strike against the Western Union Telegraph Company which threatened to involve all the workmen in the district. A visit of Governor Sparks to Goldfield early in June, when he addressed the labor unions, appeared to avert the threatened trouble, but the spirit of unrest still smoldered. Ore was first discovered on the Hayes-Monnette lease of the Mohawk in April, 1906, at a depth of about 250 feet (76 meters). By the end of the first week in June nearly 2,500 tons of sulphide ore averaging 2.7 ounces of gold per ton had been shipped, and in the following month the Mohawk ground began to attract much attention and was actively worked by several sets of lessees. In the early days of the Hayes-Monnette lease considerable fruitless work had been done on the 150-foot level; and there, as later developments showed, the main drift missed the great ore shoot by a few feet only. In September the ore shoot, there very rich, was opened from that level, and this one lease block was soon shipping up to $60,000 worth of ore a day from two shafts. The original Hayes-Monnette lease covered an area 700 feet (213 meters) long by 373 feet (1 13 meters) wide. About two-thirds of this was sold to other lessees who met with less success than did the original holders on the retained third. On some of the Mohawk leases the miners were paid $5 for six-hour shifts. Mere wages in fact counted for little where the prime consideration on the part of the lessee was to raise as much rich ore as possible in a given time and where the obvious aim of many employees and others was to steal the greatest quantity possible. It is reported that miners in some cases refused $20 a day on development work in order to accept $5 a day with the opportunity HISTORY OF MINING. 19 for illegal perquisites in the Mohawk. The extent to which "highgrading," or the stealing of rich ore, went on in 1906 is almost incredible. Two shipments of stolen ore, valued at $60,000 and $150,000 were seized on the cars. Scores of so-called assay offices sprang up, the main business of which was the traffic in dishonestly acquired "highgrade." It has been locally estimated that over $2,000,000 was stolen from the Mohawk, Red Top, and Jumbo mines alone up to the latter part of 1907. About $250,000 worth of stolen ore is said to have been recovered in 1906. While these figures may be exaggerated they give some idea of the magni- tude of the thefts. The 'report of the Goldfield Consolidated Mines Company for the year ending November 1, 1907, shows that stolen ore to the value of $30,896.98 was actually recov- ered between May 1 and October 31, 1907. T. A. Rickard a states that the total stealings from this one company for the year 1907 were fully $1,000,000, and the same conclusion is reached from a comparison of the figures of mine production, with those of the mint for that year.6 In October, 1906, the town of Goldfield was in a very flourishing condition. According to the local correspondent of the Engineering and Mining Journal there were at that time over 150 buildings in course of construction. There were 56 mining companies in operation, employ- ing 2,250 men. There were 27 leases on the Mohawk, of which 12 were shipping ore. The population of the district at the close of the year was estimated at 15,000. It is not surprising that the remarkable discoveries in the Hayes-Monnette and Little Florence lease blocks, coming at a time when over the country at large a wave of speculation had reached what we now know was nearly breaking height, should have led to overconfidence and inflation. In the prospectuses of promoters and in the minds of eager investors nearly every claim was a potential Mohawk. One mining company, the ground of which, so far as known, has never produced a pound of ore, is capitalized at 2,000,000 shares with a par value of $1. Yet, notwithstanding this obvious overcapitalization these shares were quoted at one time at $1.80, corresponding to a total valuation of the property of $3,600,000. In October, 1908, the public, with chastened judgment, valued the same chance for finding an ore body at $400,000. Overcapitalization is not confined to any one company, but is so common as to be generally accepted as a matter of course. Prospects irrespective of all probabilities are generally capi- talized at $1,000,000 from the start, and it is a fair question whether the mines of one or two of the most important companies, in spite of their past productiveness, great known resources, and reasonable expectations, warrant their very large capitalization. Even at a time of general inflation, such as that at the close of 1906, some of the most valuable of these stocks did not reach par, although others having no basis of value other than expectation were quoted at high premiums. As an investment mining stock during the life of the mine should repay in divi- dends to its holders the sum invested plus interest calculated at a rate considerably higher than that customary in well-secured loans. The public, however, in buying mining stock is influenced as a rule more by the prospect of immediate high returns than by the real value of the investment. That the speculative side of the transaction should be usually dominant follows naturally from the great extent to which chance enters into mining operations, particu- larly where, as at Goldfield, the ore bodies are both rich and irregular. The buyer expects to sell at an advance or to dispose of his holdings after the receipt of rich dividends at something near their purchase price. Friction between miners and operators continued through the latter part of 1906, the wage scale and the problem of preventing ore thefts being prominent subjects of negotiation. In August an eight-hour day was agreed upon for all work with rates of $4 and $4.50 for ordi- nary and $5 to $5.50 for skilled labor. The harmony, however, proved transitory. The attempt of the operators to eliminate stealing by the use of change rooms for the men met with oppo- sition from the miners and the regulation of wages became a recurring point of contention. "The great gold mines: Min. and Sci. Press, vol. 96, 1908, p. 161. &Lindgren, W., and McCaskey, H. D., Production of gold and silver in 1907: Mineral Resources U. S. for 1907, pt. 1, U. S. Geol. Survey, 1908, p. 122. 20 THE GEOLOGY AND ORE DEPOSITS OF GOLDFIELD, NEVADA. On November 20, 1906, occurred the most important consolidation of interests yet effected at Goldfield. The Mohawk, Jumbo, Red Top, and Laguna mines were consolidated under the title of the Goldfield Consolidated Mines Company, incorporated under the laws of Wyoming and capitalized at $50,000,000, in 5,000,000 shares, at $10 par value. In this transaction C. D. Taylor received $1,330,000 for his shares in the Jumbo and Red Top companies, at a rate of $2 a share. Mr. George Wingfield, who became president of the new corporation, with his associates received 250,000 shares as their commission for effecting the amalgamation. The consolidated company also secured options on the Combination and January mines, which they subsequently acquired. The price paid for the Combination mine in March, 1907, was reported to be $4,000,000. The extent and development of the properties in the initial consolidation are shown in the following table issued by the company early in December. 1906: Acreage and workings of consolidated mines. Mine. Area. Shafts. Drifts. Crosscuts. Raises. Winzes. Acres. 42. 227 62. 440 18.6110 33.113 Feet. 3,140 300 1,350 140 Feet. 2,710 1,670 2,020 Feet. 3,715 1,545 1,025 360 Feet. 1,565 530 645 Feet. 465 Red Top 35 125 156.470 4,930 6,400 6,645 2,740 625 To the above were subsequently added over 200 acres embraced in the Combination and January holdings. The production credited to these properties at the time of consolidation is as follows: Production of consolidated mines. Mine. Gross value. Net value. Royalties. $1,607,342 308,515 4,875,519 $813,098 260, 177 3,135,426 $201,771 Red Top 705,469 6,791,776 4,208,701 907, 240 The market value of the Consolidated shares at the beginning of 1907 was about $7. On November 21, 1907, they were quoted at $3.95. The Hayes-Monnette lease, after surpassing all records in the district for the value of ore shipped in less than a year's time, expired on January 11, 1907. According to a statement issued by the Goldfield Consolidated Mines Company, the output of the Mohawk leases was as follows: Production of Mohawk leases from April 18 to November 20, 1906. Lease. Hayes-Monnette Frances Others Ore in dry tons. 20, 909 6,422 7,466 34, 797 Gross value. $2,597,845 993, 508 484, 566 4,075,919 Net value. $2,038,398 784,490 312,538 3,135,426 Royalties. $458,640 176,510 70,320 705,470 Balances. $1,579,758 607, 980 242, 218 2, 429, 956 The foregoing table is not complete, as most of the leases still had from one to two months to run. The total gross production of the Hayes-Monnette, according to a statement by Mr. M. J. Monnette in the Goldfield News, amounted to $4,400,000. The gross output for October alone was approximately $1,300,000. Shipments continued to be made from the dump of this lease until late in 1907. The average freight and treatment rate on ores shipped to smelters in 1906 was about $23.50 a ton. Throughout the year 1907 the free development of the district continued to be hampered by friction between the mine operators and the unions. In April one of the many short-lived HISTORY OF MINING. 21 and partial strikes was settled on the reported basis of recognition by the operators of the Western Federation of Miners and the withdrawal of the organization of the Industrial Workers of the World from the district. In November the miners refused to accept part payment of their wages in checks or exchange drafts — an expedient which the employers had adopted in conse- quence of the exceptional financial conditions then prevailing throughout the country and the congestion in the smelters of the siliceous Goldfield ores, which prevented prompt settlement with the shippers. Local samplers, who act as middlemen between some of the mines and the smelters, were compelled to refuse the purchase of ore or to accept it only upon the understand- ing that payment therefor might be subject to delay. Under these unusual circumstances most of the large mines were compelled to store their rich ore or to curtail production. About 1,900 men struck on November 27. On December 6, at the request of the governor of Nevada, in view of the fact that the State maintains no militia, 9 companies of federal troops were ordered into the district from San Francisco and Monterey. No actual violence appears to have been committed by the strikers prior to the call for troops, but the experience at Cripple Creek and other mining camps in the West was held by the mine owners to justify the conclusion that any attempt to reopen the mines with nonunion men would be followed by bloodshed and by the destruction of property. On December 9 the Goldfield Mine Operators' Association announced the following changes in the scale of wages: Wages at Goldfield. Miners Machine men.. Chuck tenders . Muckers Carmen Top carmen . . . Pump men Timber men... Old. $5. 00 5.00 5.00 5.00 5.00 5.00 New. $4.00 4.00 3.75 3.75 4.00 4.50 Carpenters Machinists Engineers Electricians Blacksmiths Tool sharpeners Blacksmith's helpers Old. $7.00 00-6.00 00-6. 00 7.00 5.00 5.00 4.00 New. $5. 00 5.00 5.00 5.00 5.50 5.00 4.00 The new scale, however, was not immediately put into effect. Resolutions were passed, also, to the effect that no one affiliated with the Western Federation of Miners should be em- ployed at the mines. Some correspondence was carried on in December between the governor of Nevada and the President of the United States concerning the propriety of the call for troops and of their con- tinued presence in the district. Governor Sparks was urged to call the legislature together, in order that the State might take steps to maintain order within its boundaries or else formally call upon the Federal Government for assistance. On December 11a federal commission con- sisting of Lawrence O. Murray, Assistant Secretary of Commerce and Labor, Charles P. Neill, Commissioner of Labor, and Herbert Knox Smith, Commissioner of Corporations, was sent to the district to investigate the conditions there obtaining. Its members reached Goldfield and began the taking of testimony on December 15, 1907. In the meantime some of the mines were reopening with new men or with old employees who renounced allegiance to the local union. On December 30 the three commissioners reported their findings to the President." They concluded that there had been no justification for the calling of federal troops and that the State of Nevada should take upon itself the preservation of order in the district. On January 4 a part of the troops was withdrawn, 2 companies being left at Goldfield. On January 14 the state legislature convened in special session, and on January 16 it passed a resolution asking that the federal troops be allowed to remain until a suitable state organization could be effected to police the district. On January 24 the legislature passed a bill for the creation of a force of state con- stabulary consisting of a superintendent, an inspector, 25 subordinate officers, and 250 privates, and on the same day it requested the Mine Operators' Association of Goldfield to abolish the card system of employment which discriminated against certain labor organizations. This a 60th Cong., 1st sess., House Doc. 607, 1908. 22 THE GEOLOGY AND ORE DEPOSITS OF GOLDFIELD, NEVADA. request was acceded to, with the result that competency and good repute became the sole qualifications demanded of the employee. The following rules, copies to be posted at each mine, were promulgated by the mine owners : This mine is to be worked under the open-shop policy of the Goldfield Mine Operators' Association, hiring and dis- charging men without regard to whether they do or do not belong to any labor organization, and under the following rules and regulations: 1. The time of each man on every shift belongs to this company and to no one else. 2. No walking delegate or other representative of any labor organization is to be allowed upon these premises at any time or for any purpose. 3. No soliciting of membership in any labor organization is to be allowed upon these premises at any time by an employee of this company or by anyone else. 4. No discussion of labor questions, either for or against unions, or in any way connected therewith, is to be allowed during working hours, or upon these premises at any time or under any circumstances. 5. No employee of this company is to be annoyed or interfered with by any other employee in his work in any way whatsoever because he may or may not belong to any labor organization, or for any other reason, and all employees are to work together harmoniously for the best interests of the company. 6. No employee of this company is to harass, intimidate, or interfere with any working man of the Goldfield min- ing district because he does or does not belong to any labor organization. 7. All employees are requested to report any violations of these regulations to the management, and any employee found guilty of violating them, or any part of them, will be immediately discharged and be disqualified from any further employment by this company. 8. Any outsider violating any of these rules will be immediately ejected from the premises and prosecuted by law for trespass. On March 7, 1908, the last of the federal troops were withdrawn, and in April the Gold- field miners' union declared the strike at an end. Among the notable events of the year 1907 was the discovery of ore by lessees in the Little Florence mine, near Milltown, at a point about 600 feet south of the Florence claim, and in the Rogers lease on the Red King claim. These developments were important in that the new ore bodies occur in andesite, while the mines which had previously proved so productive are in dacite. Ore in andesite was found also in the Daisy mine, near Diamondfield. A promising feature of this year's development was the considerable depth, from 400 to 500 feet, at which some of the newly opened ore bodies were found. The Las Vegas and Tonopah Railroad, connecting Gold- field with the Bullfrog district, was completed in the latter part of October, giving the Goldfield mines an outlet by way of Las Vegas to the smelters of Utah. A few months later the Tonopah and Tidewater Railroad also built into the district. In this year Goldfield became the seat of Esmeralda County. The year 1908 was mainly a period of slow recovery from the depression of 1907 and of preparation for extensive operations in the future. The Goldfield Consolidated Mines Com- pany confined its work chiefly to the development of the Mohawk and Combination mines and to the construction of its 100-stamp mill, on the west face of Sandstorm Ridge, at a cost of $750,000. The 600-foot level of the Mohawk was opened, and there proved to be a large body of good ore at that depth. The Florence Company did practically no underground work, but completed a pipe line and a 20-stamp mill. Lessees continued to be fairly active. The Little Florence lease expired on April 26 and the Rogers Syndicate lease on July 11, 1908. Both were highly profitable. The gross pro- duction of the Little Florence is estimated at over $1,500,000 ($1,285,000 net) and of the Rogers Syndicate about $500,000. The success of these lessees has led to thorough exploration of the ground on the east, south, and west of Florence Hill and the sinking of more than a score of shafts in this vicinity to depths ranging from 300 to 500 feet. One result was the discovery of a small, although very rich, ore body in the Engineers' lease on the east side of the hill. On May 1, 1908, the St. Ives, Velvet, Potlatch, and Gold Horn mining companies con- solidated as the Goldfield Merger Mines Company, with a nominal capital of $5,000,000. Up to the date of consolidation the St. Ives had produced less than $100,000 and the Velvet probably less than $25,000. PRODUCTION. 23 The character of the Goldfielcl deposits is such that endless litigation might easily result were the law of the apex invoked with the same ingenuity and contested with the same bitter- ness as in Butte. Fortunately for the district the mine owners have been wise enough to avoid this danger by compromise or consolidation. A notable example of such foresight was shown in July, 1908, when the Goldfield Consolidated Mines Company and the Jumbo Extension Mining Company reached an agreement regarding the Wedge fractional claim of the latter company, which lies immediately northeast of the Mohawk No. 2 claim. On February 18, 1908, the Jumbo Extension Company and its tenants were enjoined from working the Wedge claim on the ground that the ore in this fraction had its apex in the property of the Consoli- dated Company. On July 24 the Jumbo Extension Company deeded the Wedge claim to the Goldfield Consolidated Mines Company and relinquished to the latter a one-fourth interest in the Vinegarone fraction, lying immediately northeast of the Red Top claim. On its side the Consolidated Company recognized existing leases on the Wedge claim and agreed not to claim more than one-half of any ore that might in future be mined from veins on the Polverde claim apexing on Consolidated ground. This agreement is creditable to all concerned — to the engi- neers who established the facts, to the lawyers who interpreted the legal bearing of these, and to the companies who accepted them. Its ratification deserves to rank as one of the important events in the history of the district. According to the secretary of the Mine Operators' Association, the total number of miners employed in the latter part of June, 1908, was about 1,800, the monthly pay roll having a total of $200,000. PRODUCTION. The gross production of the Goldfield district from the beginning of mining to the end of 1907 is shown in the following table, the figures being taken from the reports on the production of gold and silver published by the United States Geological Survey. The silver is calculated at the average commercial value at New York for each year. As the figures represent gross output, no deductions have been made for freight, treatment, or loss in smelting. Production of the Goldfield district. Year. Ore. Gold. Silver. Total value. Average value per ton. Quantity. Value. Quantity. Value. 1903 Short tons. 335 7,433 19, 548 59, 628 101,136 Fine ounces. 3, 412. 66 113,293.23 91, 087. 76 339, 890. 20 406, 756. 16 $70, 670 2,341,979 1,882,951 7, 026, 154 8, 408, 396 Fine ounces. 287 19,954 8,589 15, 648 71,710 $155 11,374 5,188 10, 484 47, 329 $70, 825 2, 353, 353 1,888,139 7, 036, 638 8, 455, 725 $211.41 316. 60 96. 58 118.00 83.61 1904 1905 1906 1907 188, 080 954, 446. 01 19, 730, 150 116, 188 74, 530 19, 804, 680 105. 29 The decrease in 1905 is accounted for mainly by the expiration of many leases at the close of that year, by the necessity of more systematic underground development by the mining companies as a preparation for mining on their own account, by the idleness of the Jumbo mine, which had contributed over $1,000,000 to the production of 1904, and by the tendency of the mine owners to hold their ore until railway transportation and better milling facilities should decrease the cost of treatment. The remarkable revival of successful leasing in 1906, particularly on the Mohawk No. 2 claim, and the improved facilities for shipping and market- ing ore are reflected in the greatly increased production for that year. 24 THE GEOLOGY AND ORE DEPOSITS OF GOLDFIELD, NEVADA. The following approximate figures, taken from the current reports of local correspondents to the mining journals, will give some idea of the size, value, and fluctuations of weekly ship- ments in the latter part of 1907: Weekly output/mm Goldjield, 1907. Weekending- JulvO July 13 July 20 July 27 August 3 August 10 August 17 August 24 August 31 September 7 . . September 14. Tons of 3, 417 3,919 3,143 3,930 3,709 3,810 3,417 1,566 2,466 Est' mated value. S590, 000 345, 250 479, 400 400,000 400, 000 350, 000 285, 000 290, 000 Week ending- September 20 . September 27. October 5 October 12 October 19 October 26 November 8.. November 15. November 22 . November 28. Tons of 3,492 4,129 3,877 5, 390 1,950 4,939 5,801 3,570 Estimated value. $400, 000 400,000 382,000 508,000 204, 850 456, 450 674,200 354.230 The following statement from the Mining and Scientific Press of November 9, 1907, shows the sources of the ore treated in the district or shipped from Goldfield during the week ending on November 3 : Output of Goldfield mines for the week ending November 3, 1907. Mohawk Mohawk-Combination Begole lease Rogers Syndicate Florence Combination mill Kinkead mill Tons. Value. 834 S125. 000 768 53,700 390 29,000 90 9,000 46 4,600 560 39,200 140 7,000 By railroad. Mohawk Begole lease. Tons. 165 Value. $100,000 16, 500 3,741 399, 700 Of the 101,136 tons of ore treated in 1907, 17,782 tons, of an average value of $44.90 a ton, were milled, yielding 434 tons of concentrates, which contained $195,231 in gold and $2,057 in silver. The 83,354 tons shipped had an average value of $91.86 a ton. In June and July, 1908, the estimated value of the weekly shipments of ore and concen- trates from Goldfield ranged from $175,000 to $200,000. Owing to causes noted in the pre- ceding historical sketch, the output of the district for 1908 will probably be less than that for 1907. LITERATURE. The following list aims to include: (1) Publications of value for a general understanding of the geology of southwestern Nevada, particularly those which treat of formations represented in the Goldfield district; (2) publications descriptive of mining districts in the region adjacent to Goldfield; and (3) publications containing original and important contributions to our knowledge of the geology or ores of the Goldfield deposits. Many short papers relating to the district are not included in any of these categories and are therefore intentionally omitted. (1) WORKS ON THE GENERAL REGION. King, Clarence. Systematic geology: U. S. Geol. Expl. 40th Par., vol. 1, 1878. Contains a wealth of information on the geologic development of the whole region of which the Goldfield district is a part. Sptjrr, J. E. Descriptive geology of Nevada south of the fortieth parallel and adjacent portions of California. Bull. U. S. Geol. Survey No. 208, 1905. Deals with the general region and may be regarded as supplementary to the work of King. Ball, S. H. A geologic reconnaissance in southwestern Nevada and eastern California. Bull. U. S. Geol. Survey No. 308, 1907. A further development and extension of the reconnaissance work begun by Spurr in 1899 (Bull. U. S. Geol. Survey No. 208, 1903). The post-Jurassic igneous rocks of southwestern Nevada. Jour. Geology, vol. 16, 1908, pp. 36-45. Describes the petrography and relationships of the intrusive granular rocks of pre-Tertiary age. LITERATURE. 25 (2) DESCRIPTIONS OF MINING DISTRICTS IN THE GOLDFIELD REGION. Spuer, J. E. Ore deposits of Tonopah and neighboring districts, Nevada. Bull. U. S. Geol. Survey No. 213, 1903, pp. 81-87. Describes Southern Klondike, Silver Peak, Gold Mountain, and Hennepah districts. The Goldfield deposits were not yet known. — The ore deposits of Tonopah, Nevada. (Preliminary report) Bull. U. S. Geol. Survey No. 219, 1903. ■ Preliminary report on the ore deposits of Tonopah, Nevada. Bull. U. S. Geol. Survey No. 225, 1904, pp. 89-110. Ore deposits of Silver Peak Quadrangle, Nevada. Bull. U. S. Geol. Survey No. 225, 1904, pp. 111-117. Developments at Tonopah, Nevada, during 1904. Bull. U. S. Geol. Survey No. 260, 1905, pp. 140-149. Geology of the Tonopah mining district, Nevada. Prof. Paper U. S. Geol. Survey No. 42, 1905. The ore deposits of the Silver Peak quadrangle. Prof. Paper U. S. Geol. Survey No. 55, 1906. Ball, S. H. Notes on ore deposits of southwestern Nevada and eastern California. Bull. U. S. Geol. Survey No. 285, 1906, pp. 53-73. Ransome, F. L. A preliminary account of Goldfield, Bullfrog, and other mining districts in southern Nevada; with notes on the Manhattan district by W. H. Emmons and G. H. Garrey. Bull. U. S. Geol. Survey No. 303, 1906. Taft, H. H. Notes on southern Nevada and Inyo County, California. Trans. Am. Inst. Min. Eng., vol. 37, 1907, pp. 178-197. Chiefly historical and descriptive of mining development and some notes on geology. (3) PAPERS ON THE GOLDFIELD DISTRICT. Spurr, J. E. Notes on the geology of the Goldfield district, Nevada. Bull. U. S. Geol. Survey No. 225, 1904, pp. 118-119. Notes occurrence of alaskite and rhyolite on Columbia Mountain, and describes their intrusion into dark siliceous sediments. Best assays then obtained (June, 1903) were $50 a ton. The ores of Goldfield, Nevada. Bull. U. S. Geol. Survey No. 260, 1905, pp. 132-139. Describes conditions in November, 1904. Gives additional notes on geology. The peculiar shape of the deposits and their mineralogical character are described in some detail. The ledges are regarded as products of meta- morphism by hot ascending water. Moore, Charles J. The Goldfield mining district. Goldfield News, April 21, 1905. Of interest as an early effort to interpret the geology of the district. Winchell, Horace V. Notes on Goldfield, Nevada. Am. Geologist, vol. 35, 1905, pp. 382-385. Describes the ore deposits as silicified rhyolite dikes. Recognizes the evidence of solfataric action. Bosqui, Francis L. Ore treatment at the Combination mine, Goldfield, Nevada. Min. and Sci. Press, vol. 93, 1906, pp. 413-^15 and 451^54. An excellent description of processes employed, with results and costs. Taft, H. H. Notes on southern Nevada and Inyo County, California. Trans. Am. Inst. Min. Eng., vol. 37, 1907, pp. 178-197. Chiefly historical and descriptive of mining development withsome notes on geology. Hastings, J. B., and Berkey, C. P. The geology and petrography of the Goldfield mining district, Nevada. Trans. Am. Inst. Min. Eng., vol. 37, 1907, pp. 140-159. Presents a good account of the rocks and shows their distribution by a sketch map. The paper errs in citing Columbia, Knickerbocker (Preble), Black Cap, and other hills as volcanic necks or cones, and contains scant information on the age and structural relations of the various rocks. Ransome, F. L. A preliminary account of Goldfield, Bullfrog, and other mining districts in southern Nevada; with notes on the Manhattan district by W. H. Emmons and G. H. Garrey. Bull. U. S. Geol. Survey No. 303, 1906. Collins, E. A. The Combination mine. Min. and Sci. Press, vol. 95, 1907, pp. 397-399 and 435-438. History of mine and methods of mining and treating the ore. Describes general character of the ore bodies. Ransome, F. L. The association of alunite with gold in the Goldfield district, Nevada. Econ. Geology, vol. 2, 1907, pp. 667-692. Describes the alteration of the dacite in connection with ore deposition. Establishes the abundant occurrence of alunite as a characteristic mineral of the ores and altered country rock, and discusses the genesis of the deposits. Sharwood, W. J. Gold tellurides. Min. and Sci. Press, vol. 94, 1907, pp. 731-732. Drawings of thin sections showing relations of telluride, gold, and quartz. Browne, R. Stuart. Cyanidation in Nevada. Min. and Sci. Press, vol. 95, 1907, p. 677. Proposes to treat Goldfield ores by dry crushing, roasting, and final leaching with cyanide solution. Rickard, T. A. Goldfield, Nevada. Min. and Sci. Press, vol. 96, 1908, pp. 559, 664, 738, 774, 840. General notes on the district. The articles on the history of the district, on the moral effect of rich ore, and on metallurgical development are particularly good. Becker, Arnold. Geological possiblities at Goldfield. Min. and Sci. Press, vol. 96, 1908, p. 846. An attempt to show that there is a second sheet of dacite below the one in which the rich Mohawk ore bodies occur and that this lower sheet may prove productive. The supposed lower dacite does not exist. 26 THE GEOLOGY AND ORE DEPOSITS OF GOLDPIELD, NEVADA. King, Lochiel M. Cyanidation in Nevada. Min. and Sci. Press, vol. 96, 1908, pp. 123-126. Advocates dry crushing, roasting, and cyanidation of crude ore. Kirby, A. G. Cyanidation in Nevada. Min. and Sci. Press, vol. 96, 1908, pp. 836-839. Describes mill tests on Combination and Mohawk ores. Believes that ores can be more economically treated by wet crushing, amalgamating, concentrating, and then roasting and cyaniding the concentrates in the district, than by roasting and cyaniding the crude ore. GEOGRAPHIC NAMES. A search for geographic names to distinguish successive eruptions of lava of the same petrographic character (there are in the district, for example, five rhyolites of different age) soon showed how few names in local use were available for this purpose. It became necessary to apply names to certain topographic features in order that the rocks typically developed at these localities might be appropriately designated. The difficulty of finding English names which are appropriate, and which can at the same time be fitly applied to geologic formations, becomes evident on trial. In names chosen from the Spanish the ordinary meaning of the words is less obtrusive, and it is possible to find terms which are appropriate, euphonious, and easily pronounced. The following list shows the new names employed in this report, with their derivation and usage : Names applied in this report to topographic features. Name. Malpais Mesa Spearhead Point Pozo Canyon Mira Mountain.. Meda Pass Chispa Hills Espina Hill Morena Ridge. .. Derivation and comment. Spanish mal pais (mill pah-ees'), bad country. Popularly pronounced m&l'-a-pi. The feature here called Malpais Mesa is locally referred to as "the Malapai" or "the mesa." Refers to shape ofpoint Spanish pozo, well. Refers to fact that a well in this ravine was formerly the chief source of water for Goldfield. Spanish mira (mee'-ra), look!, behold! Refers to view of Goldfield from thesummit From Goldfield Meda Mining Co. , whose claims cover the pass Spanish chispa, sparkle. Refers to the sparkling black mica on the surface of the hills. Spanish espina (es-pee'na), spine. Refers to shape of hill Spanish morcno (mo-ray'-na), brown. Refers to color of the rhyolite Geologic use. Malpais basalt. Spearhead rhyolite. Pozo formation (sedimentary). Mira basalt. Meda rhyolite. Chispa andesite. Espina breccia. Morena rhyolite. CHAPTER II. PRELIMINARY OUTLINE OF THE GEOLOGY AND ORE DEPOSITS. This chapter is not intended as a complete synopsis of the whole report. Its function is to give the reader such a preliminary and general view of the field as will enable him to follow more readily and, it is hoped, with greater interest, the ampler exposition of the succeeding chapters. The geologic structure of Goldfield, compared with that of most districts in which deposits of the precious metals are found, is simple. The district is essentially a low, domical a uplift of Tertiary lavas and lake sediments resting upon a foundation of ancient granitic and meta- morphic rocks. The erosion of this flat dome has exposed the pre-Tertiary rocks at a number of places in the central part of the district and these outcrops are surrounded by wide concentric zones of successively younger formations. Some of the later lavas were erupted after the dome had been elevated and truncated. The oldest rocks exposed in the district are found on Columbia and Vindicator mountains, and from Columbia or Goldfield are particularly noticeable as conspicuous dark patches on the southern slope of the former peak. Originally thin-bedded limestones or calcareous shales, with subordinate beds of sandstone, the formation is now much contorted and metamorphosed. The calcareous beds have been changed to compact aggregates of quartz (jasperoid) crowded with microscopic black particles, probably carbonaceous, and the sandstone to hard, vitreous quartzite. These beds are probably Cambrian. The metamorphism is apparently due to the intrusion into these sediments of masses of a granitic rock composed essentially of quartz and orthoclase, a type for which Spurr has proposed the name alaskite. This rock is well exposed on Columbia Mountain and makes up a large part of Vindicator Mountain. Smaller areas occur in the vicinity of Banner Mountain. Most of the alaskite contains a very little black mica and some plagioclase. In most exposures the mica is decomposed and scarcely noticeable, but northeast of the summit of Vindicator Moun- tain the alaskite mass grades into a biotite granite. The alaskite was probably intruded at about the close of Jurassic time. It is certain that this event was followed by a long interval during which the region was eroded to the surface of moderate relief subsequently covered by the irruption of Tertiary lavas. The sequence of Tertiary eruptions as exemplified by the rocks of the Goldfield district is given in the following list, the oldest rocks being at the bottom. To prevent confusion between rocks of like petrographic character erupted at different periods, recurrent kinds are distinguished by local geographic terms derived from places at or near which the corresponding rocks may be seen. a The word domal (from the Latin domus, a house) which means "belonging to a house" was originally an astrological term, but was later applied to the roof-like planes of certain crystal forms. It has unfortunately slipped into some currency in geologic literature as a substitute for domical, which is the correct adjective in reference to a dome and is analogous to conical, spherical, and cubical. 27 28 THE GEOLOGY AND ORE DEPOSITS OF GOLDFIELD, NEVADA. Sequence of the Tertiary eruptions. Formation or map name. Petrographic name. Malpais basalt Rabbit Spring formation. Spearhead rhyolite Pozo formation Dolerite Breccia, conglomerate, and sandstone. Rhyolite Conglomerate fSiebert formation.. I Mira basalt Isiebert formation.. Espina breccia Andesite breccia Medarhyolite Dacite vitrophyre. Chispa andesite Dacite vitrophyre. Dacite Milltown andesite. Morena rhyolite Sandstorm rhyolite. Kendall tuff Latite Vindicator rhyolite . Conglomerate, sandstone, tuffs, and diatomaceous earth. Quartz-bearing doleritic basalt Conglomerate, sandstone, tuffs, etc Dacitic breccia Andesite breccia Rhyolite Dacite vitrophyre Andesite Dacite vitrophyre Dacite Andesite. Rhyolite ...."do Rhyolitic and andesitic tuff. Latite Rhyolite. Occurrence. Flow or flows, with a few small intrusions. A variable and for the most part thin deposit; probably fluviatile. Flow or flows. Fluviatile deposit. Conformably underlies Spearhead rhyolite and unconfonn- ably overlies the Siebert formation. Lake beds. Flow intercalated in Siebert formation. Lake beds. Roughly bedded deposit. Roughly bedded pyroclastic deposit. Flow. Do. One or more flows in the dacite vitrophyre. Flows. Sheet-like and irregular intrusive masses passing into flows and breccias east of the area mapped. Mainly flows, but with some dikes and intrusive masses and with some tuff and breccia. Locally includes some effusive basaltic rocks which are not exposed at the surface. Intrusive masses. Flows. Obscurely bedded and in part lenticular deposits closely associated with the Sandstorm rhyolite. Flow. Do. A few dikes of uncertain position in the sequence are not included in the foregoing list. The Vindicator rhyolite rests on Cambrian sediments and alaskite on the flanks of Vindi- cator Mountain and on the summit of Columbia Mountain. Much of it is greatly altered and contains abundant alunite. The latite, as may be seen from Plate II, occupies an area a little over 2 miles (3.2 kilo- meters) in diameter in the center of the district, and a smaller area south of Columbia. Its characteristic features may be well seen in the vicinity of McLaughlin's well, on Banner Moun- tain, and on the southern edge of the town of Columbia. The rock, nowhere fresh, is normally dull purplish or greenish gray. A spotted or mottled appearance, due to flow brecciation, is rather characteristic and is well shown on a small hill half a mile north of the summit of Banner Mountain. The freshest obtainable specimens of the latite show phenocrysts of feldspar, horn- blende, and mica in a compact, streaky groundmass that was evidently once a glass with well- marked flowage lines. As a rule, the latite, when it has not been subjected to the intense local alteration connected with ore deposition, may be distinguished from the later andesitic rocks by the absence of fresh phenocrysts and the peculiar streakiness of its groundmass, which resembles the groundmass of a rhyolite rather than that of most andesites. The rock is a flow resting generally upon a clean and rather uneven surface of alaskite and Paleozoic sediments, although on Vindicator Mountain it rests in part on the oldest rhyolite. Its thickness is not known, but is clearly variable, as on Columbia Mountain the succeeding rhyolite rests directly upon the alaskite. The maximum thickness is tentatively estimated at 300 feet (91 meters); it may be considerably more. Overlying the latite, or resting on the pre-Tertiary rocks where the latite is absent, is a series of thin, glassy rhyolite flows which is best developed in the rounded white hills northwest of Columbia Mountain. This, the Sandstorm rhyolite, is closely associated with pale greenish tuffs (Kendall tuff) of mingled latitic and rhyolitic character and is cut by masses of intrusive Morena rhyolite. The effusive rhyolite is usually nearly white, has conspicuous flow lami- nation, and weathers in thin, shelly flakes. This is the rock of the Sandstorm mine and of the hills lying west of the road from the mine to Columbia. It all shows some devitrification and silicification, particularly in the vicinity of the ore deposits. Certain varieties or portions of this rhyolite acquired by flowage a very thin lamination, which gives the rock when somewhat weathered a deceptive resemblance to indurated clay shale. The rhyolite appears to have been thickest in the vicinity of Columbia Mountain and to thin out to the southeast. None of it has been found southeast of McLaughlin's well. 156654 OUTLINE OF THE GEOLOGY AND ORE DEPOSITS. 29 The Kendall tuff associated with these early rhyolitic eruptions may be best examined along the southwest base of Columbia Mountain and directly west of the Kendall mine. Under- ground it is exposed in the west workings of the 100-foot level of this mine. The intrusive or Morena rhyolite that forms Morena Ridge extends north from the summit of Columbia Mountain to the Adams mine and cuts the shaly Sandstorm rhyolite at the Conqueror mine. After the eruptions of the earlier rhyolites the region was covered with successive flows of andesite, accompanied by subordinate layers of andesitic tuff. The products of these erup- tions, the Milltown andesite, constitute the most extensive formation in the district. (See PI. II.) The total thickness of this deposit, as of most of the other volcanic formations in this district, can not be determined, owing to the slight deformation of the rocks, their poor exposures, the comparatively slight topographic relief, and the absence of persistent datum planes, such as may usually be found in stratified rocks. It probably lies between 600 and 800 feet (183 and 244 meters). The dacite, whose eruption followed the andesitic period, is in many respects the most interesting rock in the district and is very important from an economic point of view. It occupies, as may be seen by reference to Plate II, a considerable area east of Goldfield and Columbia and is the principal country rock of the larger mines. This mass appears to be an intrusive sheet about 700 feet (213 meters) in maximum thickness, but in most places much thinner. A larger body of dacite extends southward from Tognoni Springs and forms some of the high hills just east of the mapped portion of the district. This body, as may be seen from Plate II, makes up a large part of Preble Mountain, where it is probably intrusive into the Milltown andesite. East of the area mapped, however, the dacite is undoubtedly effusive and is associated with volcanic breccia. Smaller masses of dacite occur southeast of Black Butte and in the central part of the district. Mineralogically and chemically the dacite at Goldfield is merely a quartz-bearing andesite and is in no way similar to the more siliceous rocks called dacite by Spurr in his report on the Tonopah district.0 Contemporaneously with, or shortly after, the dacite intrusion a rock classed as dacite vitrophyre was erupted as a series of flows and is now extensively exposed in the low hills in the southeast corner of the district. This rock is in most places a porous light-gray or greenish rock with abundant glistening scales of black mica and phenocrysts of fresh plagioclase. The dacite vitrophyre is associated with one or more intercalated flows of andesite (Chispa andesite). The eruption of the dacite vitrophyre was followed by a flow of rhyolite (Meda rhyolite) and by eruptions of andesitic breccia. After these eruptions the region was covered by an extensive body of fresh water in which were laid down 1,000 feet (305 meters) or more of bedded conglomerates, tuffs, tuffaceous sands, pumiceous ash, and diatomaceous earth. These deposits cover a large part of the district, particularly in its outskirts. They underlie the town of Goldfield and stretch both northward and southward beyond the limits of the area studied. They also extend beneath Malpais Mesa southwest of town and are well exposed in the steep bluffs of Pozo Canyon. The beds here dip generally westward at angles ranging from 25° to 30°. As dacite vitrophyre and associated flows are present beneath the lake beds in only a small part of the district, and as the formation of the lake indicates some change in the configuration of the region, there is at least a suggestion of erosion between these eruptions and the lacustrine condition. Volcanism continued active during the existence of the lake, as is shown by the prevailingly volcanic nature of the sediments and the occurrence within them of a thick flow of quartz-bearing basalt (Mira basalt) and thin flows of glassy rhyolite. The Mira basalt, as shown by wells, underlies the southwestern part of Goldfield and is exposed on the automobile road to the Bullfrog district. a Spurr's reasons for using the name dacite for rocks which strictly should receive other names are given in Geology of Tonopah mining district, Nevada: Prof. Paper U. S. Geol. Survey No. 42, 1905, p. 59, footnote. 30 THE GEOLOGY AND OEE DEPOSITS OF GOLDFIELD, NEVADA. In the eastern part of the district, northeast of Preble Mountain, are some bedded breccias and tuffs from 200 to 300 feet (61 to 91 meters) in present thickness. They rest upon dacite and andesite and are made up largely of fragments of these rocks, particularly of dacite mingled with abundant fragments of volcanic glass and some sandy tuffs. These beds, the Espina breccia, are possibly of the same age as the lake beds just described. The dacite vi trophy re is cut by dikes of andesite. Whether these were erupted before, during, or after the lacustrine episode is not determinable. Lacustrine conditions were ended by uplift of the region, the domical structure being then initiated. After the lake beds had been beveled by erosion and entirely swept away from the central part of the district eruptions of rhyolite lavas again began. The latest rhyolite, called the Spearhead rhyolite, is a light-pink or pale-green rock, rather porous and containing abundant pumiceous fragments. It comprises two flows about 100 feet (30 meters) in total maximum thickness, which are exposed in the bluffs southwest of Goldfield. It is this rock that is quarried for building stone at Rabbit Spring. The rhyolite is in some places overlain by a few feet of unconsolidated tuffaceous sand and volcanic gravel, called the Rabbit Spring formation. Finally, the volcanic history of the region was brought to a close by the eruption of one or more flows of olivine basalt. This is the dark rock that is conspicuous as the capping of Malpais Mesa southwest of town, and has accordingly been given the local designation of the Malpais basalt. It also forms the summit of Myers Mountain, Blackcap Mountain, and of several hills south and east of the area mapped. The larger areas of this rock represent rem- nants of flows which rest upon a nearly horizontal surface of older rocks; but some smaller masses, such as that shown on the east slope of Vindicator Mountain, are intrusive and may fill orifices through which the basalt reached the surface to spread out as flows. The eruption of the Malpais basalt was followed by a period of erosion which, varied by slight deformations of the rocks, has continued to the present. There is no paleontological evidence upon which to assign the Tertiary formations at Gold- field to the recognized series of that system. For reasons later presented the prelacustrine volcanic rocks are provisionally regarded as Eocene, the lacustrine formations as Miocene, and the postlacustrine formations as Pliocene. The sulphide ores of the Goldfield district are of complex mineralogical character, native gold and pyrite being accompanied by minerals containing copper, silver, antimony, arsenic, bismuth, tellurium, and other elements. In some ores the gold occurs free in fine particles, which as a rule are so closely crowded together in the characteristic flinty quartz gangue as to form yellow bands or blotches. The associated minerals are pyrite, marcasite, bismuthinite, a reddish gray cupriferous mineral which appears to correspond more nearly to famatinite than to any other known species, and a new cupric sulphantimonite, which has been named goldfieldite. A concentric crustification is highly characteristic of the richest ores, fragments of silicified, alunitized, and pyritized rock being covered by shells of gold and sulphides. The most notable features of these ore bodies are their remarkable richness and their equally remarkable irregularity. The ores are almost without exception associated with craggy outcrops of silicified volcanic rock, although only a very small proportion of these outcrops, which are extraordinarily numerous and constitute the most striking superficial features of the district, have been found productive. Associated with the silicification other processes of locally intense alteration, especially the formation of alunite, have also been active, producing in many cases a softening of the rock affected, and thus serving to accentuate the silicified portions under the selective action of erosion. The deposits have formed along [zones of Assur- ing, which for the most part are very irregular in trend, are rarely traceable in any one direction for more than half a mile, and are not planes of notable faulting. Branching and intersection are very common. Many of the outcrops show no linear character, being mere irregular knobs of siliceous and alunitic material. Some of these probably represent intense alteration at the point of intersection of two or more inconspicuous approximately vertical fissures. Others OUTLINE OF THE GEOLOGY AND OEE DEPOSITS. 31 are erosion remnants of nearly horizontal silicified zones and, as in the case of Black Butte, merely cap the hills whose summits they form. The most important ore bodies thus far found are in dacite, although some small, very rich pay shoots have been discovered in the Milltown andesite. Oxidized ores have supplied a large part of the gold produced during the first two or three years of exploitation, and in some mines, particularly the Sandstorm and Kendall, which are in rhyolite, no sulphide ores are as yet known. As a rule the oxidized ore is a soft, shattered, more or less earthy material, usually stained brown by oxide of iron. Fragments of rusty porous quartz are mingled with kaolin, alunite, gypsum, alum, oxide of iron, and various earthy mixtures of no definite mineral composition. Some of the rich ore, as in the Sandstorm mine, is a nearly white, impure kaolin, gritty from the presence of minute crystals or grains of quartz, and containing all through it abundant specks of free gold. Barite, in crystals up to an inch (25 millimeters) in length, is abundant in this ore. In the January and Combination mines some of the most characteristic rich ore consists of porous rusty quartz (silicified dacite), in which the pores and crevices are partly filled with yellow, earthy limonite and tiny pearly scales of bismite, the oxide of bismuth. In some specimens these scales form pseudomorphs after bismuthinite. They are usually a sign of rich ore, but are occasionally found in low- grade or barren material. In the mines at Black Butte the richest oxidized ore usually shows little greenish-yellow specks of a ferric tellurite, either emmonsite or durdenite, and tellurite, the oxide of tellurium, was noted in a partly oxidized telluride ore from the Goldfield-Belmont mine near Black Butte. Melanterite (hydrous ferrous sulphate), in some cases mixed with a very little chalcanthite (hydrous copper sulphate), occurs in the partly oxidized ore of the Combination and Florence mines. The valuable constituent of the oxidized ores is native gold. Native silver or halogen compounds of silver are not common. The time of deposition of the ores is not definitely known, but was probably Pliocene. They were deposited from acidified solutions and the deposits now exposed are believed to have been at no time covered by more than 1,000 feet (305 meters) of rock. CHAPTER III. DESCRIPTION OF THE PRE-TERTIARY ROCKS. CAMBRIAN SHALE. The oldest rocks exposed in the Goldfield district are certain dark, fine-grained, and thin- bedded sediments forming parts of Columbia and Vindicator mountains. Those on Columbia Mountain are most conspicuously displayed on the southwest slope, appearing as dark patches which, by their contrast with the light-hued alaskite and rhyolite, constitute a striking feature of the hill as seen from Goldfield or Columbia. In Plate V, A, which is a view of Columbia Mountain from a point between the two towns, this difference in shade is much less evident than in the actual view. The individual beds are thin, most of them less than 4 inches thick. The material is prevailingly aphanitic and of a dense flinty texture. The color is gray, so dark as to appear nearly black when seen in mass. The microscope shows that these beds are now composed of a fine crystalline aggregate of quartz containing abundant opaque black microscopic particles, which are probably carbonaceous, and some minute crystals of pyrite. It is the presence of these inclusions that gives the rock its dark color. Some specimens show tiny grains and veinlets of a colorless anhedral mineral which has not been definitely determined, but which has the general optical characteristics of zoisite. This is the rock referred to by Spurr0 as "jasperoid" and regarded by him as probably a silicified limestone. While such a derivation is not impossible it is thought more probable that the rock was originally a siliceous shale containing considerable organic matter and probably some calcite. On the south slope of Columbia Mountain these dark flinty shales are interbedded with a few thin layers of quartzite. The shales occur in comparatively small masses which have been intruded by alaskite. The original terrane of which they once formed a part has been greatly disrupted by the act of intrusion, and it is doubtful whether any extensive remnants remain beneath the Tertiary volcanic rocks of the Goldfield district. The visible bodies of shale in Columbia and Vindicator mountains probably rest upon alaskite in intrusive contact. Their internal structure therefore has little bearing upon the present tectonic features of the region. It is sufficient to say that the beds have been greatly disturbed by the alaskite intrusion. Those on the west slope of Vindicator Mountain have a general strike of N. 20° W. and dip west at an angle of 75°. Whether this attitude represents folding prior to the granitic invasion there is no means of telling. No fossils have been found in these shales and the only local clue to their age is the fact that they constitute a part of the eroded floor upon which the Tertiary rocks accumulated. The studies of H. W. Turner,6 J. E. Spurr, c and S. H. Ball** have shown, however, that north, west, and south of the Goldfield district are extensive areas of sedimentary rocks referable to the Cambrian period. These rocks are represented in the Southern Klondike district, 14 miles (22.5 kilometers) north of Goldfield; in the Silver Peak Range, of which Montezuma Peak, 7 miles (11 kilometers) west of Goldfield, is a spur; and in some hills just east of the halfway station, 6 miles (9.6 kilometers) south of Goldfield, on the stage road to Lida. Cambrian fossils a Geology of the Goldfield district, Nevada: Bull. U. S. Geol. Survey No. 225, 1904, p. 119. The ores of Goldfield, Nevada: Bull. U. S. Geol. Survey No. 260, 1905, p. 133. 6 Silver Peak folio (unpublished). c Descriptive geology of Nevada south of the fortieth parallel: Bull. D. S. Geol. Survey No. 208, 2d ed., 1905, pp. 184-185. & A geologic reconnaissance in southwestern Nevada and eastern California: Bull. U. S. Geol. Survey No. 308, 1907. 32 U. S. GEOLOGICAL SURVEY PROFESSIONAL PAPER 66 PLATE IV 38' R- *»0 E. R. 41 E R.42 E.I 17 15' R. 43 E. R.42 E. 117 15' R. 43 E. GEOLOGIC RECONNAISSANCE MAP OE THE REGION ADJACENT TO GOEKFTELD After S.KBall 4 6 lO miles Contour interval 100 feet. ~DcvtuxrL is nxe-arv s&cu 7-eveZ-. 1906 LEGEND SEDIMENTARY ROCKS I Oal Allnvitun (grtwels ccrui sands ) Op I « f go Playa deposits fyr7ut& ofays J UNCONFORMITY •S-3 *) Ooa! >- < z CC LJ I- < o Older alhxvinm (allia^ium and play-a deposits; also in part take, beds J UNCONFORMITY cc < cc Siebert. lake beds t taJfaoeous sandstone-,cion- glomerate', and cHayaJ UNCONFORMITY ■Cpml * Prospect Mountain 5 Bute stone < (dark-anav,ftne-g/raine^f nryst4zJa7bc Hmestone-J ) IGNEOUS ROCKS Tb Basalt and. basic andesite ( flows, coneys, and dikes J Tl Late Pliocene latLte and rbyolite (stocks and flows J I Tpr Middle Pliocene Tltyolite (flows I Tr Late Miocene-Pliocene nhyolite and latite ^ (flaws) Tmmr Middle Miocene xtyolite (flows J Ta Miocene andesite and dacite (intrusive masses J r x K fir Tmj Eocene raonzonite porphyry and biotite andesite f intrusive masses and flows J, > CC < cc UJ >i «s & s > CC < h- Granite, gua nionz onite , s syenite ' hatlioatJts and- d rtz end ik&sj j ►a "r LJ CC Q_ Fanlt it The,"I>rospeot Mountain' Hm& - stoTLR' is noy*' known, as tAe- Eldorxulo 1im&&tonJ& PRE-TERTIARY ROCKS. 33 have been found at Silver Peak,3 at Lida,6 near Cuprite c (about 16 miles (25.5 kilometers) south of Goldfield), and at a locality 4 miles (6.5 kilometers) west-northwest of Montezuma Peak.d These Cambrian rocks comprise, according to Ball,* fine-grained dark limestone, shale, and quartzite, the shale and limestone in the Silver Peak Range being interbedded and grading one into the other. As shown in Plate IV, which is compiled chiefly from the geologic map (PL I) accompanying Ball's report, the situation of Goldfield with reference to the areas of Cambrian rocks which partly encircle the district is such as to render it reasonably certain that the metamorphosed beds of Columbia and Vindicator mountains are also Cambrian. They are regarded as probably metamorphosed remnants of the shaly beds belonging to that period as represented in the Silver Peak Range and elsewhere in this general region. ALASKITE AND GRANITE. DEFINITION. The name alaskite was proposed by Spurr/ in 1900 to designate the group of holocrystal- line quartz and alkali-feldspar rocks to which the name aplite had previously been rather loosely applied by most petrographers. Aplite, however, had come into wide use as a textural term applied to rocks of many kinds, usually occurring as dikes, and the name no longer had any precise mineralogical significance. Rocks of granitic texture and habit, consisting essen- tially of quartz with orthoclase or other alkali feldspar, have proved to be so widespread and to constitute such important masses, particularly in Nevada, that Spurr's proposal is amply justified. The name alaskite is already familiar to the mining men of that State. By the addition of black mica alaskite may grade into biotite granite (granitite), a transi- tion which, as will presently be shown, is exemplified in the Goldfield district. In a simple field classification the alaskite might properly be called granite, this name in such usage designating any quartz-feldspar rock of visible and even grain. DISTRIBUTION. As may be seen from the geologic map (PI. II) the principal exposures of granitic rocks are in the central part of the district, especially in the vicinity of Columbia, Vindicator, and Banner mountains. Two exceptional occurrences deserve mention, although they are too small to appear on the map. One mass, discovered in a prospect on the north slope of Black Butte, is apparently a block a few feet in diameter, inclosed in andesite. The other mass, the visible portion of which is about 10 feet (3 meters) in diameter, occurs in the northwestern corner of the area mapped in Plate II, close to the small patch of rhyolite crossed by the line of the electric power company in section 15. This also may be a loose block, as it is surrounded by the sedimentary deposits belonging to the Siebert formation, which is probably some hundreds of feet thick at this point. This supposition seems more probable than the alternative one, that the mass is the top of a sharp alaskite hill projecting through the sediments. The trans- portation of large blocks of pre-Tertiary rock by the lava flows which inundated the district at several periods in its later geological history is not inherently improbable. Underground, alaskite has been cut in the Sandstorm mine on the 400-foot level, about 290 feet (88 meters) southeast of the shaft. PETROGRAPHY. The rock of the Columbia Mountain areas is evenly granular, consisting wholly, so far as can be seen without the microscope, of xenomorphic 9 crystals of quartz and feldspar. The a Walcott, C. D., Second contribution to the Cambrian faunas of North America: Bull. TJ. S. Geol. Survey No. 30, 1886, p. 38. 6 Spurr, J. E., Descriptive geology of Nevada south of the fortieth parallel: Bull. U. S. Geol. Survey No. 208, 2d ed., 1905, p. 185. cBall, S. H., A geologic reconnaissance of southwestern Nevada and eastern California: Bull. U. S. Geol. Survey No. 308, 1907, p. 66. dBall, S. H., op. cit., p. 57. « Op. cit., pp. 51, 56, 66. /Classification of igneous rocks according to composition: Am. Geologist, vol. 25, 1900, pp. 229-232. sSo far as practicable the textural terms applied to rocks in this report are those proposed or recommended by Cross, Iddings, Pirsson, and Washington in their paper "The texture of igneous rocks" (Jour. Geology, vol. 14, 1906, pp. 692-707). 79145— No. G6— 09 3 34 THE GEOLOGY AND ORE DEPOSITS OF GOLDFIELD, NEVADA. average diameter of the grains is rather less than 5 millimeters, although some of the feldspar crystals are occasionally larger and show a slight tendency toward porphyritic development. The prevailing color is light reddish, the tint being due to microscopic flecks of hematite in the feldspars. Some of the rock, however, is nearly white. Thin sections show that over 95 per cent of the rock consists of quartz and microperthitic orthoclase. In addition to these minerals there is a little sodic oligoclase and small scattered plates of what was probably once biotite, but is now an aggregate of a faintly greenish mica with the birefringence of muscovite, and epidote. The feldspars are fairly fresh and the rock has undergone no appreciable dynamometamorphism since its original solidification. It is a typical alaskite. The alaskite of Columbia Mountain is cut by occasional aplitic dikes of lighter color and finer grain than the mass of the rock. Such of these as were microscopically examined show essentially the same mineralogical composition as the alaskite, although oligoclase is perhaps a little more abundant in them. The main mass of Vindicator Mountain is composed of a moderately coarse reddish alaskite, closely resembling that of Columbia Mountain and made up chiefly of quartz and orthoclase. In many places the rock is silicified or kaolinized. On the eastern slope of the mountain the alaskite passes gradually into biotite granite. This granite, which is well exposed along the road half a mile (0.8 kilometer) northeast of the summit of the mountain, shows a pronounced tendency toward a porphyritic texture, large rounded anhedral crystals of quartz and orthoclase being closely crowded in a rather fine-granular groundmass consisting of the same minerals with oligoclase and biotite. Some of the quartz crystals show the embayed outlines character- istic of granite porphyries. Much of the granite is considerably decomposed, the biotite being altered to chlorite and epidote. The latter mineral has also developed extensively in the feldspars. Titanite and zircon occur as accessory minerals. A similar porphyritic variety, really a granite porphyry, is exposed in a shaft which goes through Vindicator rhyolite into the granite at a point half a mile (0.8 kilometer) east of the summit of Vindicator Mountain. This f acies has a reddish tint from the abundant phenocrysts of red orthoclase. The other visible crystals are quartz and small dull greenish specks, evidently in part hornblende. The microsope shows large turbid crystals of microperthitic orthoclase, rounded and embayed ones of quartz, some automorphic green hornblende, abundant pseudo- morphs of chlorite and epidote after biotite, some irregular grains of titanite, and a little plagioclase. There is also some pyrite. The orthoclase shows incipient sericitization. The alaskite of Vindicator Mountain, particularly on the ridge south of the summit, contains numerous small dikelike masses of an aphanitic rock which has a much-altered and bleached appearance. The microscope shows a compact aggregate of quartz and other secondary minerals with no recognizable igneous characteristics. The masses may possibly represent rhyolitic dikes but their original character can only be surmised. The rock of the various smaller areas shown on the geologic map (PL II) is in most cases too decomposed for satisfactory microscopical study. Most of them are composed of typical alaskite, with no mica. Biotitic facies occur, however, in the masses exposed north of Banner Mountain and east of Vindicator Mountain. GEOLOGIC RELATIONS. The alaskite and granite are intrusive into the Cambrian shale. (See PI. V, B.) The intruding magma appears to have been highly viscous and some of the exposures on Columbia Mountain indicate that the alaskite had in some places solidified in contact with the shale before the general movement of the magma had ceased. In other words, the contact, while clearly of intrusive character, is accompanied by brecciation of both shale and alaskite. What- ever rocks may have overlain the shale at the time of intrusion were removed by erosion prior to the outbreak of Tertiary volcanism. The opening of that epoch found the Goldfield region eroded to a tract of low relief floored with alaskite and granite, within which lay a few residual patches of Cambrian shale. U. S. GEOLOGICAL SURVEY PROFESSIONAL PAPER 66 PLATE V m A. COLUMBIA MOUNTAIN; FROM THE SOUTH. The top of the mountain is Vindicator rhyolite. The two sharp knobs at the right are silicified dacite. Dark areas near the base of the mountain are Cambrian shale. B. CAMBRIAN SHALE (DARK ROCK) CUT BY ALASKITE (LIGHT ROCK). South slope of Columbia Mountain. PRE-TERTIARY ROCKS. 35 AGE. The age of the alaskite and granite intrusion is not definitely determinable from local relations. These indicate merely that the rock is post-Cambrian and is older than the Tertiary eruptives. Clarence Kinga many years ago advanced the opinion that the ranges of western Nevada and the Sierra Nevada are of contemporaneous origin and that their granitic intrusions are of early Cretaceous age. The post- Jurassic age of the Sierra Nevada batholith has long been well established, and the reconnaissances made by J. E. Spurr6 and S. H. Ball c with the study of the Humboldt region by G. D. Louderbackd all support the view of King as to the contemporaneous age of the principal granitic intrusions of the Nevada ranges. The alaskite of the Goldfield district can therefore be considered with some confidence as belonging to the early Cretaceous period. a U. S. Geol. Expl. 40th Par., vol. 1, 1878, pp. 733-754. f> Descriptive geology of Nevada south of the fortieth parallel: Bull. U. S. Geol. Survey No. 208, 2d ed., 1905. See also, The ores of Goldfield, Nevada: Bull. U. S. Geol. Survey No. 200, 1905, p. 133. <" A geologic reconnaissance in southwestern Nevada and eastern California: Bull. U. S. Geol. Survey No. 308, 1907. d Basin Range structure of the Humboldt Region: Bull. Geol. Soc. America, vol. 15, 1904, p. 336. CHAPTER IV. DESCRIPTION OF THE PRELACUSTRINE TERTIARY IGNEOUS ROCKS. INTRODUCTION. Definite assignment of all of the various lithologic units composing the volcanic series at Goldfield to the standard divisions of Tertiary time is not yet possible and may never be effected. The general post-Mesozoic age of the volcanic rocks of the Great Basin has, however, been so firmly established by von Richthofen, King, and later investigators as to be generally accepted as one of the basal facts of the geologic history of the region. In the vicinity of the fortieth parallel, King ° was able, by reference to the Miocene sediments of Pahute Lake and the Pliocene beds of Shoshone Lake, to determine the divisions of the Tertiary to which many of the lavas belong. In the Tonopah district Spurr, b by the help of the Siebert sediments, whieh he tentatively correlated with those of King's extinct Miocene Pahute Lake, was also able to reach some con- clusions as to the age of the several eruptions. The extent to which similar results are attainable in the Goldfield region will be fully discussed in a subsequent chapter. For the present it is enough to keep in mind the fact that a group of lake sediments, equivalent to and very probably once continuous with the Siebert tuff of Tonopah, occurs in the Goldfield district. They record a distinct lacustrine epoch initiated and terminated by deformation and erosion. It is thus possible to divide the Tertiary rocks of the district into three natural groups divided by conspicuous unconformity. These are: (1) the prelacustrine flows and intrusions, (2) the lake beds and associated volcanic rocks, and (3) the postlacustrine volcanic rocks. The correlation of these groups with the rocks of other districts and the discussion of their geologic chronology will be deferred until the rocks them- selves have been described. The prelacustrine rocks in the order of their eruption are: (1) the Vindicator rhyolite, (2) latite, (3) the Kendall tuff, (4) the Sandstorm rhyolite, (5) the Morena rhyolite, (6) the Milltown andesite, (7) dacite, (8) dacite vitrophyre and the Chispa andesite, (9) the Meda rhyolite, and (10) andesite breccia. In the preliminary report c on the district, written in advance of chemical and full petro- graphic study, the latite was called the "first or earlier andesite" and was made to include most of the altered rock now called Vindicator rhyolite. In the present stage of the science of petrology the consistent treatment in an economic report of any varied eruptive series presents peculiar difficulties. The ordinary classification and nomenclature of igneous rocks which has grown up in the half century since Sorby applied the microscope to their study has the recognized defects of most structures built from old materials and added to at various times. It has become unsatisfactory both to the general geologist and to the petrologist. The modern quantitative system of classification, while logical, refined, and accurate, is adapted rather to the needs of the specialist than to those of the field geologist or engineer. On the other hand, simpler schemes for classifying rocks without the use of the microscope, such as that recently presented by Pirsson,d are not adequate to express the facts developed in an investigation like the present, in which field observations have been supple- mented by microscopical and chemical work. In view of these considerations the older petro- graphical classification, exemplified in the Elemente der Gesteinslehre and Mikroskopische « V. S. Geol. Expl. 40th Par., vol. 1, 1878. 6 Geology of the Tonopah mining district, Nevada: Prof. Paper U. S. Geol. Survey No. 42, 1905. <■ Bull. U. S. Geol. Survey No. 303, 1907. d Pirsson, L. V., Rocks and rock minerals. New York and London, 1908. PRELACUSTRINE TERTIARY IGNEOUS ROCKS. 37 Physiographie of Rosenbusch, has, nothwithstanding its defects, been generally followed in this report. In addition, the position in the quantitative system has been given of such unaltered rocks as have been chemically analyzed. VINDICATOR RHYOLITE. GENERAL CHARACTER AND OCCURRENCE. The oldest member of the volcanic series derives its name from Vindicator Mountain and is most extensively exposed on the flanks of that peak. As may be seen from Plate II, the central pre-Tertiary mass of the mountain is surrounded by the rhyolite on all sides except the southeast, the exposure attaining a width of nearly half a mile on the north. A small mass of much-silicified rock, probably a remnant of the rhyolite, rests on the summit of the peak. What is supposed also to be a larger residual of the same flow caps Columbia Mountain. The rock is nowhere fresh, and as a rule contains abundant alunite, the mineral being in many localities distinctly visible in freshly broken fragments of the rock as small pale-pink crystals. Much of the altered rhyolite is very hard and forms prominent outcrops, often with characteristic pitted surfaces, due to the solution and removal of the pseudomorphs of alunite after feldspar. As the basal member of the Tertiary volcanic series the Vindicator rhyolite rests upon an undulating surface of alaskite and Cambrian shale. The character of the rock shows it to have been effusive. The base of the flow is well exposed half a mile northeast of the summit of Vindicator Mountain, where a nearly white altered rock may be seen lying upon a slightly rolling surface of biotite granite. The latter shows only slight superficial weathering and appears to have been swept clean of loose detritus before the first Tertiary eruptive. The basal portion of the flow contains many fragments of the underlying granite as well as of the dark Cambrian shale. Considerable alteration has taken place in the volcanic rock near the contact, it being bleached to a delicate pale-green tint and in places intensely silicified. This silicification is related to a fairly regular system of fissures which strike about N. 30° W. and dip northeast, giving a sheeted structure to the rhyolite. These fissures do not show in the underlying granite. The solutions which effected the silicification probably worked their way along the contact between the two rocks and ascended in the parallel fissures. The most intense alteration borders these cracks, which are in many places very narrow and were not themselves filled with quartz. The rhyolite on the summit of Columbia Mountain was originally supposed to be part of the intrusive mass of Morena rhyolite which forms the ridge to the north. It is, however, distinctly a capping, and prospect shafts near its edge have shown it to rest on the Cambrian shale. At the north end of the oval cap (PI. II) a small pit, open in 1905, exposed the base of the rhyolite, which is here separated from the shale by a foot or more of gravelly material containing fragments of alaskite and shale, evidently old surficial detritus. Petrographically the rock of the summit is identical with that on the west slope of Vindicator Mountain, near the Lucky Boys shaft. On the other hand, no very distinct contact has been found between the rhyolite capping Columbia Mountain and the somewhat similar Morena rhyolite to the northwest, which is known to be intrusive. The boundary as drawn on the geologic map (PL II) corresponds to an obscure line of separation which is admittedly unsatisfactory. Nevertheless the preponderance of evidence favors the view that the capping of the mountain is the Vindicator rhyolite which has been intruded on the west by the younger but locally similar Morena rhyolite. A close, irregular intrusive contact between two similar rhyolites might be difficult to recognize even were the surface swept clean of all detritus. There are no exposures from which the thickness of the Vindicator rhyolite can be directly measured. It is evidently far from uniform, as a glance at the map will show. The maximum thickness, as estimated from the general relations and structure illustrated by sections A- A' and D-D', Plate VIII, is probably about 200 feet (61 meters). 38 THE GEOLOGY AND ORE DEPOSITS OF GOLDFIELD, NEVADA. PETROGRAPHY. The weathered surfaces of the Vindicator rhyolite are generally some shade of light gray, although in places they are stained buff or brown by iron oxide. A jutted appearance, already referred to, is characteristic of the harder silicified outcrops. On fresh fracture the rock is white or light gray, usually with a faint pink tint due to the abundant alunite. Some varieties northeast of Vindicator Mountain are pale greenish gray. The rock is everywhere much altered, the only primary mineral recognizable, as a rule, being quartz in fairly abundant anhedral phenocrysts up to 5 millimeters in diameter. Under the microscope the Vindicator rhyolite shows rounded and embayed phenocrysts of quartz and pseudomorphs of alunite after feldspar, presumably orthoclase. Some thin sections show alunite pseudomorphs also after phenocrysts whose outlines are suggestive of mica. The groundmass has the general structure characteristic of rhyolitic glasses, but has undergone complete devitrification and is now a fine-grained aggregate of quartz and alunite, accompanied in some varieties of the rock by smaller quantities of kaolinite. Diaspore has been found in some thin sections, and calcite occurs in a richly alunitic variety of the rhyolite from the east slope of Vindicator Mountain. The general texture of the rock as it appears under the microscope is shown in Plates XXVIII and XXXI. A good place to study the alunitic alteration of the rhyolite is on the east shoulder of Vindicator Mountain, about a quarter of a mile from the summit. Some of the rock here is nearly white, mottled with spots and rings of pale-pink alunite. Some specimens also show minute, faint-blue specks which have not been identified with any mineral observed in thin section. A chemical analysis of this rhyolite (specimen G. 333) is given on page 183 in connec- tion with a full discussion of the character of its alteration. The rock capping Columbia Mountain also illustrates particularlv well the pseudomorphous development of alunite after feldspar. (See PI. XXVIII.) In the simple field classification suggested by Pirsson the Vindicator rhyolite would be called a felsite. The rock is too much altered to be assigned a place in the quantitative system. LATITE." GENERAL CHARACTER AND OCCURRENCE. The latite, as may be seen from Plate II, occupies the greater part of an area a little over 2 miles (3 kilometers) in diameter in the center of the district, and a smaller area south of Columbia. Its characteristic features may be well seen on Banner Mountain, in the vicinity of McLaughlin's well, and on the southern edge of the town of Columbia. This rock has not been found in a fresh condition. Its normal color is dull purplish or greenish gray. A spotted or mottled appearance, due to flow-brecciation, is rather characteristic and is well shown on a small hill half a mile (0.8 kilometer) north of the summit of Banner Mountain. The freshest obtainable specimens of the latite show phenocrysts of feldspar, hornblende, and mica in a com- pact, streaky groundmass that was evidently once a glass with well-marked fiowage lines. All the phenocrysts have the dullness that indicates more or less thorough alteration, and the original glassy base is now devitrified. As a rule, the latite, when it has not been subjected to the intense local alteration connected with ore deposition, may be distinguished from the later andesitic rocks b}T the absence of fresh phenocrysts, and especially by the peculiar streakiness of its groundmass, which resembles the groundmass of a rhyolite rather than that of most andesites. Even intense alteration does not always obliterate this feature. The much-altered latite has frequently been mistaken for dacite, and probably no amount of experience will insure even a keen observer against occasional errors of this kind. The altered latite may contain blebs of secondary quartz, but these are usually of lighter tint and less homogeneous than the primary quartz of the dacite. Little vugs, with projecting quartz crystals, are rather characteristic of the alunitized and pyritized latite. o The "earlier andesite" of the preliminary report. PRELACUSTRINE TERTIARY IGNEOUS ROCKS. 39 The rock is apparently a flow resting upon a rather uneven surface of alaskite, Cambrian sediments, and Vindicator rhyolite. Its thickness is not known, but is probably very variable, as on Columbia Mountain the succeeding rhyolite rests directly upon the alaskite. The maxi- mum thickness is tentatively estimated at 300 feet (91 meters). Although the latite is pre- vailingly massive or exhibits only moderate flow brecciation, a west crosscut on the 612-foot level of the Combination-Fraction shaft has exposed some altered pyroclastic rock which appears to belong to this formation. The latite underlies a large part of the district, but is exposed only where deformation followed by extensive erosion has stripped away the rocks that once covered it. As might be expected from its place in the local geologic column and the general domical structure of the district, the rock occurs in the central part of the area studied, encircling the exposed masses of alaskite, Cambrian shale, and Vindicator rhyolite. Banner Mountain lies ahnost in the center of the largest expanse of the latite. This tract, while roughly circular, has a very irregular outline expressive not only of the usual inequalities of erosion, but also of the nearly hori- zontal undulating contact between this rock and those that overlie it. A smaller area of latite is exposed just south of the town of Columbia, and a very small exposure at the northwest end of the same town is worthy of mention, since it shows the latite overlain by the Sandstorm rhyolite. When the district was studied in 1905 the presence of latite under the andesite south and southeast of Florence Hill could only be inferred. At present several shafts go through the andesite into the latite. The Yellow Tiger, situated a mile southeast of Milltown, went into latite at a depth of about 510 feet (155 meters), showing that this formation extends southward beneath the andesite for at least three-quarters of a mile (1.2 kilometers) from its nearest surface exposure. The developments of the past three years have proved, moreover, that the latite in general underlies the dacite of the Mohawk, and other important mines near Goldfield at a maximum depth of about 700 feet (213 meters). The only part of the district where the base of the latite is visible is in the vicinity of Vin- dicator Mountain. The contact with the underlying rocks, however, is so poorly exposed and so obscured by alteration that no detailed observations on its original character are possible. The fact that the latite in some places, as on Banner Mountain, is in direct contact with the alaskite suggests that there may have been considerable erosion whereby the Vindicator rhyolite was in part removed prior to the latitic eruptions. On the other hand, the Vindicator rhyolite may never have covered all of the old alaskite surface. It is possible, moreover, that the jux- taposition of the latite and alaskite along the south slope of Vindicator Mountain may be due to a fault nearly parallel to and northwest of the one shown (PI. II) half a mile northwest of Banner Mountain. While the relation of the rocks suggests such a fault the evidence for its existence is hardly sufficient to warrant placing it on the map. In regard to the relations of the latite south of Columbia to the older rocks little definite information is available. The mass is overlapped on the west, south, and partly on the east by the younger Siebert formation, under which it is known to extend for over half a mile (0.8 kilometers) to the south. On the north it is in contact with Kendall tuff, the contact corre- sponding to a fault. PETROGRAPHY. The normal tint of the latite is dull gray with a suggestion of lilac or purple. Some varie- ties, however, are dull mottled gx-een and where local alteration has been intense the rock may be yellow, pale pink, light green, or white. More or less alteration has invariably taken place, and none of the rock has the dark-gray color and glistening phenocrysts characteristic of the later andesitic and basaltic rocks of the region. Surfaces of fresh fracture show numerous small dull-white phenocrysts of feldspar, with much less conspicuous darker phenocrysts rep- resenting some altered femic mineral, in a dense finely streaked groundmass, which on close inspection reveals the pasty flow-texture frequently found in rhyolite, but not common in latitic or andesitic rocks. At many localities, particularly in the vicinity of McLaughlin's 40 THE GEOLOGY AND OEE DEPOSITS OF GOLDFIELD, NEVADA. well and north of Banner Mountain, the rock is decidedly mottled, and close examination shows it to be a flow breccia in which the fragments are of the same general character as the matrix, although some slight difference in texture is sufficient to produce delicate color dis- tinctions in weathering. In this respect also the rock resembles rhyolite. Under the microscope the latite shows a vitrophyric texture, phenocrysts of plagioclase, biotite, and hornblende lying in a glassy groundmass which shows the characteristic wavy and curled flowage lines associated with this textural type. Apatite, magnetite, and zircon are accessory constituents. The phenocrysts are never quite fresh. The plagioclase, which is andesine-labradorite with approximately the composition AbtAnl; is changed to quartz, alunite, calcite, sericite, and kaolinite. The relative proportions of these secondary minerals as well as the degree of alteration or replacement varies in different specimens, even in those from the same locality. Quartz is the most abundant mineral formed at the expense of the feldspars, although calcite is scarcely less common. Sericite is decidedly subordinate to quartz and calcite, and kaolinite is rather rare except with alunite in cases of special alteration in the vicinity of ore bodies. It is apt to be more abundant in the altered groundmass than in the phenocrysts. As a rule, the feldspar is only partly altered, a portion of the crystal being replaced by quartz or calcite or both, while another portion remains as limpid and fresh in appearance as in the younger basalts of the region. The replacement is usually sharp and complete, with no intervening stage or zone of turbidity in the feldspar as seen under the microscope. The alteration does not necessarily proceed from the periphery of a crystal toward its center. Many feldspar phenocrysts, especially those which originally contained glass inclusions, are changed to quartz and calcite in their central parts while still retaining an outer shell of fresh andesine. Only a very few remnants of fresh biotite and no hornblende were found in the 40 to 50 specimens of this rock microscopically examined. The most cbaracteristic change in the biotite is a bleaching, whereby the mineral becomes pale green or colorless and resembles muscovite in birefringence. This form of alteration is associated with the development of particles of magnetite and hematite, which in some pseudomorphs are so thickly crowded as to render them practically opaque and in others are gathered into a dark peripheral shell. This shell, defining the outline of the former phenocryst, is as a rule persistent and may remain when the rock has been wholly altered to a granular aggregate of quartz. The common alteration of biotite into chlorite interlaminated with lenses of epidote is also represented in some specimens. The former presence of hornblende as an original constituent of the rock is indicated by pseudomorphs of quartz, calcite and iron oxides possessing the characteristic prismatic sections of that mineral. Most of these pseudomorphs, like those after biotite, are enveloped in dark shells of iron oxides. It is possible that some pyroxene may also have been present in the original rock, but no pseudomorphs definitely referable to this mineral have been detected. The groundmass of the latite was originally glassy, containing only incipient crystal forms. In the rock of the small outcrop at the northwest end of Columbia the groundmass shows a faint spherulitic structure. Elsewhere it exhibits the ordinary flow banding of a pasty microlitic glass. Very little, if any, of this glass now remains. It has not only devit- rified, or become crystalline, through lapse of time and through conditions of pressure and temperature favoring such molecular rearrangement, but has also been altered by the same agencies that have changed the phenocrysts to aggregates of secondary minerals. The boun- dary between endogenous devitrification and the processes that have altered the phenocrysts is not a sharp one. Simple devitrification, however, involves no essential change in the com- position of the rock, whereas in the more pronounced phases of general alterations, such as have in some places changed the latite to an aggregate of quartz with very subordinate kao- linite and pyrite, there has been a notable change in the chemical constitution of the rock as well as in its mineralogical character. The most abundant secondary mineral in the groundmass is quartz. Calcite also is com- mon, while kaolinite and sericite are rather rare. Alunite is abundant in the vicinity of the PRELACUSTRINE TERTIAEY IGNEOUS ROCKS. 41 ore deposits. Where the alteration has not been extreme, the groundmass shows little bunches of quartz and calcite interspersed through a faintly crystalline groundmass in which the con- stituent crystals are too minute for identification. Where alteration has been most thorough, this groundmass is transformed to a distinctly crystalline granular aggregate of quartz. Owing to its generally altered condition the latite has not been subjected to complete chemical analysis. A partial examination by Dr. E. C. Sullivan, however, of a specimen collected 1 mile northwest of McLaughlin's well affords tho following results: Partial chemical analysis of latite. Si02 61. 14 CaO 5. 60 K,0 3. 90 Na20 3. 26 The specimen analyzed (G. 348) has a dull olive-gray tint and is fresher than most of the rock. It contains phenocrysts of andesine or labradorite (A^AnJ partly altered to calcite; of biotite changed to chlorite, quartz, epidote, and calcite; and of hornblende (and possibly augite) replaced by pseudomorphs of calcite, quartz, and magnetite. The groundmass is the usual obscurely crystalline aggregate resulting from the devitrification of a glassy base. The rock contains a few minute crystals of pyrite. The partial analysis shows that it is a latite rather than an ordinary andesite, and the use of the special name is convenient to distinguish the rock from the andesites proper that occur higher in the volcanic series. The general alteration which the latite has undergone, while probably broadly related to the economic mineralization of the district, is not always intimately associated with individual ore deposits, nor is it confined to those particular parts of the district where ore bodies are known to be present. On the southern edge of the town of Columbia the latite has been altered to a white, porous chalky rock which has been quarried for building stone. Under the microscope this shows almost no trace of its original igneous texture, but is chiefly a very fine-grained aggregate of kaolin with some quartz, alunite, and sericite. Certain phases of intense or local alteration of this and other rocks, in the immediate vicinity of the ores, are reserved for fuller treatment in a later chapter in connection with the description of the ore deposits. KENDALL TUFF. The Kendall tuff, which takes its name from the Kendall mine, is of uniform character and as a rule is easily distinguished from the much younger tuffaceous beds of the Siebert for- mation, with which it is in places in contact. As taken from mine workings where oxidation has not penetrated, the body of the tuff is rather dark gray and has an andesitic appearance. This gray matrix is flecked with irregular pale-green spots, usually less than half an inch in diameter, of a soft waxy material which sometimes contains small scales of biotite. When slightly weathered the tuff is a shade lighter in color and the green spots become yellowish. As exposed and quarried on the north edge of the town of Columbia, the tuff is light gray with a rather faint greenish mottling instead of the more distinct spots seen elsewhere. As a rule the tuff contains few visible rock fragments, but pebbles of alaskite, andesite, and rhyolite have been found in it and in some places are moderately abundant. Well-rounded bowlders of alaskite up to 6 inches (15 centimeters) in diameter were observed embedded in the tuff on the dump of the Winston lease shaft, on the Mohawk No. 1 claim, southeast of Columbia. Similar bowlders, as well as fragments of rhyolite, are common also at a depth of 213 feet (65 meters) in the tuff of the Gold Sovereign prospect, half a mile (0.8 kilometer) north of McLaughlin's well. The largest area of the tuff associated with the Sandstorm rhyolite is that partly under- lying the town of Columbia. Another body is inclosed in the rhyolite at the Kendall mine 42 THE GEOLOGY AND ORE DEPOSITS OF GOLDFIELD, NEVADA. and sonie smaller included masses occur on the lower western slope of Columbia Mountain. Tuffaceous beds or layers are also found in some of the shafts sunk in the Sandstorm rhyolite. The microscope shows the tuff to be everywhere more or less altered and to consist of fragments of glassy rhyolite and of latite or andesite. The rock is apparently of mixed deriva- tion and can not properly be called either a rhyolite or a latite tuff. On account of the alter- ation it is not possible to identify the latitic fragments with certainty, but it is probable that they were derived from the latite of the district. The rhyolitic eruptions presumably broke through this rock at certain points with explosive violence and comminuted fragments of the latite were thus mingled with rhyolitic particles. The finding of occasional fragments of alaskite in the tuff lends support to this view. Many of the rhyolite particles in the tuff con- tain abundant quartz phenocrysts, and as such phenocrysts are not common in the Sandstorm rhyolite these particles may also have been derived from an older rock, probably from the Vindicator rhyolite. On the other hand, the tuff also contains angular fragments and blocks up to a foot (0.3 meter) or more in diameter of the Sandstorm rhyolite, as may be seen in the Black Rock shaft about 500 feet (152 meters) west of the Conqueror mine. The rhyolite-latite tuff is very closely associated with the Sandstorm rhyolite, next to be described, and is to be regarded as a practically contemporaneous deposit. It is apparently not a continuous formation, but probably accumulated in local basins at more than one period during the rhyolitic eruptions. The greater part of the tuff, however, is near or at the base of the rhyolite, and for this reason is first described. The large area of tuff near Columbia is considered to occupy an approximately basal posi- tion with reference to the Sandstorm rhyolite, although were this the only body of the Kendall tuff it would be difficult to say whether it overlies or underlies the rhyolite to the north of it. It is possible that the contact between the two may in part be due to faulting. The two small patches farther north, on the west slope of Columbia Mountain, appear to be small lenticular masses in the rhyolite. The body of tuff at the Kendall mine may also be a lens with Sand- storm rhyolite beneath it as well as above it but the base was not exposed in the mine workings at the time of visit. (See fig. 29, p. 237.) The main Sandstorm shaft, not accessible at the time of visit, is reported to have gone from Sandstorm rhyolite into Kendall tuff at a depth of 200 feet (61 meters) and to have continued in this rock for another 200 feet to the bottom. A shaft close to the road, about 500 feet (152 meters) east of the Sandstorm shafts, pene- trates 100 feet (30 meters) of glassy banded rhyolite and exposes 25 feet (7.5 meters) of tuff at the bottom. The tuff is overlain nearly horizontally by the rhyolite but its base is not reached by the shaft. The Black Rock shaft, 500 feet west of the Conqueror mine, exhibits a similar relation of rhyolite to tuff. The bottom of this shaft, which was about 100 feet (30 meters) deep at the time of visit, is in rhyolite-latite tuff, here containing large angular blocks of rhyolite. The tuff is overlain by about 80 feet (24 meters) of glassy spherulitic rhyolite and rhyolite flow breccia, including layers of the shalelike variety of the Sandstorm rhyolite. The rocks are devitrified and altered and the planes separating tuff from flow breccia and volcanic glass are indistinct, much of the glassy rhyolite having a clastic, sedimentary aspect. At the Gold Sovereign mine, already referred to, the shaft after going through a slight thickness of shaly Sandstorm rhyolite continued for 200 feet (61 meters) in greenish bedded tuffs which on account of their lithologic character and stratigraphic position are correlated with the Kendall tuff. The material here contains abundant fragments of alaskite and rhyo- lite with small particles of Cambrian shale in its lower part and rests on an uneven surface of granite or alaskite. As exposed in a crosscut east of the shaft on the 213-foot level the contact, which apparent y is not a fault, dips to the west at about 45°. The relations of the tuff to the latite and Vin icator rhyolite in this locality are not fully understood. While the oldest rhyolite appear;, in this part of the district, to have never covered or to have been eroded away from the granit » before the eruption of the latite, it is difficult to account for the local absence of the latter fo mation at the Gold Sovereign mine, particularly as the latite is the prevailing rock for more han a mile (1.6 kilometer) north of McLaughlin's well (see PI. II) and prior to PRELACUSTRINE TERTIARY IGNEOUS ROCKS. 43 the sinking of the shaft was supposed to continue under the small residual areas of Sandstorm rhyolite. It seems necessary to conclude: (1) That revision of the mapping would show some Kendall tuff outcropping around the edges of the small patches of Sandstorm rhyolite, a fact easy to overlook on account of the poor exposures and the general similarity of the weathered %u$ to some varieties of the latite. Such overlooked areas can not be large, inasmuch as typi- cal latite occurs north of McLaughlin's well and both east and north of Banner Mountain. (2) That the old granitic surface is locally irregular and was in part exposed after the erup- tion of the latite and before the deposition of the Kendall tuff, the latter being laid down on a surface that was also diversified by hillocks and hollows. Excellent exposures of the Kendall tuff may be studied in the railway cuts along the south slope of Columbia Mountain. The beds here have a dip of 45° SW. SANDSTORM RHYOLITE. GENERAL CHARACTER AND OCCURRENCE. Overlying the latite and most of the Kendall tuff or, in places where the earlier volcanics are absent, resting on the pre-Tertiary rocks, are some thin, originally glassy rhyolite flows which attain their greatest development in the rounded white hills northwest of Columbia Mountain. This effusive rhyolite is usually nearly white, shows conspicuous flow lamination, and weathers in thin, shelly flakes. It is the rock of the Sandstorm mine, whence its name, and of the hills lying west of the road from the mine to Columbia. It all shows some devitrification and silicification, particularly in the vicinity of the ore deposits. Certain varieties or portions of this rhyolite acquired by flowage a very thin lamination, causing the rock when somewhat weathered to closely resemble indurated clay shale. This appearance is exceedingly decep- tive, as may be seen at the Conqueror (Tonopah Club) mine. The town of Diamondfield is partly underlain by this shalelike rhyolite, and small residual patches of a similar material are scattered over the surface of the latite northeast of Banner Mountain. (See PI. II.) The rhyolite appears to have been thickest in the vicinity of Columbia Mountain and to thin out to the southeast. None of it has been found southeast of McLaughlin's well. The largest area of the Sandstorm rhyolite is that extending from the vicinity of the town of Columbia northward to the south base of Kendall Mountain. Another body, probably con- nected with the Sandstorm mass under the intervening Milltown andesite (see PI. II), contains the Adams and Tonopah Club mines, southeast of Kendall Mountain. The northwestern half of the roughly circular main area of latite is fringed with small patches of the Sandstorm rhyolite. This is for the most part the shaly variety and its outcrops are inconspicuous, the presence of the rock being indicated in most instances merely by the thin loose flakes, resem- bling gray shale, into which the rhyolite disintegrates on weathering. A rather more resistant variety forms some low hills about half a mile southeast of Black Butte, and a few small residual outliers, chiefly of the shaly form, are scattered over the latite north of McLaughlin's well. The area between Diamondfield and Black Butte, on the other hand, is probably an inlier, a small rhyolite hill projecting through the younger Milltown andesite. That the Sandstorm rhyolite is younger than the latite was a conclusion reached in 1905 from the relative distribution of the two rocks as shown in Plate II. At that time also the dumps of two abandoned shafts — one half a mile S. 5° E. from the summit of Vindicator Mountain and just south of the road to McLaughlin's well, the other on the west slope of the mountain — indicated that the shaly Sandstorm rhyolite had been penetrated and latite found below. In 1905 a shaft half a mile (0.8 kilometer) southeast of the top of Vindicator, after going through about 50 feet (15 meters) of Milltown andesite, had continued for another 50 feet into soft, altered, rhyolitic flow breccia with streaks of dark devitrified glass, the whole looking remarkably like a gray tuffaceous sandstone with thin layers of shale. The bottom at the time of visit was in shaly rhyolite. In 1908 this shaft had been abandoned, but the dump showed that the rhyolite had been penetrated and latite found beneath it. 44 THE GEOLOGY AND ORE DEPOSITS OF GOLDFIELD, NEVADA. The Sandstorm rhyolite north of Columbia probably rests for the most part on Kendall tuff, which in turn appears to occupy one or more depressions in the alaskite. The irregularity of the pre-Kendall surface is well shown at the Mayne shaft, 1,500 feet (457 meters) northwest of the summit of Columbia Mountain, near the eastern edge of the largest area of alaskite. (See PL II.) Although only about 200 feet (61 meters) from the outcrop of the alaskite, this shaft was sunk 100 feet (30 meters) before reaching that rock. In the southeast crosscut on the 400-foot level of the Sandstorm mine the Kendall tuff, according to Mr. H. C. Cutler, the superintendent, was found resting upon a slope of alaskite, which dipped about 50° W. To what extent this irregularity is the result of faulting since the eruption of the Sandstorm rhyolite can not be determined from the scanty data available. At the northwest end of Columbia town one small and rather obscure exposure shows rhyolite of the shaly variety dipping west and apparently overlying latite. The relation of these rocks to the Kendall tuff at this place is not clear. At the Sandstorm shaft the rhyolite has a thickness of 200 feet (61 meters). This is not a maximum, as at least another hundred feet is represented by the hill which rises southwest of the shaft. A single measurement, moreover, owing to the uneven surface upon which the rock rests and the disturbance introduced by the subsequent intrusion of the Morena rhyolite, throws little light upon the average thickness. It is thought probable that the Sandstorm rhyolite may attain a maximum thickness of 300 to 400 feet (91 to 122 meters) northwest of Columbia Mountain. Around Vindicator and Banner mountains it thins to less than 100 feet (30 meters), and southeast of McLaughlin's well disappears, the Milltown andesite resting upon the latite. Although the Kendall tuff and Sandstorm rhyolite are separately mapped and successively described, their intimate relationship should not be lost sight of. They probably belong to the same eruptive epoch and are to some extent intermingled. PETROGRAPHY. As exposed in the principal area, northwest of Columbia Mountain, the Sandstorm rhyolite is a nearly white rock with fine, often much contorted flow banding. Under the influence of weathering, the rhyolite splits along this flow lamination into thin shelly flakes, somewhat resembling disintegrated shale. Much of the surface of the low, rounded, white hills between Columbia and the Sandstorm mine is covered with this flaky detritus. Locally, as near the Sandstorm and Kendall mines, the rhyolite is intensely silicified and outcrops as cellular masses of nearly pure quartz. Phenocrysts are small and inconspicuous, consisting chiefly of feldspar. The abundant groundmass was once highly glassy, and in some localities still shows small spherulites and lithophyses. The delicate fluxion lines in this groundmass are very character- istic of the Sandstorm rhyolite and, in connection with the paucity of quartz phenocrysts, serve to distinguish the rock from the younger and intrusive Morena rhyolite. The general dull-white appearance of the rhyolite is sufficient to show that the rock no longer retains its original glassy condition, but has crystallized into secondary aggregates. Microscopical inves- tigation confirms this conclusion. Seen in thin section under the microscope, the Sandstorm rhyolite shows phenocrysts of sanidine in a groundmass which, in addition to the wavy flow lines visible in hand specimens, frequently exhibits delicate reticulating and spiral cracks, the typical perlitic structure of siliceous volcanic glasses. The glass itself, however, as may be seen between crossed nicols, has devitrified and is now represented by an exceedingly fine-grained aggregate, consisting chiefly of quartz, but containing also some chalcedony or opal, kaolin, and probably other minerals not optically determinable. Some specimens show remnants of mica, probably biotite, and occasional altered crystals of sodic plagioclase. Quartz phenocrysts, while not entirely absent, are rare and inconspicuous. Zircon occurs sparingly in the usual small rounded grains and prisms. A large part of the rhyolite shows more intense alteration than can be ascribed to simple devitrification. Such rock, for example, as that which lies along the ridge between the Sand- PRELACUSTRINE TERTIARY IGNEOUS ROCKS. 45 storm and Kendall mines and forms several craggy points south of the former property, con- sists for the most part of a crystalline granular aggregate of quartz, which, although aphanitic, is of less fine grain than the usual product of devitrification. With the quartz may occur considerable kaolin, silicification and kaolinization clearly having gone on simultaneously. Alunite is also fairly abundant and in some specimens occurs with quartz as distinct pseuclo- morphs after sanidine. In the most altered varieties the phenocrysts and some of the glassy bands or streaks in the groundmass have been dissolved and the cavities thus formed lined with druses of quartz. Such rock is rough and cavernous. Being composed of almost pure quartz, it is resistant of decay and forms most of the prominent outcrops in the rhyolitic area. About 900 feet (275 meters) east of the Sandstorm mine, the rhyolite, near its contact with the overlapping Milltown andesite, has a more regular lamination than is usu"! Li th3 area just described, and splits, on exposure to the weather, into thin gray flakes which might easily be mistaken for shale. Close observation, however, reveals irregularities in the lamina- tion which show it to be a flowage phenomenon, and microscopical examination renders it certain that the rock is a devitrified glassy rhyolite. A similar shaly facies occurs at the south- ern end of the main rhyolite area and is exposed in the Columbia Mountain No. 2 Tunnel, near its portal. This variety of the rhyolite, however, is much more abundant in an area of the Sandstorm rhyolite presently to be described, namely, that extending from the Adams mine, about a third of a mile (0.5 kilometer) east of the Sandstorm, northeastward past the Con- querer (Tonopah Club) mine. The rhyolite of the small area shown in Plate II, in the northwest corner of the region, is a partly devitrified spherulitic glass. This rock is fresher than in the other areas and con- tains some glass as well as a few phenocrysts of sodic plagioclase. The principal secondary minerals are quartz, chalcedony, and opal. The lithologic character of the shaly facies of the Sandstorm rhyolite is well displayed just north of the Conquerer mine. Much of the material here has the appearance of a white or light-gray shale with a dense porcelain-like texture grading in places into softer chalky- looking varieties. The microscope shows that these are devitrified glasses consisting of very fine grained aggregates of quartz, kaolin, and possibly other minerals. Interlaminated with these aphanitic layers are rhyolite flow breccias containing fragments of white pumice and of devitrified glassy rhyolite. One of the shaly bands, about 1,500 feet east of the summit of Kendall Mountain and close to the contact with the Milltown andesite, contains abundant hollow spherulites or lithophyses up to several inches in diameter. An unusual variety of the rhyolite outcrops prominently just west of the Adams mine. This is a rough porous rock evidently somewhat altered. The microscope shows it to be a devitrified and partly silicified spherulitic glass. Rock of the same character occurs north of the Conqueror mine, and both are probably alteration products of a variety of the rhyolite resembling that from the western edge of the district, described above. The rock of the small areas extending from the west side of Vindicator Mountain to Dia- mondfield is chiefly the gray shaly variety. Just west of Diamondfield, however, are some outcrops of rhyolite flow breccia. Between Diamondfield and Black Butte is an area of devitrified and silicified glassy rhyo- lite ranging from white chalky facies to nearly black flinty varieties. The area mapped as Sandstorm rhyolite between Black Butte and Tognoni Springs is occupied by much altered rock of somewhat doubtful character. Most of the area is littered with the shaly detritus indicative of the presence of the Sandstorm rhyolite and some of the specimens collected are devitrified glassy rhyolite such as is known to occur in that formation. Other specimens, however, contain abundant quartz phenocrysts and resemble the later Morena rhyolite. Still others are undoubtedly much altered latite. It is certain, therefore, that the area as mapped includes rocks of more than one kind, although it is doubtful whether these can be separately mapped, owing to their general alteration and to the unsatisfactory character of the exposures. 46 THE GEOLOGY AND OEE DEPOSITS OF GOLDFIELD, NEVADA. The remaining areas of Sandstorm rhyolite, including the outliers north of McLaughlin's well and the patches south of Vindicator Mountain, are all occupied by the gray shaly variety already described. Many of them, were it not for the relations clearly shown near the Sand- storm and Conqueror mines, would probably, in the absence of microscopical investigation, be taken for sedimentary shales. MORENA RHYOLITE. GENERAL CHARACTER AND OCCURRENCE. The Morena rhyolite is intrusive into the Sandstorm rhyolite and pre-Tertiary rocks, but is older than the Milltown andesite. The presence of this rock on Morena Ridge, the northern spur of Columbia Mountain, has suggested its local name. The principal area of intrusive rhyolite is that shown on Plate II, as extending from near the top of Columbia Mountain northward to the Adams mine. Smaller masses are exposed on the west slope of the mountain and in the vicinity of the Conqueror mine. The irregular intrusion of the Morena rhyolite into the shaly Sandstorm rhyolite is well shown in the Adams and Conqueror mines, the intrusive rock close to the contact being crowded with inclusions of the other. The shaft of the Kendall mine, about 200 feet (61 meters) deep at the time of visit late in 1905, was in the intrusive rhyolite at the bottom, but the contact with the effusive Sandstorm rhyolite was not then visible. A sharp intrusion contact between the Morena rhyolite and Cambrian shale as exposed in a prospect on the west side of Columbia Mountain, near the summit, is shown in Plate VI, A. PETROGRAPHY. The Morena rhyolite is somewhat darker than the Sandstorm rhyolite, being generally gray or buff. As a rule it shows no flow lamination or banding, and contains abundant small phenocrysts of quartz, with less conspicuous feldspars, in a compact lithoidal groundmass. Although the rock has in places been subjected to intense local alteration, it is on the whole fresher than the Sandstorm rhyolite, many specimens showing under the microscope abimdant glass with only incipient devitrification. The quartz phenocrysts, most of which are less than 5 millimeters in diameter, show the usual embayed and rounded outlines characteristic of siliceous porphyries in thin section. These phenocrysts as a rule are not affected by alteration, although in a specimen from the area at the Conqueror mine, near the contact with the Sandstorm rhyolite, they are enlarged by secondary quartz, which has replaced the groundmass adjacent to the crystals, in optical continuity with them. The principal feldspar is orthoclase. In some specimens this is fresh and clear, but more frequently it shows some alteration, either to very fine grained obscure aggregates composed chiefly of kaolin, or, in certain intensely altered facies, to aggregates of alunite and quartz. These latter pseudomorphs are well shown in specimens from the Conqueror mine and doubt- less in many other localities where the rhyolite has clearly undergone similar alteration. Most of the fresher varieties contain a few crystals of plagioclase, some of which is sufficiently calcic to be classed as labradorite. Biotite was originally present as phenocrysts, but appears to be everywhere bleached or chloritized. In the same altered rock that shows the secondary enlargement of quartz phenocrysts, from near the Conqueror mine (specimen G. 697), there occurs a colorless secondary mineral which closely resembles quartz in refraction and birefringence. The mean refractive index, however, is slightly lower, being less than the Canada balsam of the slide. The mineral, like quartz, is uniaxial, but is optically negative. It forms anhedrons with a suggestion of stout prismatic development, and is probably scapolite. Although the Morena rhyolite does not exhibit the same conspicuous flow lamination as the Sandstorm rhyolite, the microscope shows marked fluxion in the groundmass, the streaky glass curving around the phenocrysts in the manner typical of siliceous glassy lavas. U. S. GEOLOGICAL SURVEY PROFESSIONAL PAPER 66 PLATE VI T •-1 S84--N v.. ;H^,^- -v m 0 -wrr S^tf Jas al * r ( ' \'^> vt: UK A. " .4. INTRUSIVE CONTACT BETWEEN MORENA RHYOLITE AND CAMBRIAN SHALE. West slope of Columbia Mountain. .'■",-%-' -••--_-.:"t .^->- Sl^i^&JVV ~-^^ .■ -TVs- lsls*3S*-a 73. GOLDFIELD; FROM MIRA MOUNTAIN. The sharp peak is Columbia Mountain. The principal mines lie beyond the basalt-capped hill in the right foreground. PRELACUSTRINE TERTIARY IGNEOUS ROCKS. 47 MILLTOWN ANDESITE. INTRODUCTORY STATEMENT. The intrusion of the Morena rhyolite may have been followed by some erosion. Then came eruptions of andesite, which covered the region with successive flows of this rock, with here and there local and subordinate accumulations of andesitic tuff. The products of these eruptions constitute the most extensive formation in the district. (See PI. II.) The total thickness of this deposit, as of most of the other volcanic formations in this district, can not be accurately determined, owing to the slight general deformation of the rocks, their poor exposures, the comparatively low topographic relief, and the absence of persistent datum planes, such as may usually be found in stratified rocks. It probably lies between 600 and 800 feet (183 and 244 meters) . The petrographic study of the andesites shows that they contain phenocrysts of labradorite feldspar, hornblende, augite, orthorhombic pyroxene, and occasionally biotite in groundmasses ranging from hyalopilitic to vitrophyric in texture. The formation mapped as Milltown ande- site undoubtedly includes more than one lava flow, with some pyroclastic and intrusive rocks, but it is quite impracticable in this field to discriminate individual flows in mapping the whole area. The local name of the formation is derived from the small settlement of Milltown, about a mile east of Goldfield. DISTRIBUTION. As may be seen from Plate II, the andesitic terrane occupies a very large part of the district. One broad, irregular belt stretches eastward from the edge of the main valley north of Goldfield past Diamondfickl and beyond the eastern boundary of the area mapped. Another belt extends from near Goldfield eastward beyond Preble and Blackcap mountains. These two belts are prevented from meeting on the west and east sides of the central part of the district by extensive intrusive masses of dacite. Were it not for these intrusions the andesite would undoubtedly form a complete although irregular band around the central latite area, and thus still further accentuate the general concentric and domical structure of the district. The rounded andesitic hill which emerges from the Siebert formation near the railway, 2 miles (3.2 kilometers) north of Goldfield, is probably an inlier, the andesite being continuous, under the later formation, with the andesite of Kendall Mountain and vicinity. Some small areas of the andesite similarly projecting through the Siebert formation are shown in the north- east corner of the geologic map (PI. II). PETROGRAPHY. GENERAL CHARACTER OF THE FORMATION. The rocks mapped as the Milltown andesite in Plate II undoubtedly include more than one lava flow and exhibit greater variety in color and texture than any other formation in the district. In a few localities the superposition of one flow upon another can be recognized, as, for example, in the hill two-thirds of a mile ( 1 kilometer) northeast of Columbia Mountain, in another hill half a mile (0.8 kilometer) northeast of Kendall Mountain, and in the extreme northeast part of the district; but after some effort had been made to extend these local dis- tinctions over the district the attempt was abandoned as impracticable. The actual petro- graphic difference between rocks belonging to successive eruptions is in some cases no greater than between the variations in texture and composition of individual lava flows. Since the exposures over all but a very small part of the district are such that the different flows would have to be discriminated solely by petrographic means, much of the andesite being altered almost beyond recognition, and since it is by no means certain that each flow extended over the whole district, the necessity for treating the andesite as a unit is apparent. With the flows are asso- ciated some local deposits of andesite tuff, as already mentioned, and some intrusive bodies of small size, the whole constituting a typical volcanic complex. 48 THE GEOLOGY AND ORE DEPOSITS OF GOLDFIELD, NEVADA. The fresher varieties of the andesite range in color from nearly black to light gray. The altered forms are usually of lighter hue and may be gray, brown, red, yellow, green, or white. The darker fresh kinds are in most places dense ringing rocks with splintery fracture and an almost basaltic aspect. Such a rock, showing small phenocrysts of augite, occurs 1,000 feet (305 meters) northeast of the transformer station east of Columbia Mountain. A similar andesite, but with the megascopic dark phenocrysts of hornblende instead of augite, forms a dike which is crossed by the road south of Vindicator Mountain. As a rule, however, the hornblendic varieties are lighter colored and less dense rocks than the pyroxenic ones, although, as will be shown, the two types are connected by intermediate forms. Andesite with conspicuous pheno- crysts of hornblende is particularly abundant in the part of the district lying northeast of Black Butte. A similar hornblendic variety occurs also in a hill 1,000 feet (305 meters) south of Dia- mondfield. Hornblende is present in many varieties of the andesite in which it is not con- spicuous in hand specimens. It has in many such rocks undergone molecular change into aggre- gates of augite, magnetite, and plagioclase, the abundance of augite being often in rough inverse proportion to the diminution of the hornblende by this process. While it can not De said that all of the pyroxene andesite in the district once contained hornblende or biotite, the evidence is clear that much of it did. The probability of such a derivation of some pyroxene andesites from originally hornblende-bearing magmas was pointed out by Von Lasaulx ° some years ago. Later, H. S. Washington,6 after showing that hornblende and biotite in molten magmas are stable only under plu tonic conditions and undergo a paramorphic change into augite and magnetite in lavas not too quickly cooled, suggested that "some of the augite andesites, especially the more acid ones, may owe their augitic character to the alteration and subsequent disintegration of previously existing hornblendes or biotites, in accordance with the views of Von Lasaulx." The pyroxenic andesites of the Goldfield district, even those containing enstatite or hyper- sthene, furnish a good example of such an origin. Not all of the pyroxene in them was formed by the paramorphic change of hornblende and biotite and the subsequent dispersal of the ao-gregates of augite and magnetite by the movement of the magma, but most of the pyroxene andesites, had they been more quickly cooled and solidified, would probably contain horn- blende and perhaps biotite. The occurrence of plagioclase with augite and magnetite as a result of the molecular disin- tegration of hornblende is not often mentioned. J. P. Iddings c notes it, however, and states that orthorhombic pyroxene may also be present in such paramorphic aggregates. In the course of the present investigation over 200 specimens of the Milltown andesite, from all parts of the district, have been microscopically studied. While the andesitic rocks are of too many kinds to be embraced in a single petrographic description, it is impracticable, on the other hand, to describe in detail every one of the many varieties found. Accordingly only certain representative or striking facies, including those of which chemical analyses have been made, will be fully described. Such description will be followed in each case by comments upon the range, transitions, and affiliations of the variety described. HORNBLENDE-PYROXENE ANDESITE. By far the most prevalent type of andesite is one in which labradorite, augite, enstatite, and hornblende all occur as phenocrysts in a hyalopilitic or microlitic groundmass. Two fresh specimens of this type, one (G. 316) from the summit of a hill two-thirds of a mile (1 kilometer) northeast of Columbia Mountain, just north of the Goldfield-Diamondfield road, and the other (G. 59) from the area of andesite shown in the northeast corner of the geologic map (PI. II) about 1£ miles (2.5 kilometers) northeast of Black Butte, were selected for chemical analysis and special description. The latter specimen was collected just outside of the area included in Plate II. a Ueber Yorkommen und Verbreitung der Augitandesite im Siebengebirge: Sitzungsber. Nieder-rhein. Gesellsch. in Bonn, vol. 41, 1884, p. 155. 6 The magmatic alteration of hornblende and biotite: Jour Geology, vol. I, 1896, pp. 257-282. c Rock minerals: New York and London, 1906, p. 341. PRELACUSTRINE TERTIARY IGNEOUS ROCKS. - 49 The specimen, from the hill near Columbia Mountain is a dark, reddish brown, evidently glassy rock, in which the naked eye can detect minute phenocrysts of plagioclase and black hornblende. Under the microscope, phenocrysts of plagioclase up to 3 millimeters in length and smaller crystals of augite, orthorhombic pyroxene, hornblende, magnetite, and apatite appear scattered through an abundant glassy groundmass crowded with minute feldspar microlites. The tex- ture of the groundmass is hyalopilitic. The rock is perfectly fresh. The feldspar phenocrysts, save for inclusions of glass, are clear, exhibit the usual albite, Carlsbad, and pericline twinning and have an approximate composition of Ab3An7, corresponding to a rather calcic labradorite. The microlites are too small and are embedded in too much glass for satisfactory optical determination of their place in the isomorphous plagioclase series. In all of the Milltown andesite studied the phenocrysts are labradorite and range in composition from Ab3An4 to AbtAn4. The augite is faintly green in thin section, with a maximum measured extinction angle of 40°. In other specimens of the andesite it is about 45°. The planes of the prism zone are often well developed, but many crystals show only rounded outlines. The augite of the pyroxene-hornblende andesite specimens frequently shows the usual twinning on the plane (100). This mineral decomposes readily, and in many specimens of the andesite in which the labradorite is still fresh the monoclinic pyroxene has been converted to pseudomorphs of calcite. It is probably near diopside in composition. Orthorhombic pyroxene is rather abundant in small euhedral phenocrysts of prismatic habit with blunt pyramidal terminations. Although nearly colorless, the crystals are faintly pleochroic, rays vibrating parallel to Xa giving a slight reddish tint and those parallel to Y and Z being faintly tinged with green. The birefringence is low and the optical character is appar- rently positive, although some uncertainty attaches to the latter determination owing to the large optic angle and small size of the prism cross sections. The pyroxene is thus probably enstatite, hypersthene being optically negative and having as a rule stronger pleochroism and bire- fringence. In many specimens of the pyroxene-hornblende andesite the orthorhombic pyroxene is partly or wholly decomposed to a pale yellowish green mineral of variable birefringence, the interference colors ranging from the usual gray or yellow of ordinary serpentine to those almost as brilliant as in biotite. In some cases the mineral is distinctly an aggregate; but in most specimens it is optically homogeneous, with a fine fibrous structure parallel to the prism axis of the pyroxene. Such pseudomorphs exhibit parallel extinction, and the direction of least elasticity is that of the elongation of the fibers. The mineral, like iddingsite, which it some- times resembles, is probably closely related to serpentine. The relation to ordinary serpentine of such strongly birefringent minerals as iddingsite and possibly other similar alteration products of the magnesian silicates is still obscure. The orthorhombic pyroxene becomes serpentinized during the early stages of alteration of the andesite, before the augite changes to calcite. The hornblende occurs in rounded anhedrons with narrow opaque reaction rims. The absence of extensive paramorphic change and the glassy character of the groundmass indicate comparatively quick cooling of the magma. Two varieties of hornblende are present, usually intergrown in the same crystal. One is pleochroic in brown and the other in green tints. Apparently in both, however, the ray vibrating parallel to X is greenish yellow. All of the Milltown andesite contains magnetite, probably with some ilmenite, and apatite. The latter occurs in the usual small stout hexagonal prisms, many of which have a fibrous appearance due to lines of small dark inclusions parallel to the prism axis. Such crystals are faintly pleochroic. The second rock, that from the northeast corner of the district, is dark gray and appears more crystalline. The phenocrysts of feldspar and hornblende are much more abundant. a Throughout this report the crystallographic directions of greatest, mean, and least elasticity willbe designated, respectively, asX,Y,and Z, instead of by the German a. b, and c, frequently used. This usage follows the example set by J. P. Iddings in his "Rock minerals," New York and London, 190B, and makes for clearness and convenience. 79145— No. 6G— 09 4 50 THE GEOLOGY AND ORE DEPOSITS OF GOLDFIELD, NEVADA. The microscope shows phenocrysts of the same minerals as occur in the other rock. Deter- mination of some of the feldspars by the Michel Levy method gives compositions approximating to AbxAn4, corresponding to a calcic labradorite. The central parts of the crystals are often of spongy texture and full of glass inclusions, these cores usually showing sharp crystallo- graphic outlines and being inclosed in a shell of clear labradorite. The augite is colorless or faintly green and shows a maximum extinction of about 35°. The hornblende is generally brown in thin section, the pleochroism being X greenish yellow, Y and Z yellowish brown. The absorption is Z>Y>X. Some of the hornblende shows no reaction rims or paramorphism. Other crystals have been partly or wholly altered, prior to the solidification of the rock, into aggregates of augite, magnetite, and plagioclase. Orthorhombic pyroxene occurs much as in the rock near Columbia Mountain and appears to be enstatite. The groundmass is glassy hyalopilitic. Chemical analyses of these two rocks were made by George Steiger in the United States Geological Survey laboratory, the results being as follows : Chemical analyses of pyroxene-hornblende andesite. SiOa.. AI2O3. Fe203. FeO.. MgO. CaO.. Na20. K20.. 1. 2. 3. 58.06 60.41 54.66 17.43 16.59 17.53 3.83 3.18 3.18 1.91 1.70 3.52 2.60 2.13 3.62 6.33 5.26 7.33 3.34 3.94 3.56 2.61 1.70 2.22 H20 below 110° C. H20 above 110° C. Ti02 C02 P2O5 MnO 0.97 1.88 .87 None. .27 .09 100.19 1.94 2.64 .62 None. .31 .07 100.49 0.59 .69 .99 1.35 .30 .12 99.66 1. Pyroxene-hornblende andesite (G. 59), U miles (2.5 kilometers') northeast of Black Butte. 2. Pyroxene-hornblende andesite (G. 310), two-thirds mile (1 kilometer) northeast of Columbia Mountain. 3. Pyroxene-hornblende andesite, 1 mile (1.6 kilometers) northeast of Columbia Mountain. The norm of analysis 1, calculated in accordance with the quantitative system of Cross, Iddings, Pirsson, and Washington,0 is as follows: Norm of pyroxene-hornblende andesite 1\ miles northeast of Black Butte. Quartz 13.26 Orthoclase 15. 57 Albite 27. 77 Anorthite 25. 02 Diopside (CaO, MgO, SiOo) 3.46 Enstatite (MgO, Si02) 4.90 Ilmenite 1. 67 Magnetite 3. 71 Hematite 1. 28 Apatite 67 97.31 Water 2.75 100.06 This affords 81.62 per cent of salic minerals against 15.69 per cent of femic minerals, and the rock belongs in the dosalane class of that system. It is dosalic, alkalicalcic, quardofelic, and dosodic, thus corresponding to the subrang tonalose. It is accurately described in terms of the quantitative system as a vitriphyro-tonalose. It may be noted that a very large proportion of the andesites of the western United States b fall in this same subrang, which is very near the hypothetical average igneous rock as calculated by F. W. Clarke,0 H. S. Washington,0, and Alfred Harker/ The mode of the rock analyzed differs from the calculated norm in the presence of much glass, probably richer in potassium than the crystalline part of the fabric, in the absence of recog- nizable orthoclase, in the presence of labradorite instead of albite and anorthite, in the absence of free quartz, probably in the occurrence of somewhat aluminous and ferruginous microclinic pyroxene (augite) instead of diopside, and in the actual mineralogical functions of the iron oxides. « Quantitative classification of igneous rocks, Chicago and London, 1903. >> See Washington, II. S., Chemical analyses of igneous rocks: Prof. Paper II. S. Geol. Survey No. 14, 1903, pp 231-245. <• Bull. U. S. Geol. Survey No. 228, 1904, pp. 14-20. d Op. cit.,pp. 106-117. « On the average composition of British igneous rocks: Geol. Mag., new ser., 4th decade, vol. 6, 1899, pp. 220-222. PRELACUSTRINE TERTIARY IGNEOUS ROCKS. 51 The norm of rock 2 is as follows : Norm of pyroxene-hornblende andesite two-thirds mile northeast of Columbia Mountain. Quartz 17.64 Orthoclase 10. 01 Albite 33.54 Anorthite 22. 52 Diopside [(CaMg)O.SiO,] 1. 30 Enstatite 4. 70 Apatite 67 Magnetite 3. 94 Ilmenite 1. 22 Hematite 48 96.02 Water 4. 58 100. 60 This rock also is a vitriphyro-tonalose, but lies near the line separating this subrang from yellowstonose, the corresponding subrang in the persalane class. The rock of analysis 3 was collected a few hundred yards east of rock 1, and may belong to an underlying flow. It shows no hornblende in the thin section studied, and was selected as representative of the pyroxene andesite. Subsequent examination of the hand specimen, how- ever, revealed a single phenocryst of hornblende, and the analysis is accordingly discussed at this place. The rock well illustrates the close relation between the hornblende-pyroxene and pyrox- ene andesites in this district. Under the microscope the rock appears perfectly fresh, the carbonate indicated in the analy- sis evidently occurring in a few small scattered amygdules. The phenocrysts are labradorite (Ab3 An4), augite, enstatite, magnetite, and apatite. The pyroxenes are more abundant than in the hornblendic varieties of andesite just described. The augite is faintly green, with extinc- tion angles up to 43°. The orthorhombic pyroxene is particularly well developed in the usual stout prisms and is slightly more pleochroic than in the rocks previously described. It is probably near hypersthene in composition. The groundmass is hyalopilitic. The norm of this rock is as follows: Norm of pyroxene-hornblende andesite 1 mile northeast of Columbia Mountain. Quartz 6.90 Orthoclase 12.79 Albite 29. 34 Anorthite 25. 85 f31CaO.SiO,l Diopside] 26MgO.Si02 6. 92 I 5FeO.Si02j Enstatit< j64MgO.SiO.,A ltell2FeO.Si02J" 7.98 Apatite 0. 67 Magnetite 4. 64 Ilmenite 1. 98 C02... Water. 97.07 1.35 1.28 99.70 The rock in terms of the quantitative system is dosalic, alkalicalcic, quardofelic, and dosodic, and is therefore, like the other two rocks analyzed, tonalose. Study of the distribution of the pyroxene-hornblende variety of the Milltown andesite shows that while it is certainly the dominant facies, and although it occurs here and there over the whole andesite area, yet it occupies no well-defined portions of that area to the exclu- sions of the other varieties presently to be described. In a few places the distinction between the pyroxene-hornblende facies and andesite free from hornblende or containing biotite is sharp enough to indicate a contact between two flows. This, however, is exceptional. As a rule the hornblende andesite grades into pyroxene andesite, and every step in the transition can be studied in thin sections from those in which hornblende is abundant to those in which the mineral has undergone complete magmatic transformation into aggregates of labradorite, augite, and magnetite, or is so rare as not to appear in every thin section of the rock. In some pyroxene andesites these aggregates still preserve the rough outlines of the hornblende; in others the outlines are lost and the aggregate merges with the general fabric of the rock. As already pointed out, most or all of the pyroxene andesite once contained hornblende, the survival or disappearance of this mineral depending upon the rate and conditions of cooling. Further- more, it is almost certain that hornblende may be present in one part of a flow and absent in another. 52 THE GEOLOGY AND ORE DEPOSITS OF GOLDFIELD, NEVADA. PYROXENE ANDESITE. In every respect, except the absence of hornblende ana rather more abundant pyroxene, the pyroxene andesite is identical with the hornblendic variety just described. Its chemical composition is probably well represented by analysis 3 on page 50, although, as stated, this particular facies contains an occasional phenocryst of hornblende. A particularly glassy variety is exposed on the hillside just east of Tognoni Springs. This is a dark-gray rock, which on close inspection is seen to be composed chiefly of glass with a characteristic oily luster. The material has a pronounced flow structure, brought out in specimens by the alternation of bands of greenish-gray glass with nearly black layers. The microscope shows the rock to be a vitrophyre, the glass containing phenocrysts of labradorite and orthorhombic pyroxene as well as tiny microlites of augite and plagioclase. The orthorhombic pyroxene is more strongly pleochroic than in most of the andesites of the district. The acute bisectrix corresponds to the direction of greatest elasticity, X, and sections parallel to the macropinacoid (100) give a biaxial interference figure. The axial angle, also, is smaller than in the enstatite of the other andesites studied and the pyroxene is in this case hypersthene. HORNBLENDE-BIOTITE ANDESITE. A specimen from 1 mile (1.6 kilometer) northeast of Black Butte (G. 63) was selected for chemical analysis as representative of the hornblende-biotite andesite. This is a light-gray, somewhat porous rock showing abundant phenocrysts of hornblende, biotite, and feldspar in an aphanitic base. Most of the phenocrysts are less than 5 millimeters in length. Under the microscope the feldspar proves to be labradorite with the approximate com- position Ab2An3, it being less calcic than in the pyroxenic varieties of the. andesite. The horn- blende is the common brown variety with narrow dark reaction rims consisting of magnetite, plagioclase, and a colorless isotropic material, probably glass. Similar rims surround the sections of biotite, which has the optical character of meroxene. The rock was evidently cooled too quickly to allow any molecular rearrangement of the hornblende and biotite. Among the smaller phenocrysts are rather abundant prisms of cloudy pleochroic apatite and grains of magnetite. The groundmass is glassy hyalopilitic, the plagioclase microlites being for the most part too minute for satisfactory determination of their precise character. No pyroxene appears in the thin section studied. The chemical analysis of this rock, by Mr. George Steiger, is as follows: Chernical analysis of hornblende-biotite andesite. Si02 63.16 A1203 : 16.74 Fe203 3.94 FeO 47 MgO 1.12 CaO 4.07 Na20 3.88 K,0 3.71 H20 below 110° C 1.12 H20 above 110° C 77 Ti02 61 C02 'None. P265 30 MnO 04 99. 93 The analysis, as might have been expected, shows more silica and less iron oxides, magnesia, and lime than those of the pyroxenic andesites on page 50. The norm calculated from this analysis is as follows: Norm of hornblende-biotite andesite. Quartz 17. 16 Orthoclase 21. 68 Albite 33. 01 Anorthite 17. 24 Diopside (CaO.MgO.SiO,) 43 Enstatite 2.60 Titanite 14 Apatite 67 Ilmenite 1. 06 Hematite 3. 65 97.64 Water 1.89 99 53 PRELACUSTRINE TERTIARY IGNEOUS ROCKS. 53 In this norm the proportion of salic to femic minerals is greater than 7 to 1, and the rock falls in the persalane class. It is quardofelic, alkalicalcic, and sodipotassic, although very near dosodic. The rock is accordingly amiatose but is exceedingly close to yellowstonose. The chemical analysis of this rock shows that it can not be regarded merely as a quickly cooled part of a magma chemically identical with that which solidified as hornblende-pyroxene and pyroxene andesite. In other words, it indicates clearly that the mineralogical differences in the Milltown andesite can not all be explained as various steps in the change from the complex molecules of biotite and hornblende to the more stable combination of augite, magnetite, and labradorite. A rather striking variety of hornblende-biotite-augite andesite (G. 47) occurs 1J miles (2.5 kilometers) east of Black Butte, just outside of the area included in Plate II. This rock contains abundant small sparkling phenocrysts of hornblende and biotite and subordinate plagioclase in a light-gray aphanitic groundmass. The microscope shows that the majority of the pheno- crysts are of sharp euhedral form. The hornblende shows no resorption. Its pleochroism is X light yellowish green, Y dark brownish green, and Z brownish yellow. The absorption is Y > Z > X and the extinction angle Z f\ C is about 11°. Some crystals are twinned repeatedly on the -orthopinacoid (100). A colorless augite also occurs as phenocrysts, often intergrown with hornblende and biotite. In this rock there is nothing to indicate that the constituents of the augite have ever crystallized as hornblende. The plagioclase is labradorite. The ground- mass is glassy, with microlites of plagioclase. The appearance of this rock in thin section is shown in Plate VII, A. Hornblende-biotite andesite, free from pyroxene, occurs so far as known only in the north- east corner of the district and possibly in the small hill 1,000 feet (305 meters) south of Diamond- field, the rock at the latter locality not being sufficiently fresh to permit the positive statement that pyroxene was never present. Biotitic andesite occurs half a mile west of Diamondfield, on the southeast slope of Blackcap Mountain, one-half mile (0.8 kilometer) south of Myers Mountain, about a mile (1.6 kilometers) northeast of Kendall Mountain and in a few other places in the district. At all the localities mentioned, however, the rock is pyroxene-bearing or is so decomposed as to leave the question of the possible former presence of pyroxene in doubt. It thus appears that there is scarcely any more ground for a definite division of the Milltown andesite on the basis of the presence or absence of biotite than on the basis of the presence or absence of hornblende. There is a suggestion from the position of the biotite- hornblende andesite in the northeast corner of the district that this rock belongs to a late flow in the Milltown andesite. This suggestion is supported moreover by the similarity in mineral- ogical and chemical composition of the biotite-hornblende andesite with the dacite presently to be described. TUFF. Deposits of tuff constitute a wholly subordinate part of the Milltown andesite. A small accumulation occurs near the east base of the hill three-fourths mile (1.2 kilometers) northeast of Columbia Mountain. Tuffaceous rocks are present along the eastern edge of the area, north of Tognoni Springs. These, however, like much of the massive andesite with which they are associated, are so intensely altered to white kaolinic aggregates that little can be determined regarding their original character or present boundaries. The hill two-thirds mile (1 kilometer) northeast of Myers Mountain is composed in part of much-altered tuff. In view of the ease with which clastic rocks of this character succumb to chemical attack their general altered condition in this district is not surprising. It is probable that in other parts of the area than those men- tioned rocks now bleached and metamorphosed beyond recognition may have been originally tuffaceous. In underground work andesite tuff and breccia has been found in the Daisy mine as the pre- vailing rock on the 300-foot and 400-foot levels. The Crooks shaft of the Kewana Leasing Company, about half a mile (0.8 kilometer) southeast of the summit of Columbia Mountain, went through 140 feet (43 meters) of dacite, then through more than 100 feet (30 meters) of andesite into andesitic breccia. The latter continued to a depth of at least 410 feet (125 meters) — the bottom of the shaft at time of visit. 54 THE GEOLOGY AND ORE DEPOSITS OF GOLDFIELD, NEVADA, BASALT. In the Portland mine, east of Goldfield, a crosscut to the east on the 250-foot level which was accessible in 1905 exposed a series of thin amygdaloidal basalt flows with associated tuffs. Nearly all the rock in this mine is much altered, and the ground in general is so soft and so cut UP by gouge-filled fissures that prospecting was carried on with difficulty. Such observations as were possible under these conditions showed that the basalt occurs near the base of the Milltown andesite and just above the latite. The thickness of the basalt and basalt tuff could not be determined. What appears to be the same amygdaloidal basalt has been cut in the Red Hills shaft, 800 feet (244 meters) southeast of the Portland. The material of the flows is an ordinary olivinite basalt with nothing noteworthy in its character. It is nowhere exposed at the surface, so far as known, and represents a very local eruption at the beginning of the andesite period. The old vent is probably somewhere beneath the Milltown andesite in the vicinity of the Portland mine. GEOLOGIC RELATIONS. The Milltown andesite overlies the Sandstorm and Morena rhyolites, or the latite where these are absent. While probably made up chiefly of gently inclined lava flows, only obscure traces of stratiform structure are visible. Here and there a hill rising above the minor undu- lations of the surface furnishes a suggestion of one nearly horizontal flow capping another. The general topography of the district, however, and the conditions of exposure are such that almost nothing of the internal structure of the andesite complex is revealed. One of the best places in the district to observe the effusive character of the andesite and to distinguish the superposition of flows is in the steep slope just east of the northernmost of the three Tognoni Springs. The lower part of the slope is occupied by a poorly exposed and rather decomposed andesite. Above this lies about 40 feet (12 meters) of andesitic tuff- breccia, which is overlain by 50 or 60 feet (15 to 18 meters) of brittle, banded volcanic glass, an andesite vitrophyre, which has been described on page 52. This glassy lava is overlain by dacite, which at this place is probably a flow. Nowhere in the region adjacent to Goldfield is there, so far as known, a single definite and well-exposed contact between the individual flows of the formation. Yet the occurrence of tuffaceous and glassy rocks and the variety in the andesites prove that the formation is really complex. Andesitic dikes within the Milltown andesite may be present at many localities, but can not ordinarily be distinguished from the effusive members of the formation, owing to similarity in petrographic character and obscurity of exposure. As already stated, no accurate determination of the thickness of the Milltown andesite can be made. The Yellow Tiger shaft (see PI. VIII, section F-F') goes through 510 feet (155 meters) of this rock, and the total thickness at this locality prior to erosion is estimated at 700 feet (213 meters). Whether this can be regarded as greater or less than the average for the formation is not known. DACITE. INTRODUCTORY STATEMENT. The dacite, whose eruption followed the andesitic period, is in many respects the most interesting rock in the district, and is certainly the most important from an economic point of view. It occupies, as may be seen by reference to Plate II, a considerable area east of Gold- field and Columbia and is the principal country rock of the Mohawk, Combination, January, Jumbo, Redtop, and Florence mines. It is, at least in part, intrusive in the andesite. The dacite, of which typical and fairly fresh specimens can be collected on the little hill 500 feet (152 meters) northeast of the transformer station, has the general appearance of rather dark andesite. It is usually more conspicuously porphyritic than the andesites of the PRELACUSTRINE TERTIARY IGNEOUS ROCKS. 55 district, but its essential distinction from them is the presence of phenocrysts of quartz. All of these are angular fragments or crystals rounded by magmatic corrosion, and as a rule are neither very numerous nor very conspicuous. The rock consists of labradorite feldspar, hornblende, biotite, augite, and quartz in the usual andesitic groundmass. Chemical analysis of the dacite shows that it contains 60 per cent of silica, or only 2 per cent more than a horn- blendic andesite from the northeastern part of the district. Mineralogically and chemically the dacite at Goldfield is merely a quartz-bearing andesite and is in no way similar to the more siliceous rocks called dacite by Spurr in his report on the Tonopah district." DISTRIBUTION. The dacite that lies just east of Goldfield contains the principal mines of the district. (See PI. II.) Another large mass of dacite extends southward from near Tognoni Springs to Preble Mountain. This body extends for some miles east of the area included in Plate II and forms the high hills east of Tognoni Springs. In this vicinity the rock is fresh but the southern extension of the mass, particularly that forming the greater part of Preble Mountain, is intensely altered, so much so that the dacite is distinguishable with much difficulty from the similarly altered andesite. Smaller masses of dacite occur just east of Black Butte, in the extreme northeast corner of the district, between Diamondfield and McLaughlin's well, and in the vicinity of Preble Mountain. The distribution of the dacite is much more irregular than that of the Milltown andesite, the irregularity scarcely admitting any other explanation than that of intrusion. The outlines of the dacite areas, moreover, suggest that this rock cuts the andesite, a suggestion in harmony with the clearly effusive character of the Milltown andesite as a whole. In two places masses of soft altered latite have been observed which appear to be included blocks in the dacite. One of these is in the Mohawk mine (see p. 207), and the other is on the 500-foot level of the Winston shaft on the Cornishman claim. The latter mass is about 10 feet (3 meters) long and is exposed on one side of a drift which it does not cross. The dacite, which is also somewhat altered, shows a platy structure parallel to the surface of the inclusion. PETROGRAPHY. The unaltered and typical dacite is a dark-gray rock in which the most obvious char- acteristic, as compared with the Milltown andesite, is a more conspicuous porphyritic texture. Phenocrysts of plagioclase from 5 to 10 millimeters in length are abundant, and in contrast with the dark-gray aphanitic groundmass give the dacite a decided speckled appearance, which is of use as a rough means of recognizing exposures of this rock. Even where greatly altered the dacite, as may be seen on the dumps of the Red Top, Mohawk, Combination, and other mines, still retains a spotted appearance — due to the difference in shade between the pseudo- morphs after the feldspar phenocrysts and the altered groundmass — which is rarely found in the altered forms of the andesite. Associated with the phenocrysts of plagioclase are less abundant ones of augite, hornblende, and biotite, the proportions and relative prominence of these ferromagnesian or femic minerals varying in different localities. The- phenocrysts of quartz, which constitute the most useful and in many places the only petrographic means of distinguishing the dacite from the andesite, are never abundant and seldom conspicuous. Close inspection of hand specimens, however, will usually reveal the rounded outlines and conchoidal fracture of the quartz which is often more noticeable in altered than in fresh varieties of the rock. The appearance of the fresh dacite can be well studied on the hill immediately northeast of the transformer station east of Columbia, and in the steep hills just east of Tognoni Springs. A specimen (G. 97) taken half a mile (0.8 kilometer) northeast of Columbia Mountain, near the point where the dacite wedges out against the Columbia Mountain fault (see PI. II), o Spurr's reasons for using the name dacite for rocks which should strictly receive other names are given in Geology of the Tonopah district, Nevada: Prof. Paper U. S. Geol. Survey No. 42, 1905, p. 59, footnote. 56 THE GEOLOGY AND ORE DEPOSITS OF GOLDFIELD, NEVADA. was selected for chemical analysis as the freshest obtainable representative facies of this par- ticular dacitic body. The rock analyzed is dark gray, with moderately abundant phenocrysts of clear plagioclase, up to a centimeter in length, in a dark aphanitic groundmass. There are present, also, less numerous phenocrysts of augite and biotite with occasional anhedral a grains of quartz. The volumetric ratio of phenocrysts to groundmass is estimated at rather less than 1 to 3. Under the microscope the feldspar phenocrysts prove to be labradorite of the approximate composition AbjAn^ They are perfectly fresh, with slightly rounded euhedral b outlines. A noticeable feature is the presence in .many crystals of closely crowded minute inclusions of glass, which in some cases constitute cloudy cores or kernels, in others sharply bounded shells, the center of the crystal being clear. The augite crystals are roughly euhedral or subhedral, with a maximum measured extinction angle, Z /\ c, of about 45°. The biotite occurs in the usual short, rather irregular pseudo-hexagonal prisms. Both biotite and augite are entirely fresh. The quartz phenocrysts are anhedral, with rounded, embayed, or sharply angular outlines. Hornblende is very abundant, but is confined almost exclusively to the groundmass, most of the crystals being comparable in size rather with the feldspar microlites than with the pheno- crysts just described. The general color is yellowish green, the pleochroism being X yellow, Y yellow-green, and Z brownish green, and the absorption Z > Y > X. Neither the biotite nor the hornblende shows any magmatic resorption or pseudomorphism. The largest horn- blende crystal in the thin section studied is about half a millimeter in length. It should be said, however, that in dacite from other parts of the district the hornblende occurs as phenocrysts. The feldspar microlites in the groundmass are at least in part labradorite of as calcic com- position as the phenocrysts. They, the hornblende, and a little magnetite and apatite are embedded in an abundant glass, which in transmitted light is gray, with incipient crystals (crystallites). There is one crystal of titanite, 0.3 millimeter in length, in the thin section studied. The chemical analysis, by Mr. George Steiger, is given below, under 1. Chemical analyses of dacite. 1. 2. I. 2. SiOs 59. 95 15. 77 3.34 2.34 2.73 5.84 3.07 2.52 .95 2.00 01.25 15.92 3.75 1.17 2.28 5.39 3.19 3.23 1.08 1.88 Ti02 0.82 .02 None. .26 None. .09 .11 .13 0.71 A1203 ZK>2 co2 PaOs Fe203 None. FeO .22 MgO : F CaO MnO .08 Na20 BaO K20 SrO H20 below 110° C H20 above 110° C. . . 99.94 100. 15 1. Dacite (G. 97), one-half mile (0.8 kilometer) northeast of Columbia Mountain. Intrusive. 2. Dacite (G. 83). Diamond Peak. Effusive. The norm calculated from analysis 1 is as follows: Norm of dacite one-half mile northeast of Columbia Mountain. Quartz Orthoclase 17.34 15.01 Magnetite 4.87 Ilmenite Apatite. . . . 1.52 Albite 25.68 21.96 37 .34 Anorthite Zircon Water 96.93 o. 21 4. 63 2. 95 Diopside Enstatite 99.88 a Anhedral = without crystal faces, xenomorphic, allotriomorphic. See Cross, W., Iddings, J. P., 1'irsson, L. V., and Washington. U.S., The texture of igneous rocks: Jour. Geology, vol. 14, 1906, p. 698. '>EuhedraI=bounded by crystal faces; idiomorphic, automorphio. PRELACUSTRINE TERTIARY IGNEOUS ROCKS. 57 This dacite, like the andesite previously described, is a tonalose in accordance with the nomenclature of the quantitative system. It is, however, close to the sodipotassic subrang harzose in the same quardofelic order, austrare. Another specimen of dacite (G. 83) selected for analysis comes from Diamond Peak, one-half mile (0.8 kilometer) east-southeast from Tognoni Springs and just outside the area mapped in Plate II. Like most of the dacite in this part of the district, it is more conspicuously porphyritic than the rock just described, the dark-gray groundmass being thickly strewn with crystals of plagioclase up to a centimeter in length, with abundant sparkling phenocrysts of hornblende and biotite. The volumetric ratio of phenocrysts to groundmass is estimated at nearly one to two. Under the microscope, the rock closely resembles the dacite from near the transformer station. The plagioclase is labradorite ranging from A^A^ to Ab3An4. The hornblende is of the same character as in the facies last described, but in addition to occurring in the groundmass it forms phenocrysts up to 2 or 3 millimeters in length. These crystals exhibit no magmatic resorption or paramorphism. The section, however, shows one or two aggregates of hornblende, augite, and magnetite that are suggestive of paramorphic change of an earlier generation of hornblende phenocrysts. Quartz occurs in the thin section of this specimen in two or three small, rounded, embayed phenocrysts. It is more abundant and conspicuous in other specimens from the same rock mass. The groundmass is a colorless glass crowded with crystallites and with mierolites of plagi- oclase and hornblende. No titanite was observed in this rock, the accessory minerals being magnetite and apatite. The chemical analysis of this rock is given under 2, on page 50. The calculated norm from analysis 2 is as follows: Norm of dacite from Diamond Peak. Quartz 17. 10 Orthoclase 18. 90 Albite 27. 25 Anorthite 19. 46 Diopside 5. 34 Enstatite 3. 40 Ilmenite 1. 37 Magnetite 1. 86 Hematite 2. 40 Apatite 34 97.42 Water 2. 96 100. 38 This norm corresponds to a harzose, near tonalose. In the ordinary classification the rock is a dacite, close to quartz latite. The mass of dacite which is partly mapped in Plate II as a small area in the extreme north- east corner of the district is composed of a very fresh rock of different appearance from the dacite near Goldfield or near Tognoni Springs. This variety is rather light gray with moderately abundant phenocrysts of plagioclase, hornblende, augite, and biotite in a dense aphanitic groundmass. The microscope shows that this rock, in spite of its different aspect, is practically identical in mineralogical composition and texture with the dacite from Diamond Peak. The quartz phenocrysts are few and small and might easily be overlooked in a casual examination of a thin section. Some of the hornblende and biotite crystals show incipient peripheral change to magnetite and augite. The groundmass consists of mierolites of plagioclase and augite, with grains of magnetite in a pale-brown to colorless glass containing crystallites. The rock is absolutely fresh. In general the fresh dacite, wherever found, is remarkably uniform in character, as seen under the microscope. The rock, however, has been extensively altered, and even moderately fresh rock is not the most common except in the northeastern part of the district. Much of the dacite is so changed in appearance by this alteration that one unfamiliar with the various stages of the process and unable to resort to petrographical methods would be quite unable to identify it. 58 THE GEOLOGY AND ORE DEPOSITS OF GOLDFIELD, NEVADA A comparatively inconspicuous mode of alteration consists in the change of the plagio- clase and augite to calcite, which may be accompanied by quartz; of the biotite to epidote and chlorite with some form of iron oxide ; and of the hornblende to dark aggregates of finely dis- seminated magnetite and quartz. Such alteration may usually be recognized by the lusterless greenish-gray tint of the rock and the dullness or opacity of the plagioclase phenocrysts. Another much more intense process of alteration, which is well exemplified in the vicinity of Preble Mountain and in the mines near Goldfield, changes the rock to a light-gray or white mass in which the occasional small phenocrysts of quartz are all that remain of the original minerals of the dacite. The feldspars, most of them still recognizable from their outlines, are no longer clear and vitreous, but are dull and chalky. The microscope shows that the prin- cipal constituents of such altered rock are quartz and alunite, the hydrous sulphate of alu- minum and potassium. In some varieties kaolinite is present with the alunite; in still others the rock is chiefly quartz and kaolinite. A more detailed account of this alteration and of the further stage of complete silicification will be given in Chapter XIV. GEOLOGIC RELATIONS. Most of the dacite within the area covered by the geologic map (PI. II) is regarded as intrusive into the Milltown andesite and older rocks. As this important fact is not obvious, and as the dacite is known to occur as an effusive rock associated with dacitic breccia just east of Tognoni Springs, the evidence bearing upon the question whether the dacite of the district is intrusive requires detailed consideration. At one point only within the district, so far as known, is a contact between unaltered dacite and andesite exposed. This is near the eastern border of the district, 1,300 feet (396 meters) in a direction N. 26° W. from the sharp summit of Espina Hill. At this place a little saddle is occupied by dacite between an isolated area of andesite on the west and volcanic breccia on the east. (See PL VIII, section A- A'.) The andesite is a fine-grained compact variety and looks younger and fresher than the dacite. The latter, however, contains frag- ments of the andesite and has a noticeably glassy selvage band within half an inch (12 milli- meters) or less of the sharp irregular contact. The dacite shows some flow structure near the contact, and the intrusion presumably took place very close to the then existing surface. The large body of dacite northeast of Goldfield has the general form of an irregular sheet with a present maximum thickness of about 700 feet (213 meters). Its outline is very irreg- ular. Along the east side of Columbia Mountain the dacite ends against the Columbia Moun- tain fault. (See PI. II.) South of the town of Columbia the rock extends westward across the line of the fault and is in part overlapped by the younger Siebert formation. Surface exposures in this vicinity throw no light whatever on the character of the contact between the dacite on the one hand and the latite and Kendall tuff on the other. The artificial expo- sures underground are scarcely more satisfactory. Some shafts sunk by lessees west of the Red Top mine might at one time have afforded valuable information; but in this district shafts from 200 to 400 feet (61 to 122 meters) deep are often put down and abandoned within a few months. They soon become inaccessible or unsafe, those who sank them disappear, and only the dump is left to perplex and tantalize the geologist. The workings of the Red Top, Mohawk, Combination, and January mines all show the dacite to be in contact along its western border with latite. On the whole, this contact, as illustrated in Plate VIII, section C-C, has a general dip east, the average angle being from 30° to 40°. The rocks in its vicinity are generally altered and soft. Partly in consequence of this condition they are disturbed and are traversed by many seams of muddy gouge. There has been con- siderable movement along the contact, whatever its original character, and its present appearance in individual exposures is that of a fault plane. Detailed study of the mines shows, however, that these planes are not continuous and that the contact is more irregular than it should be were the dacite here bounded on the west by a fault. On the 450-foot level of the Mohawk mine the main latite-.dacite contact is at the Mohawk shaft. From this shaft a west crosscut to the Mackenzie shaft goes through latite for 400 feet (122 meters), then enters dacite and continues PRELACDSTRINE TERTIARY IGNEOUS ROCKS. 59 in this rock for 250 feet (76 meters) to the face. (See PL VIII, section C-C'.) As usual the contact is disturbed, but this dacite west of the Mackenzie shaft is thought to be a dike which has come up through the latite and connects with the dacite sheet above. In the lower levels of the Mohawk mine and in parts of the Combination mine ore has been found at the contact, partly in dacite and partly in latite. In such places the contact, much obscured by the mineralization, appears to be of the irregular kind characteristic of igneous intrusion. On the whole, while much remains to be learned, the evidence relating to the dacite-latite contact west of the Red Top, Mohawk, and Combination mines is thought to indicate that it was originally intrusive and that it has since been modified by many local faults. As will later be shown, the whole body of dacite containing the principal mines has been racked by move- ments which have transformed joints, contacts, and other planes of weakness into gouge-filled fissures. On the south the dacite is in contact with the Milltown andesite. When the preliminary report was issued it was thought probable that this contact dipped gently to the south, such a supposition being a reasonable conclusion from the general relation of the geologic boundary between the two rocks to the topography. The Florence was then the only shaft that had penetrated the Milltown andesite in this locality and the exposures it afforded lent some support to such a view. (See PL VIII, section F-F'.) It is now known that the contact is in general very steep and that the andesite near Milltown rests not on dacite, but on latite. In the Florence workings the contact is much obscured by the alteration of the rocks. It is apparently close to the shaft on the 150-foot level and only 20 to 30 feet (6 to 9 meters) south of the shaft on the 250-foot level. (See fig. 28). The Little Florence shaft, 500 feet (152 meters) south of the Florence shaft and 500 feet deep, is all in andesite. The Rosebud, Rogers, Florence Annex (Engineer's Lease), Pollard-Florence, and Florence-Extension No. 2 shafts, all 500 feet (152 meters) deep, and all on the southeast slope of Florence Hill, show andesite as the prevalent rock to the bottom. It thus appears that in this locality not only does the dacite abut against the Milltown andesite with a nearly vertical contact, but the latter rock extends to unusual depth (see PL VIII, section G-G') and probably occupies one of the fissures or conduits through which the andesitic flows issued. At one place on the 509-foot level of the Rogers lease a narrow slab of mineralized dacite between andesite walls has been drifted on for a short distance. It is probably a small dike. On the south slope of the little hill north of Milltown the Baltimore Belle shaft, 375 feet (114 meters) deep, is all in andesite. Farther east the Atlanta-Cherokee shaft, 500 feet (152 meters) deep and, as shown on Plate II, very close to the dacite contact, is nearly all in andesite. A little dacite was cut near the bottom, but this, probably an intrusive offshoot from the main body to the north, was penetrated and andesite was found below it. The Garrison shaft, just northeast of the Atlanta-Cherokee, is in dacite at the surface, but the bottom, at 300 feet (91 meters), is in andesite. Both dacite and andesite occur at the 250-foot level, the relations of the two rocks being suggestive of irregular intrusion of the andesite by the dacite. Alteration and disturbance of the rocks, however, render interpretation of the observed relations uncertain. Near this shaft the contact crosses the ridge and swings north of the line of shafts, which con- tinues southeastward along the crest to the Gold Bar and Victor mines. The Gold Bar workings, 300 feet (91 meters) deep, are mainly in andesite and latite, the latter being the rock of the 300- foot level. Considerable dacite is exposed on the 200-foot level, however, where it apparently occurs as irregular masses in the andesite. The rocks in this mine are generally much altered and disturbed so that contacts as a rule are very obscure. At one place, however, on the 200- foot level, west of the shaft, a little intrusive tongue of dacite projecting into andesite was plainly discernible in 1908. Although both rocks were soft and altered the sharp irregular contact was distinct, and specimens have since been microscopically identified as andesite and dacite. Of the contact along the eastern and northern sides of the main dacite sheet little more is known than appears from the map (PL II) and structure sections (PL VIII). It is poorly exposed and has not been much explored underground. The boundary corresponding to the 60 THE GEOLOGY AND OBE DEPOSITS OF GOLDFIELD, NEVADA. contact is sinuous, and in general defines the thin edge of the dacite sheet which rests for the most part on Milltown andesite, but in some places on latite or Sandstorm rhyolite. Practically nothing is known concerning the detailed character of the contacts of the other bodies of dacite, such as that near Black Butte and those in the vicinity of Preble Mountain. These contacts are either not actually exposed or are so blurred by the intense alteration of the rocks that the only information they furnish is such as is deducible from their courses on the map and from the relation of these to the topography. This information alone, however, is demonstrative of intrusion. If the boundary of the dacite mass of Preble Mountain, for example, be supposed reasonably accurate, if it be carefully considered with reference to the slopes which it traverses (see PI. II), and if the attempt be made to get from this inspection an idea of the shape of the mass, this shape is found to be consistent only with the hypothesis of irregular intrusion of the dacite into the andesite. Finally the dacite as a whole does not accord with the general concentric plan which has resulted from the doming and erosion of a series of originally nearly horizontal lava flows. Reference to Plate II shows that it cuts across the annular area of Milltown andesite from west to east. So far as the mapped area is concerned the evidence for the generally intrusive character of the dacite may be regarded as sufficient. It appears, however, that the intrusion took place under a cover of andesitic rocks which was comparatively thin, and that some of the dacite broke through and was erupted at the surface. The textural uniformity of the dacite and the comparatively slight extent to which the hornblende and biotite have undergone paramorphic change both suggest that the magma solidified under conditions of pressure and temperature such as would be afforded by intrusion under some load. On the other hand, the comparative thinness of the former cover is indicated by the presence of some glass in the groundmass of the dacite and the absence of any recognizable contact metamorphism of the andesite by the invading rock. Some additional reconnaissance east of the mapped area in 1908 showed that in the neigh- borhood of Tognoni Springs a transition takes place from intrusive dacite on the west to effusive dacite on the east. A mile or two east of these springs, on the east slope of the first high hill east of Diamond Peak, are exposed the edges of a series of lava flows dipping gently to the west. At the base of the section observed is a flow of rather dense andesite overlain by a dark-gray andesite vitrophyre like that which may be seen on the slope just northeast of Tognoni Springs. (See p. 52.) Resting on this glassy flow is an unstratified dacitic breccia from 200 to 300 feet (61 to 91 meters) thick composed wholly of fragments of dacite and containing angular blocks and bomblike masses up to 6 feet (1.8 meters) in diameter. This deposit is overlain by a flow of massive dacite of approximately equal thickness. A mile (1.6 kilometers) or less east of the section just described another hillside exposes a flow of dacite resting on glassy andesite without any intervening breccia. Above the typical dacite is a flow of volcanic glass, probably dacitic, and overlying this a flow of rhyolite which is thought to be the Meda rhyolite. Diamond Peak, which lies just east of the mapped area and is the culminating point of the steep slope east of Tognoni Springs, is composed mainly of dacite. This is apparently a flow, several hundred feet thick, which dips gently westward and passes directly, with no essen- tial change in petrographic character, into the dacite south of the springs. This in turn is directly continuous with the dacite of Preble Mountain, supposed to be intrusive. It thus appears that in the Goldfield district there is a remarkable transition from an intrusive rock to an effusive one. The imaginary restoration of the conditions under which the eruption took place is somewhat difficult. The familiar conception of narrow vertical dikes connecting with overlying lava flows has no application here and no sharp distinction seems possible between the intruded and extravasated dacite. The magma appears to have irregu- larly invaded the older rocks, to have lifted these in part as an overlying crust, and to have poured through various ragged rents in this comparatively thin cover. The locus of one such rent is supposed to lie between Preble Mountain and Tognoni Springs, most of the dacite west PEELACUSTRINE TERTIARY IGNEOUS ROCKS. 61 of this line being intrusive and most of that east of it effusive. The breccias to the east of the mapped area prove that the outbreak of dacitic magma was accompanied by explosive activity. That transitions similar to the one just described must have occurred countless times in the history of the earth is obvious. It is rare, however, that erosion has progressed just far enough to reveal but not obliterate them. It is the realization of these unusual conditions that has led to skeptical scrutiny of the evidence for intrusion in the case of the dacite near Goldfield and to the presentation of that evidence in more detail than would otherwise be necessary. DACITE VITROPHYRE." GENERAL CHARACTER AND OCCURRENCE. The dacite vitrophyre is a volcanic formation, consisting of thin lava flows with one or more ash beds, which as a whole rests upon an uneven surface of andesite and is overlain by the Meda rhyolite, andesite breccia, and deposits of the lacustrine epoch. Its age, so far as fixed by the general geological succession, is thus the same as that of the dacite. The vitrophyre is limited to the southern part of the district and extends from the vicinity of Myers Mountain southeastward past Blackcap Mountain and beyond the boundary of the area mapped. With some Chispa andesite it forms a series of low, rounded, light-colored hills (Chispa Hills), crossed by the freight road from Goldfield to the Bullfrog district and skirted on the north by the Gold Crater road. The details of distribution may be had from Plate II. PETROGRAPHY. The most abundant and characteristic material of the formation is a very light gray or nearly white rock, often with a faint tinge of green or pink. The texture is apparently porous, although the microscope shows this appearance to be in most cases misleading. The com- parative softness of the material and the presence of blotches in the glassy groundmass give it considerable resemblance to a tuff. The rock is, in most places, finely speckled with small scales of biotite and contains less noticeable crystals of feldspar and quartz. A typical specimen (G. 158) collected alongside of the Gold Crater road, 1 mile (1.6 kilo- meters) southwest of Blackcap Mountain, was selected for description and chemical analysis. The rock is light greenish gray with irregular greenish blotches. Flakes of biotite, a millimeter or two in diameter, and larger phenocrysts of quartz and clear feldspar are dis- tributed through a dull aphanitic groundmass. Under the microscope (PI. VII, B) the rock shows a typical vitrophyric structure, phenocrysts of vitreous plagioclase, biotite, and quartz being embedded in a eutaxitic glass. The plagioclase is in part labradorite, near Ab2An3 in composition, but other varieties may also be present. There is, in the section studied, a single phenocryst of hornblende partly changed to an aggregate consisting chiefly of magnetite. The groundmass is almost wholly glass, partly transparent, and partly gray and cloudy, with incipient crystal growths., Streaks of these different varieties of the glassy base, drawn out by flowage, give the rock' its blotchy appearance in hand specimens and its eutaxitic structure as seen under the microscope. Aj&hemical analysis of this rock, made in the Survey laboratory by George Steiger, is as Chemical analysis of dacite vitrophyre. H20 below\lO° C 3.35 H,0 above 110° C 4.06 Ti02 64 CO, None. P,Os ._ .24 a In the preliminary report (Bull. U. S. Geol. Survey No. 303, 1967, p. 18), written before th tion here designated dacite vitrophyre was provisionally called quartz-latite. PLATE VII. Photomicrographs of Volcanic Rocks. A. Hornblende-biotite-augite andesite (G. 47). Northeast corner of district, 1J miles east of Black Butte. Con- tains phenocrysts of labradorite (1), hornblende (h), biotite (b), and augite (not shown in section) in a glassy hyalopilitic groundmass (g). Ordinary light. Magnified 40 diameters. B. Dacite vitrophyre (G. 163). Southern edge of district, If miles southwest of Preble Mountain. Contains phenocrysts of plagioclase (p) near oligoclase in composition, biotite (b), and quartz (q), in a eutaxitic brown glass (g) containing shreds of clearer glass (g7). This variety probably approaches quartz latite or rhyolite in composition. Hole in section (h). Ordinary light. Magnified 35 diameters. C. Olivine basalt (dolerite) (G. 2). Edge of Malpais Mesa above Rabbit Spring. Contains phenocrysts of anorthite (a), olivine (o) partly altered to red-brown serpentine and an occasional crystal of hornblende (not shown). The holocrystalline groundmass (g) is composed of plagioclase (labradorite or anorthite), augite, olivine, magnetite, a little interstitial calcite, and apatite. Nicols crossed. Magnified 40 diameters. D. Mica basalt (dolerite) (G. 46). Northeast corner of district, 2 miles east of Black Butte. Contains anorthite (a), a bright chestnut biotite (b), augite (p), olivine (not shown), calcite (c), magnetite and apatite. There is no sharp distinction between phenocrysts and groundmass. The biotite projects into irregular miarolitic cavities, many of which are partly filled with calcite. The minerals are all fresh except the olivine, which is altered to deep red-brown serpen- tine. Hole in section (h). Nicols crossed. Magnified 40 diameters. 62 U. S. GEOLOGICAL SURVEY mwj i "£ ' ■ / J*-' F /' *^J?9^HHE *&&: ' S .> ■■:„ £ Jtff j * r •■■ ':/.;■<* ~"*! WW- h ^SfflB^ \. | fei ' - •••^r*"* -Ft .-.••■' "s~v'!. '• "■ *£A i \ J* [r*?:'; ■•>■-' Sj •> •^>..'V-f5- . 1» ■■ "SLs »■» '-"V ■■•,'■:■ . -■■-' Svf ilpf^ | . . ■ ■*■""/ Wliffix^ s ffii 5 « s'ft ^|™ ► •-•.■»■;•> « •■■ ■ - lv-,-.',;- i- gL-:t>«.> 1/ N. oS4y&2 • * »-.•'■-< PROFESSIONAL PAPER 66 PLATE VII a. J>- PHOTOMICROGRAPHS OF VOLCANIC ROCKS. PRELACOSTRINE TERTIARY IGNEOUS ROCKS. 63 A remarkable feature of this analysis, and one not easily accounted for, is the unusual ratio between the ferrous and ferric iron. As the rock is perfectly fresh, containing no hem- atite and very little augite, it would seem that ferrous iron should be much more abundant than the ferric form, inasmuch as in biotite and magnetite the ferric iron is normally combined with respectively greater and equal amounts of the divalent form. Three determinations of the iron were made by Mr. Steiger and two additional determinations, by another method, were carried out by Doctor Hillebrand. All agree so closely as to show that the abnormal ratio is not due to defective analysis. As there is apparently enough magnetite in the rock to account for all the ferrous iron found it seems necessary to conclude that the biotite is of unusual composition and that probably some iron in the ferric state is present in the glass of the groundmass. a The norm calculated from this analysis is as follows: Norm, of dacite vitro phyre. Quartz 20. 76 Orthoclase 16. 68 Albite 25. 68 Anorthitc 18. 90 Corundum 1. 12 Enstatite 3. 80 Hematite 4. 48 Ilmenite 30 Titanite 1. 18 92.90 Water 7.41 100. 31 The rock is amiatose, in the persalane class, britannare order, alkalicalcic rang and sodi- potassic subrang, of the quantitative classincation. It is practically on the line, however, between amiatose and the unnamed dopotassic subrang of the same rang and order. The only rock falling in this unnamed subrang in H. S. Washington's tables of analyses & is a so-called retinite, described by V. Sabatini and analyzed by G. Aichino. This analysis is here quoted for comparison with the dacite vitrophyre. Si02 64. 32 A1203 17. 87 Fe203 2. 55 FeO Not determined. MgO Trace. CaO 3.06 Chemical analysis of retinite. c NaO 1.63 K,0 4.52 H20 6.19 100. 14 The interesting feature of the comparison is the considerable difference between the analysis here quoted and that of the dacite vitrophyre, which very narrowly escapes falling into the same subrang. A mile and a half (25 kilometers) south of Preble Mountain (one-fourth mile outside of the area mapped) a quarry has been opened in a bed of white volcanic ash, and the material, although very soft, has been used for buildings in Goldfield. It is composed almost entirely of small particles of volcanic glass with a few crystals or fragments of biotite, feldspar, and quartz. No chemical analysis has been made of this tuff, but it probably corresponds in com- position to the dacite vitrophyre with which it is associated. RELATION TO THE DACITE. As the dacite vitrophyre has not the slightest physical resemblance to the dacite, it was at first supposed that the vitrophyre was the younger rock — the product of eruptions, that may have been separated from the dacite by a considerable interval of deformation and erosion. This a Since this was written the Swedish chemist Robert Mauzelius has found that the ferrous iron of minerals may be partly oxidized during the grinding preparatory to analysis. W. F. Hillebrand (Jour. Am. Chem. Soc, vol. 30, 1908, pp. 1120-1131), in whose paper may be found references to earlier work, has recently confirmed and extended the experiments of Mauzelius and others. This discovery may account in part for the unexpected ratio of ferrous and ferric iron in the dacite vitrophyre, but there has been no opportunity to test this before the report goes to press. 6 Prof. Paper U. S. Geol. Survey No. 14, 1903, p. 183. c Sabatini, V., Descrizione geologica delle Isole Pontine: Boll. R. Comitato geol. ital., vol. 24, 1893, p. 252. 64 THE GEOLOGY AND ORE DEPOSITS OF GOLDFIELD, NEVADA. was the view expressed in the preliminary report." Subsequent petrographic study, however has shown that the vitrophyric dacite has some mineralogical features in common with the intrusive dacite, and chemical analyses prove that the two rocks are nearly identical in chemical composition. In order to illustrate this chemical likeness, the analyses of the dacite rocks are here given side by side. Chemical analyses of dacite and dacite vitrophyre. [George Steiger, analyst.] Si02 A1203 Fe203 FeO MgO CaO Na20 K20 H20 below 110° C H2O above 110° C 1. 2. 3. 59.95 59.99 61.25 15.77 16.14 15. 92 3.34 4.42 3.75 2.34 .13 1.17 2.73 1.51 2.28 5. 84 4.17 5.39 3.07 3.04 3.19 2.52 2.82 3.23 .95 3.25 1.08 2.00 4.06 1.88 TiOa 0. 82 Zr02 02 C02 None. P2O5 .26 F None. MnO 09 BaO 11 SrO 13 99.94 2. 0.64 None. .24 None. .05 100. 50 0.71 None. .22 None. .08 100.15 1. Dacite, one-half mile (0.8 kilometer) northeast of Columbia Mountain. 2. Dacite vitrophyre, 1 mile (1.6 kilometers) southwest of Blackcap Mountain. 3. Dacite, Diamond Peak, one-half mile (0.8 kilometer) east-southeast of Tognoni Springs. The vitrophyre, owing to the abundance of glass, contains a larger quantity of water than the more crystalline rocks. It has somewhat less iron, calcium, and magnesium, but the chem- ical difference is no greater than may obtain in rocks known to be the products of a single erup- tion. The vitrophyre, as has been shown, falls into the persalane class of the quantitative classification, while the dacite is in the dosalane class. Both rocks, however, are near the border line between the two arbitrary classes, and any such definite scheme of artificial grouping nec- essarily separates many rocks which are chemically very close together. Were the dacite and dacite vitrophyre separated in geologic time by an interval of erosion or by the eruption of some other lava, the resemblance would be regarded as a rather remarkable coincidence. As it is, the two rocks are known to be of nearly the same age. Whether they were simultaneously erupted, the vitrophyre as an effusive equivalent of the dacite, can not be deter- mined from the data available. The fact that dacite known to be effusive east of Tognoni Springs has the same general habit as the intrusive dacite near Gokmeld, whereas the dacite vitrophyre is a rock of wholly different aspect, suggests that the eruptions of the dacite and dacite vitrophyre were not strictly contemporaneous. The vitrophyre is probably slightly younger. CHISPA ANDESITE. GENERAL CHARACTER AND OCCURRENCE. The Chispa andesite occurs as flows intercalated in the dacite vitrophyre. A traverse of the Chispa Hills shows five of these flows, of which the northern ends of two only come into the area mapped (PI. II). They dip to the southwest with the dacite vitrophyre at angles up to 50°. There is evidently some faulting in this vicinity, and it is possible that some of the apparently distinct flows may be repeated exposures of the same lava sheet in successive fault blocks. All the dark andesite bands, which contrast in color with the light dacite vitrophyre, end rather abruptly on the northwest in a manner suggestive of faulting. The larger of the two areas shown in Plate II is in contact along its northern border with the Milltown andesite. This contact is covered by soil and wash and is further obscured by the deep decomposition of the rocks. Its position is uncertain and nothing is known of its character. It may correspond to a fault. PETROGRAPHY. The Chispa andesite is generally a brownish-gray porous rock. The most abundant of the small phenocrysts are augite, and, with less conspicuous feldspars, are embedded in a brown aphanitic vesicular groundmass. The microscope shows the rock to be an ordinary fresh "Bull. U. S. Geol. Survey, No. 303, 1907, p. 18. PRELACUSTKINE TERTIARY IGNEOUS ROCKS. 65 glassy augite andesite with no special features. The phenocrysts of augite, plagioclase, and magnetite lie in a turbid microlitic glass. A few aggregates of smaller individuals of these minerals appear to represent resorbed hornblende. ANDESITE DIKES. Cutting the Milltown andesite, dacite vitrophyre, and Chispa andesite in the southeastern corner of the district are a few dikes of a still younger andesite. Possibly similar dikes occur elsewhere, but in most places it would be impossible to distinguish them if present from the mass of the Milltown andesite. Many exposures originally supposed to be dikes were found afterwards to be merely unaltered parts of the andesite, which in some localities outcrop from the softer disintegrated material around them in a manner strongly suggestive of younger intrusions. The dike andesites are as a rule not particularly fresh, and no special petrographic study was made of them.. Some show phenocrysts of hornblende, but the microscope proves them to be for the most part rather feldspathic rocks with subordinate femic constituents. The groundmass contains considerable glass, and a vesicular texture is not uncommon. It appears therefore that the parts of the dikes now visible were never far from the surface. MEDA RHYOLITE. GENERAL CHARACTER AND OCCURRENCE. The Meda rhyolite, which takes its local name from Meda Pass, is exposed in the vicinity of the pass and close to the road south of Myers Mountain. Two small areas of rhyolite in the northeast corner of the district, parts of a much larger area to the east, are supposed to represent the same epoch of eruption and are mapped as Meda rhyolite, although it is not certain that they were ever continuous with the rhyolite near Meda Pass. The rock is a flow which north- east of Tognoni Springs rests on Milltown andesite and dacite and in the southern part of the district on dacite vitrophyre. It probably varies much in thickness. PETROGRAPHY. The rhyolite of the type locality near Meda Pass varies in color from light gray to pink. Some of it has a well-marked flow structure which is accentuated by many narrow lenticular streaks of obsidian. Small phenocrysts of feldspar and quartz are abundant although not con- spicuous. The microscope shows the rock to be a fresh glassy rhyolite vitrophyre in which the phenocrysts of quartz and orthoclase are accompanied by less abundant crystals of plagioclase and biotite. The plagioclase is mostly oligoclase. Some of the rock northeast of Meda Pass is a little more crystalline than the variety just described and contains more abundant scales of biotite. It is this latter facies that is exposed south of Myers Mountain. The rhyolite mapped in the northeastern corner of the district is a light reddish-gray variety with abundant small phenocrysts of quartz which, with crystals of orthoclase and biotite, are embedded in a eutaxitic groundmass. East of the area mapped this rock grades into more crystalline varieties. ANDESITE BRECCIA. About half a mile (0.8 kilometer) southeast of Meda Pass the northern end of a body of andesite breccia barely comes into the area mapped. This is a bedded deposit and consists of fragments of andesite, mostly scoriaceous and more or less decomposed, firmly cemented in a matrix of andesitic tuff. The fragments are rarely over 6 inches (15 centimeters) in diameter. The breccia rests upon the Meda rhyolite, or where this is absent on the dacite vitrophyre. It dips gently to the southwest and is overlain by tuffs supposed to be part of the Siebert formation. It is probable that this breccia was laid down contemporaneously with the intrusion of the andesite dikes noted above. 7!)145— No. 06—09 5 CHAPTER V. KOCKS OF THE LAKE EPOCH. INTRODUCTION. In the Tertiary lake that probably covered much of the district after the eruption of the dacite, dacite vitrophyre, Meda rhyolite, and andesite breccia, there were laid down over 500 feet (152 meters) of bedded tuffs, tuffaceous sands, pumiceous ash, conglomerates, and diatoma- ceous earth. These are the deposits known to the miners as "cement rock." Volcanism con- tinued during the existence of the lake, as shown by the prevailingly volcanic character of the sediments and the occurrence within them of a thick flow of quartz-bearing basalt (Mira basalt) and a few thin flows of glassy rhyolite. The Mira basalt, as shown by wells, underlies the southwestern part of Goldfield and it is exposed on the automobile road to Bullfrog. Lacus- trine conditions were ended by deformation of the region, the domical structure probably being initiated by this uplift. The sedimentary deposits of the lake epoch will in this report be called the Siebert forma- tion, being regarded as the equivalent of the Siebert tuff of the Tonopah district, described and named by Spurr.° SIEBERT FORMATION. DISTRIBUTION. The beds of the Siebert formation are prevailingly rather soft and disintegrate readily. Consequently they do not as a rule give rise to prominent outcrops. They underlie the town of Goldfield and occupy the valley to the north through which passes the railway to Tonopah. South of Goldfield they cover a large area, Myers Mountain and similar eminences in that direction being made up of these beds capped by basalt. The}7 also underlie much of the basaltic mesa southwest of Goldfield and some of the best exposures of them are in the steep sides of the mesa near Pozo Canyon. (See PL II.) Other areas extend into the northern part of the district and deposits belonging to this formation undoubtedly underlie a large part of the desert plains which surround the Goldfield Hills. LITHOLOGY. The sediments of the Siebert formation exhibit a wide range of character, although they consist almost entirely of volcanic and diatomaceous material, the former greatly predomi- nating. Most of the material exposed or penetrated in wells near Goldfield consists of soft, sandy tuffs alternating with beds of volcanic conglomerate or gravel. The bedding is in most places fairly regular, but in small exposures is not always clearly distinguishable from cross-bedding. In the 100-foot well of the Columbia Ice and Cold Storage Company the gravel or conglom- erate beds are said to occur every 20 to 30 feet (6 to 9 meters) and to be from 1 to 2 feet (0.3 to 0.6 meter) thick. The soft, light-gray, sandy beds which constitute most of the formation as exposed near Goldfield and in the valley to the north are composed almost entirely of volcanic ash. The constituent particles, as seen under the microscope, are chiefly angular bits of transparent a Spurr, J. K., ecology of tho Tonopah mining district, Nevada: Prof. Paper U. S. Qeol. Survey No. 42, 1905, pp. 51-55. 66 KOCKS OF THE LAKE EPOCH. 67 glass. These show so little rounding as to indicate that the material either was transported only for very short distances by streams or else fell directly as ash showers into the waters of Siebert Lake. In some beds the minute size of the particles suggests that the material was blown from some vent as fine dust, such as might be carried for many miles by winds. With the tuffs are associated some thin beds of diatomaceous earth, distinguishable from the ash beds by their whiteness and lightness. There is in some places, however, a gradation from tuff into the organic deposit. The purest form of diatomaceous earth was found in the northwest corner of the area mapped, near the point where the electric-power line enters the district. The material is cream color, exceedingly light, and splits into paper-thin leaves. A little of the powder when covered with a drop of water and examined under a high power of the microscope is seen to be made up entirely of the whole and broken cells, or frustules, of diatoms. The species of these tiny plants are probably the same as those identified by Dr. R. M. Bagg from the Siebert tuff at Tonopah." Inasmuch as these low organisms, owing to their wide range through geologic time, are of little value in determining the age of the rocks with which they are associated, it seemed scarcely worth while to have specific determinations made on the Goldfield material. An impure and less thinly laminated diatomaceous earth occurs just east of the railway, near the crossing of the electric-power line, and similar mate- rial, associated with soft, light-gray, pumiceous tuffs, underlies much of the low ground between Myers Mountain and Meda Pass. The conglomerates associated with the fine tuffs and infusorial earth contain pebbles of most of the prelacustrine rocks of the district, those of rhyolite being probably most abundant. The material of the conglomerates, however, varies from place to place. Some of the shafts sunk near the eastern side of the town of Goldfield show the Siebert formation to contain many fragments of dacite up to a foot (0.3 meter) or more in diameter. Still larger fragments of the same rock are abundant in the Siebert beds about a mile southeast of Myers Mountain. The dump of an abandoned shaft, a few yards northeast of the railway station in Columbia, shows that the basal part of the Siebert (which here rests on the Kendall tuff) is a breccia con- taining fragments of dacite up to 18 inches (0.5 meter) in diameter. The matrix in which these blocks are embedded is composed of particles of volcanic rocks of various kinds, those of andesite predominating. Small pebhles of quartz also were noted in some of the conglom- erates of the Siebert. The flow of Mira basalt, shown south of Goldfield in Plate II, is overlain by beds of light- colored tuff which contain, near their base, vesicular blocks of the basalt. This phase of the Siebert is well exposed on the north slope of Spearhead Point, south of Goldfield. The beds, which dip 25° S., have in general a pale greenish yellow tint and are rather soft. They com- prise fine-grained tuffaceous sandstones and small-pebbled conglomerates or grits, the latter showing cross-bedding. In the northeastern part of the district much of the Siebert formation is a soft, brown, sandy tuff, composed chiefly of particles of feldspar, hornblende, and other minerals found in the massive lavas. This material in places overlies a deposit made up of fragments of light vesicular glass, or pumice. At Meda Pass the Meda rhyolite is overlain by a bed of white pumiceous tuff probably from 20 to 30 feet (6 to 9 meters) thick. The upper surface of this tuff is very uneven, the inequalities being apparently due in part to erosion and in part to subsequent minor faulting. Upon it rest dark friable sandy tuffs, which in the limited exposures available show very irregular lamination with diverse dips, but no true bedding. This material is really a basaltic or andesitic sand in which the partially rounded grains of plagioclase, augite, magnetite, and brown glass have been cemented by calcite. It is closely associated with, and probably grades into, or is overlain by, coarser tuffs in which the cementing material of the basaltic fragments is also mainly crystalline calcite. The exposures in this part of the district are very unsatis- factory, but the tuffs just described are probably part of the Siebert. The beds which appar- a Spurr, J. E., Geology of the Tonopah mining district, Nevada: Prof. Paper U. S. Geol. Survey No. 42, 1905, pp. 09-70. 68 THE GEOLOGY AND ORE DEPOSITS OF GOLDFIELD, NEVADA. ently overlie them and form the ridge between Meda Pass and Mira Mountain are exposed only in a few prospect pits. One such pit between bench mark 5813 and Mira Mountain shows soft gray tuffs with layers of coarse angular conglomerate. The material is partly andesitic, but is of mixed derivation. Similar soft tuffs dip 35° to 40° W. under the basalt cap of the mountain. THICKNESS. The thickness of the Siebert formation has previously been given (p. 29) as "1,000 feet or more." This, however, may be under the mark. It is difficult to draw sections to scale, and in accordance with known surface relations, that do not give a thickness of over 2,000 feet (610 meters) for the lake sediments in the vicinity of Goldfield. Exposures are far too poor to permit of any satisfactory measurement of thickness, and consequently we are forced to be content with estimates. The beds are certainly over 500 feet (152 meters) in thickness. Part of the apparent 2,000 feet, however, is probably due to faults and minor folds not visible at the surface. On the whole, 1,000 feet (305 meters) is probably as fair an estimate as can be made at present of the maximum thickness of the Siebert formation at Goldfield. Ball's map a indicates that the nearly horizontal Siebert beds which constitute the upper part of Monte- zuma Peak have a thickness of at least 1,000 feet, and the formation exhibits similar develop- ment in the Monitor Hills,6 25 miles (40 kilometers) northeast of Goldfield, and at the southern end of the Belted Range,0 60 miles (96.5 kilometers) to the southeast. CONDITIONS OF DEPOSITION. The variations in the Siebert formation from pure diatomaceous earth and fine volcanic ash to coarse accumulations of large angular rock fragments indicate that the Tertiary lake was of variable depth, and that parts of the district rose above its waters. On the other hand, the Siebert lake beds, as shown by the work of Ball d and of Spurr,g and as indicated by the probable correlation of them with the Pahute lake beds of King, have a wide distribution over western Nevada, so that the lake, in spite of the evidence of the existence of near-by land, can have been no local feature. It was probably an exceedingly irregular body of water, com- parable in shape with the labyrinthine inland sea which would arise were the present desert valleys to receive a rainfall persistently in excess of evaporation. That the bottom of the lake was exceedingly uneven is shown not only by the relation of the beds to the present topography of the district, but by the reconnaissance work of S. H. Ball / over a much larger area. Above the waters of the Tertiary Siebert or Pahute Lake rose not only mountains of older rocks, but volcanoes in active eruption, which hurled angular blocks of lava into the water, and must at times have covered parts of the lake with floating pumice and volcanic dust. Torrential rains probably aided in transferring the detrital products of eruption to their final resting place at the bottom of the lake, while in the intervals of quiet between eruptions, or in sheltered spots, diatoms found in the temperature of the water and in its silica contents conditions favorable to their abundant development. STRATIGRAPHY. The stratigraphy of the Siebert rocks, owing to their prevalent softness, is very unsatis- factorily revealed. In general the beds dip away from the center of the district at low angles. Exposures in the bluffs southwest of Goldfield indicate a dip of about 18° W. in that part of the field. This, however, is probably steeper than obtains north of Goldfield and in the northern part of the district. The beds have been subjected to some faulting, as may be seen along the edge of the mesa, southwest of town. This disturbance will be described in a subsequent chapter. ™ Ball, S. II., A geologic reconnaissance in southwestern Nevada and eastern California: Bull. V . S. Oeol. Survey No. 308, 1907, PI. I. b Op. cit., p. 07. c Op. cit., p. 143. d A geologic reconnaissance in southwestern Nevada and eastern California: Bull. U. S. Geol. Survey No. 308, 1907. « Geology of the Tonopah mining district, Nevada: Prof. Paper IT. S. Geol. Survey No. 42, 1905. / Op. cit., PI. I, figs. 7 and 13. ROCKS OF THE LAKE EPOCH. 69 MIRA BASALT. OCCURRENCE. The Mira basalt occurs as a flow, apparently about 100 feet (30 meters) in greatest thickness (see also geologic sections, PI. VIII), intercalated in the Siebert sediments. This rock underlies the southern part of the town of Goldfield. The flow rises gently toward the south, capping Mira Mountain and some smaller hills in its neighborhood. (See PI. II.) North of Goldfield the Mira basalt is partly concealed by the Siebert formation, a few small areas only having been uncovered by erosion in the vicinity of the railroad station. PETROGRAPHY. The basalt as exposed at the surface is prevailingly vesicular and is characterized mega- scopically by the presence of rather large phenocrysts, up to three-fourths of an inch (1.8 centimeters) in length, of vitreous feldspar, which are disseminated sparingly through the rock. Although these feldspars are often bright and fresh, the rock as a whole presents a somewhat more weathered appearance than the later olivine basalt which caps the large mesa southwest of Goldfield. Denser and fresher varieties are obtained, however, in some of the wells near the town. Under the microscope the rock appears as an ordinary olivinitic basalt, save for the rather sporadic occurrence of quartz phenocrysts. The plagioclase is labradorite. The olivine is in some facies completely serpentinized, in others only initially attacked. The quartz occurs in rounded or embayed anhedrons, which, in some specimens, are surrounded by narrow rims of augite. Not every thin section contains quartz, and where this mineral is absent there is little to distinguish this rock from the later basalt. This similarity is particularly marked in the case of specimens of the older basalt taken from wells in the southern part of town. The rock from some of these wells is a doleritic variety with much olivine and no quartz. In spite of its resemblance to the basalt of the neighboring mesa (PI. II), this doleritic facies is apparently part of the same flow as the vesicular quartz-bearing variety, and is so mapped. It must be said, however, that the geologic relations of the rocks in the valley around Goldfield are very obscure. There may be unrecognized faults concealed beneath the loose detritus which covers most of the surface. ESPINA BRECCIA. In the eastern part of the district, northeast of Preble Mountain, is a deposit of breccia and tuft* wdiich shows a rough nearly horizontal bedding, and is about 200 feet (61 meters) in thick- ness. The material is for the most part greatly altered so that its original character is in part doubtful. Fragments of dacite are abundant, particularly in the lower beds, while the upper beds contain much volcanic glass in bomb like masses up to a foot (0.3 meter) in diameter, mingled with fragments of glassy rhyolite. The breccia records explosive volcanic eruptions of rhyolitic material which has since been extensively altered to opal, secondarj^ quartz, kaolinite, and perhaps alunite. Whether the stratification was effected beneath the waters of Siebert Lake or is the result of successive showers of volcanic detritus upon a land surface is a question to which the character of the material affords no decisive answer. The Espina breccia may be part of the Siebert formation, but definite correlation is not at present possible and the deposit, therefore, has been given a local name. CHAPTER VI. POSTLACUSTRINE TERTIARY ROCKS. INTRODUCTORY STATEMENT. With the close of the lake epoch the rocks of the district underwent deformation, followed by erosion. Consequently the postlacustrine rocks rest unconformably upon the older forma- tions, as may be well seen in the cliffs bounding the mesa southwest of Goldfield, particularly in the vicinity of Pozo Canyon. Here the Siebert sediments are in some places tilted to angles up to 30°, with the practically horizontal lavas which cap the mesa lying upon their eroded edges. The postlacustrine rocks comprise four distinct formations, which, from the base up, are (1) the Pozo formation, consisting of beds of volcanic conglomerate and sandstone; (2) two flows of rhyolite, which may conveniently be called the Spearhead rhyolite; (3) a thin layer of sandstone and conglomerate, here named the Rabbit Spring formation; and (4) one or more flows of olivine basalt (Malpais basalt), with some biotitic and hornblendic facies. POZO FORMATION. The Pozo formation is named from Pozo Canyon, where may be seen the only satisfactory exposure of these rocks in the district. At the bend in the ravine (see PL II), about three- quarters of a mile (1.2 kilometers) southwest of the center of Goldfield, some 50 feet (15 meters) of the Pozo formation is exposed in a cliff section, capped with the Spearhead rhyolite, which in turn is overlain by the Malpais basalt. The Pozo consists of roughly bedded, imperfectly assorted conglomerates associated with some soft sandstone. The material is mainly of volcanic derivation^ andesitic, basaltic, and pumiceous fragments being abundant. The pebbles, which are not well rounded, range in size from sand grains to blocks a foot or two (0.3 to 0.6 meter) in diameter. The larger blocks are not confined to any one part of the deposit and some are embedded in the fine sandy layers. The general bedding of the deposit is nearly horizontal, but in detail the stratification is irregular and as exposed in the cliff shows small local unconformities. It is evident that after some of the sands were laid down currents changed, channels were scoured, and were later filled with gravel. The whole deposit is clearly of fluviatile origin. The base of the formation is not visible in the section just described. On the opposite side of the ravine, however, the conglomerate may be seen resting upon an uneven erosion surface of the soft yellowish Siebert beds. The Pozo formation thins rapidly to the north, and at Spearhead Point the rhyolite rests directly upon the eroded edges of the Siebert strata. Partly consolidated gravels and sands referable to the Pozo formation are exposed in the railway cut a short distance south of Meda Pass. They conformably underlie the Spearhead rhyolite and doubtless rest uncomformably upon the tuffaceous Siebert beds, although this contact is not exposed. The pebbles are subangular, ill-assorted, and of many kinds. A few are of dacite which had undergone the characteristic alunitic alteration prior to the erosion that furnished the materials of the conglomerate. The total thickness of the deposit, which contains some sandy and tuffaceous layers, is probably between 50 and 100 feet (15 and 30 meters). A little less than a mile (1.6 kilometers) north of Black Butte is a ridge capped with roughly bedded conglomerate with some fine tuff near the base of the deposit. The conglom- erate contains fragments of andesite and dacite cemented by calcite. In its upper part the deposit contains many blocks, some as much as 6 feet (2 meters) across, of vesicular basalt of the same kind as that of the post lacustrine flows. POSTLACUSTRINE TERTIARY ROCKS. 71 The correlation of this material is somewhat in doubt, but it is provisionally mapped with the Pozo formation. It is possible, also, that a small part of what has been mapped as Siebert in the northeast corner of the district may really belong with the Pozo, as the latter formation had not been recognized when this part of the field was studied. It is questionable, however, whether the Pozo, if present northeast of Black Butte, could be there satisfactorily separated from the dominant and poorly exposed Siebert. SPEARHEAD RHYOLITE. The rhyolitic flows are well exposed at Rabbit Spring, west of Goldfield, and in Pozo Canyon. At Rabbit Spring they have a thickness of about 80 feet (24 meters), while at the southern boundary of the district mapped they are altogether only about 20 feet (6 meters) thick. In most places two distinct subdivisions are recognizable — an upper, thicker, pinkish member, and a lower, thinner, brown member. These are thought to be distinct flows, but the rock of both members is essentially the same and no evidence of any erosion or deposition between the erup- tion of the two varieties has been found. At Rabbit Spring, where the upper rhyolite has been quarried for building stone, the rock is a rather soft, porous, pinkish-gray rhyolite, containing so many fragments of pumice as to warrant the name of "flow breccia." These pumiceous fragments are everywhere present in the Spearhead rhyolite, but they vary in abundance from place to place. In some localities they are so numerous as to give the rhyolite the aspect of a tuff; in others the flow is comparatively compact and massive. Under the microscope the rhyolite shows phenocrysts of quartz and orthoclase and a curly eutaxitic glass, which, in some specimens, shows incipient devitrifaction. Among the rarer phenocrysts are biotite, hornblende, and green pyroxene. These seldom occur as more than one or two imperfect crystals in any single section and may be entirely absent. The Spearhead rhyolite has been extensively used as a building stone in Goldfield and is the material of the court-house and of the town fire station. RABBIT SPRING FORMATION. The Rabbit Spring formation is exposed in the bluffs above the spring whence it derives its name and in other places along the edge of Malpais Mesa. A deposit correlated with it occurs also beneath the basalt of Blackcap Mountain. As exposed near Rabbit Spring, the formation is from 10 to 15 feet (3 to 4.5 meters) thick, and is consequently exaggerated as shown on the geologic map (PL II). It consists here of sand- stone, apparently derived from the underlying rhyolite, with lenses of conglomerate, of which the pebbles are all of volcanic rocks. In its upper part the formation merges with the brecciated vesicular base of the overlying olivine basalt. The occurrence of this bedded sandstone and con- glomerate indicates fluviatile action or a very brief recurrence of at least local lacustrine condi- tions just prior to the basaltic eruptions. At Blackcap Mountain the basalt cap rests in part upon a wedge of volcanic sandstone and conglomerate, the pebbles of the latter being mostly andesite and basalt. This wedge is about 25 feet (7.6 meters) thick on the west face of the mountain, but thins to the east, and has not been seen on that side of the summit. (See PI. II.) The lower 7 feet (2 meters) of the basalt is exceedingly vesicular and much brecciated by the movement of the flow. These sediments are correlated with those above Rabbit Spring, although it is by no means certain that they were laid down in one continuous body of water. The. Siebert formation, if it ever covered this part of the district, was eroded away before the Rabbit Spring formation was laid down. The Spear- head rhyolite is also missing at Blackcap Mountain. 74 THE GEOLOGY AND ORE DEPOSITS OF GOLDPIELD, NEVADA. ' One is a compact aphanitic rock, which caps a hill just outside of the extreme northeast corner of the district, as mapped in Plate II. Under the microscope this basalt shows a strik- ing flow structure, the small crystals of plagioclase, olivine, and augite being nearly all arranged with their longest dimensions parallel. The other, a somewhat porous, light-gray variety, is on the hilltop just east of the area of rhyolite mapped in the northeast corner of the district. The most noticeable feature of this rock, as seen in hand specimens, is a bright golden-brown mica. The small scales of this mica arc particularly abundant in the irregular pores of the basalt, projecting from the walls of these little cavities and frequently partly embedded in calcite. The microscope shows the rock to be a holocrystalline aggregate of calcic labradorite (near AbjAn,), augite, biotite, hornblende, magnetite, and apatite. (See PI. VII, D.) Origi- nally a little olivine was present, but this has been altered to a deep red-brown ferruginous serpentine or allied mineral. Calcite is fairly abundant, filling rough miarolitic or interstitial cavities. Although the calcite apparently began to crystallize in actual cavities in the rock, it has also directly attacked and replaced some of the contiguous labradorite. The line between calcite and labradorite is irregular but sharp, and the plagioclase crystals show no tendency to alter into calcite throughout their mass. The brown mica is biaxial with small axial angle. The plane of the optic axes lies in the plane of crystal symmetry as in common biotite and phlogopite. The pleochroism is X light yellow, Y and Z bright-yellowish chestnut. The absorption scheme is Y = Z>X. The optical character indicates that the mica is either biotite (meroxene) or phlogopite, the color suggest- ing the latter material. Inasmuch, however, as the rock as shown by the analysis under 2 on page 73 is by no means poor in iron, the mica is probably merely a biotite of rather unusual color. The norm of this mica-bearing dolerite, calculated from analysis 2 on page 73, is as follows: Norm of mica dolerite. Anorthite 30. 02 Albite 25. G8 Orthoclase 10. 01 Quartz 18 Diopside 13.61 Hematite 8. 70 Enstatite 5. 80 Ilmenite 2. 13 Titanite 98 97. 11 (Calcite 1. 20) Water 1. 43 99.74 This rock also is a hessose in the quantitative classification. On the east slope of Vindicator Mountain and near the eastern edge of the district, 1£ miles (2.5 kilometers) north of Blackcap Mountain, are small bodies of basalt that appear to be intrusive in the older rocks, and may fill conduits through which some of the extrusive basalt reached the surface. The rock of the Vindicator Mountain areas is dark gray and compact, with small phenocrysts of plagioclase, augite, and hornblende. Microscopical examination leaves the character of the larger mass (PI. II) somewhat in doubt, as the mineral supposed to have been olivine is entirely altered to calcite and serpentine and the groundmass is rather andesitic in texture. Some of the smaller masses shown, however, are clearly olivinitic basalt, with small phenocrysts of labradorite, augite, and olivine in a dense partly glassy groundmass. The rock of the small areas north of Blackcap Mountain is compact and nearly aphanitic. It shows under the microscope abundant small phenocrysts of partly serpentinized olivine and of labradorite, in a groundmass of plagioclase, augite, magnetite, apatite, and a little glass. CHAPTER VII. QUATERNARY DEPOSITS. The post-Tertiary deposits of the Goldfield district comprise unconsolidated gravels belonging to two periods. The older gravels have been recognized chiefly to the south of Goldfield, along both sides of the automobile road to Bullfrog, being found in some places 500 feet (152 meters) above the bottoms of neighboring ravines. They are particularly abundant on the slopes of Mira Mountain. These gravels are apparently not well bedded, are very poorly exposed, and owing to their tendency to roll down the slopes and mingle with later detritus can not be accurately mapped. They are not shown on Plate II. The pebbles consist largely of rocks foreign to the district. Mr. W. H. Emmons estimated that about 40 per cent of them are of micaceous slate or phyllite, 20 per cent of dense dark-gray limestone, 15 per cent of hard quartzite and 25 per cent of andesitic and other dark volcanic rocks. Some of these rocks occur as bowlders a foot (0.3 meter) in diameter and nearly all are weli rounded. The maximum thickness of these gravels is not known, although a shaft in one place shows them to be at least 50 feet (15 meters) thick. It appears most probable that the material of these gravels was brought from the south- west by a stream which must at times have carried more water than is ever found in the present arroyos. The later gravels and sands are those of the present stream courses, which, it should be understood, contain running water only at rare intervals and for brief periods. These gravels are of local derivation and in most places can not be definitely separated from the loose imperfectly washed detritus that covers so much of the district and is so serious an obstacle to the work of the prospector or geologist. On Plate II only the thicker and more extensive accumulations of alluvium are shown, for the reason that in this arid region the details of distribution of the superficial gravel and ubiquitous "wash" are of little importance compared with the structure and distribution of the underlying rocks. The areas of alluvium shown, therefore, are merely those which are so thick or so extensive as to prevent the underlying rock structures from being satisfactorily deciphered. No attempt has been made, so far as known, to work any of the gravels for gold, and it is doubtful whether they could be successfully exploited, even were abundant water available. For not only is the gold of the district very fine, but the concentration by running water has doubtless been far less perfect than in those regions where a comparatively stable system of perennial streams has steadily concentrated the gold into narrow and definite channels. In an arid region like that of Goldfield the channels are wide and ill defined and the process of erosion is too erratic and intermittent for effective concentration. Moreover, the total depth of erosion since the ores were deposited has been comparatively small, as will be shown later. 75 CHAPTER VIII. GEOLOGIC STRUCTURE. The structure of the Goldfield district, as previously stated, is broadly simple. A Tertiary volcanic series resting upon the worn surface of much older rocks has been elevated into a dome of gentle curvature (see Pis. II and VIII), and this after some modification by faulting and igneous intrusion has been truncated by erosion so as to denude patches of the fundamental rocks in the central part of the uplift, leaving them surrounded by annuli of successively younger formations. This structure was afterwards covered, at least in part, by flows of lava which have in their turn been eroded from all but the outlying parts of the district. Banner Mountain may be taken as the approximate center of the domically uplifted area. (See PI. II.) The uplift, however, is not symmetrical, and Vindicator Mountain appears to correspond structurally to a local protuberance on the dome. It is quite possible that originally there was. a depression here in the pre-Tertiary surface, since the oldest of the lavas, the Vindi- cator rhyolite, is found mainly on the flanks of this mountain. The symmetry of the dome is further modified, as will later be shown, by irregular intrusions of the dacite and by the Columbia Mountain fault. (See PI. II.) The scattered and relatively small areas of pre-Tertiary rocks now exposed throw little light on the structure of the old floor through which the lavas broke. The basal rock, in these exposures, is mainly alaskite, which has invaded and greatly disrupted a series of Cambrian sediments. It is probable that the alaskite or granite is the prevailing rock upon which the Tertiary rocks as a whole rest, but it is quite possible that included in this plutonic rock and forming parts of the floor may be masses of the Cambrian sedimentary terrane much larger than those visible on Columbia and indicator mountains. It is doubtful whether, with the information now available, the configuration of the pre- Tertiary floor can be ascertained with any accuracy. The contacts between alaskite and the volcanic rocks in the vicinity of Vindicator and Banner mountains show no sharp rugosities, but on the other hand they scarcely suggest that the alaskite was worn down to a smooth plain. That the old surface suffered considerable deformation in Tertiary time is evident from the relations shown on Columbia Mountain, where Tertiary rhyolite is intrusive into alaskite and Cambrian sediments. Doubtless equal or greater deformation has affected parts of the floor now buried, and the occurrence of such local disturbance complicates the problem of an ideal restoration of the surface as it was before the Tertiary volcanic eruptions began. The fact that the pre-Tertiary rocks are exposed only in the central part of the eroded dome, or where, as on Columbia Mountain, faulting has modified the domical structure and brought the older rocks within the reach of erosion, indicates that the prevolcanic surface had low relief; otherwise knobs of alaskite or of Cambrian sediments would be found here and there projecting through the andesite.. The pre-Tertianr floor was therefore in the main a rolling granitic surface diversified by rounded hills a few of which may have attained heights of 200 to 300 feet (61 to 91 meters) above the general level. None of the exposures in the district affords evidence of any considerable detrital accumulation on this old surface prior to the volcanic outbursts, although, as mentioned on page 37, there is a little such material beneath the Vindicator rhyolite on Columbia Mountain, and the basal part of the rhyolite generally contains many inclusions of Cambrian shale. Overlapping the pre-Tertiary core of Vindicator Mountain on its west and east sides are parts of the oldest lava in the district,' the Vindicator rhyolite. This flow is at present not extensive, US GEOLOGICAL SURVEY GEORGE OTIS SM ITH. Dl RECTOR PROFESSIONAL PAPER 66 PLATE VIII A T. m . . SECTION A-A ~£Lr c, ■M SECTION Bit SECTION C-C Vindicator Mm SECTION J)J> SECTION EK EXPLANATION T Shafts approximately in the plane of section -r Shafts behind the i plane of section T~ Shafts in front of the plane of section FOR EXPLANATION OF COLORS SEE LEGEND ON GEOLOGIC MAP. PLATE It SECTION G G GEOLOGIC SECTIONS ACROSS THE GOLDFIELD DISTRICT, NEVADA BY F . I, KANSOME Horizontal and vertical scale :ioob looo 3QOO a ooo liset GEOLOGIC STRUCTURE. 77 for it does not appear around other areas of alaskite exposed to view in the vicinity of Banner and Columbia mountains. Whether it is the product of a small local outburst which never extended far from the site of Vindicator Mountain, where it perhaps accumulated in a hollow, or whether there was considerable erosion between its eruption and the latite inundation is not known. The maximum thickness of the Vindicator rhyolite is estimated at about 200 feet (61 meters). The rhyolitic capping of Columbia Mountain is probably a remnant of the same flow. The latite flow, which rests in part upon the Vindicator rhyolite but mainly upon the pre- Tertiary floor, now forms the surface rock over a considerable area in the center of the dome. The average diameter of this area is about 2 miles (3.2 kilometers), but its outline, as may be seen from Plate II, is very irregular. This irregularity of outline, considered in connection with the definition of the bottom of the formation by the various areas of alaskite from which the latite has been stripped by erosion, and of the top by the residual patches of younger Sand- storm rhyolite which rest on the latite northeast of Banner Mountain, shows that the latite flow lies in a nearly horizontal position in the center of the dome, where it is not generally of great thickness. The estimated maximum is about 300 feet (91 meters). Outside the main central area latite is exposed south of Columbia in consequence of the struc- tural modifications of the dome brought about by the Columbia Mountain fault, as will be shown in subsequent pages. Following the latite as one of the concentric structural elements of the dome is the Sandstorm rhyolite and associated Kendall tuff. As shown in Plate II, the rhyolite is exposed in a number of small irregular areas around the latite in the northwest half of the dome and occurs in small residual patches or outliers northeast of Banner Mountain. It is absent so far as known from the southeast half of the uplift. As in the case of the Vindicator rhyolite, it is not quite clear whether this absence is due chiefly to erosion or is a result of the original distribution of the flow. As will presently appear, however, there is reason to conclude that some erosion of the region took place after the eruption of the rhyolite and before the outbreak of andesitic lavas. Reference to Plate II will show that on the south side of Vindicator Mountain one small residual mass of Sandstorm rhyolite is almost in contact with the alaskite. This indicates that the alaskite mass of the mountain was not entirely buried by the latite, but stood out in part as an island in the volcanic flood. Otherwise there should everywhere be a wide band of latite separating exposures of the younger rhyolite from those of alaskite. It may appropriately be observed at this stage that in a volcanic sequence, such as is here dealt with, unconformities have not the same definiteness and significance as when they inter- vene between sedimentary rocks. In the latter case they usually record an elevation of the area of sedimentation, a change of sea bottom into land, erosion of this land, subsequent sub- mergence, and renewed deposition of sediments on the eroded surface. In the Goldfield region there is no evidence of general submergence at any time during the prelacustrine epoch. The area as a whole was a land surface, and erosion was undoubtedly active during the entire period of volcanic accumulation. Each flow as it was poured out was at once attacked by air, rain, and streams. Such erosion was probably very uneven, and its results depended upon the character of the material erupted, the nature of the local topography, the length of time between eruptions, and probably other less obvious factors. In sedimentary rocks the exist- ence of planes of stratification and the knowledge that originally these were nearly horizontal enables us to restore in imagination the surface initially exposed to erosion. No such restora- tion is possible in the case of the volcanic formations of Goldfield. We may not assume that the flows spread evenly over the whole district, that they were of uniform thickness, or that the topography at the close of each eruption was even approximately a plain. It is as a rule impossible to say in how far the observable inequalities in the thickness and distribution of the various flows are clue to original irregularity of deposit and how far to intervolcanic erosion. The thickness of the Sandstorm rhyolite is variable. In the central part of the area it is probably not over 100 feet (30 meters) thick, but west of the Columbia Mountain fault, in the vicinity of the Sandstorm mine, the formation, which here is apparently made up of a 78 THE GEOLOGY AND OBE DEPOSITS OF GOLDEIELD, NEVADA. series of thin glassy flows, becomes considerably thicker. The workings of the Sandstorm mine show that this rock extends to a depth of 200 feet (61 meters) and is underlain by another 200 feet of Kendall tuff. The increased thickness of the Sandstorm rhyolite in this part of the district and its irregular intrusion by the closely following Morena rhyolite suggests that both eruptions broke through the pre-Tertiary floor in this part of the district. Conse- quently the bottom of the Sandstorm rhyolite north of Columbia Mountain may be very irreg- ular, and the extrusive rock may pass in depth into facies not distinguishable from the Morena intrusive type. The Morena rhyolite, whose intrusion closely followed in time the extravasation of the Sandstorm rhyolite, does not appear in the domical structure as displayed east of the Columbia Mountain fault. The main mass of Morena rhyolite that forms the northern spur of Columbia Mountain and the smaller bodies exposed in the vicinity of the Conqueror mine clearly cut irregularly through the Sandstorm rl^olite and through the pre-Tertiary rocks. These intrusive bodies have been subjected to the same stresses that have produced the general domical structure of the district, but they have introduced by their intrusion local disturbances whose effects mask the more general tectonic relations. The same statement, as will presently be seen, applies also in less degree to a younger intrusive rock, the dacite. Although the contact between the two rocks is nowhere clearly exposed, there is little doubt that the Milltown andesite normally overlies both the Sandstorm and Morena rhyolites. This shows, not only that the intrusive rhyolite was erupted before the andesite flows swept over the region, but that sufficient erosion must have intervened to lay bare a rock, or a rock facies, that had solidified under some cover. Additional evidence of such postrhyolitic erosion is afforded by the many places where the Sandstorm rhyolite has been cut out and the andesite rests directly upon the latite, as near Diamondfield and along the entire southeast side of the dome. The thickness of material removed in the course of this erosion can not be accurately determined, but there are reasons for supposing that it was not great. It has already been shown that prior to the outbreak of Tertiary volcanism the surface of the region was hummocky. The hills were neither high nor sharp, and the valleys were broad with gentle slopes. There was neither active erosion nor active deposition. After the latite flow had covered the region the surface was presumably more nearly a plain than before. There is no reason to conclude that the addition of this mantle of volcanic rock greatly accen- tuated erosive processes, and no evidence has been found indicative of any trenching of the volcanic terrane by streams. Upon the latite, which probably underwent some local deformation at this time, iwas thrown out the Kendall tuff. This appears to have accumulated chiefly in basins or small valleys, and its deposition was immediately followed by the pouring out of the thin glassy flows of Sandstorm rhyolite, alternating in some places with small accumulations of tuff. The rhyolitic material probably accumulated to the greatest thickness near the vent or vents, which there is some reason to suppose lay north of the site of Columbia Mountain. Finally, the Morena rhyolite rose through fissures opened by earlier volcanic paroxysms and solidified as intrusive masses in the flows. There is nothing to indicate that the intrusive rock solidified under any other cover than the previously erupted Sandstorm rhyolite. Subsequent preandesitic erosion appears to have done little more than level off and carry away such rhyolitic accumulations as rose above the general level of the region. Possibly there was some local subsidence north of Columbia Mountain, which accounts for so much of the rhyolite being left in that part of the district, while elsewhere it was reduced to a thin layer or entirely removed. There is nothing to show that the postrhyolitic erosion was able at any point to cut deeply below the latite terrane upon which the rhyolite was erupted. If the region between the beginning of the rhyolitic eruptions and the beginning of the andesitic period had been deeply buried it is improbable that erosion would have so nearly restored the general surface to its postlatite level and configuration. It seems reasonable to suppose, therefore, that the Morena rhyolite was intruded under a comparatively light load of extrusive (Sand- GEOLOGIC STRUCTURE. 79 storm) rhyolite, and that a very moderate erosion sufficed to level off the region to the gently undulating surface which was to receive the andesitic flows and tuffs. The distribution of the andesitic rocks has been described on pages 47 to 54. If the intru- sive dacite be for the present disregarded, the andesite forms a broad ring, the outer annulus of the successive eruptive formations exposed in the truncated dome. As shown in Plate II, this band is of very uneven breadth, its inner margin encroaching irregularly over the Sand- storm rhyolite and latite, and its outer border being determined by the still greater sinuosities of the edge of the overlapping Siebert formation. Its shape is modified also by the Columbia Mountain fault. The Milltown andesite is the thickest of the eruptive formations entering into the structure of the dome. It is very difficult, however, to estimate this thickness, owing to the absence of any regular planes within the formation that might be confidently taken as corresponding to the general dip of the whole. The only shaft that has penetrated the andesite at a point where a direct section of the formation would throw light on its total thickness or general dip is the Yellow Tiger. The vertical section in this shaft gives 510 feet (155 meters) of andesite, which, as shown in Plate VIII, section F-F', may correspond to an actual thickness of about 600 feet (183 meters). The Milltown andesite is certainly not a single flow, but is probably built up of several overlapping lava sheets, with a minor proportion of tuff and perhaps some intrusive andesite. In the few localities where the composite character of the formation is shown the contacts between successive sheets are nearly horizontal. It is probable that the formation as a whole varies considerably in its dip at different places, but has in general a centrif- ugal inclination with reference to the domical structure of about 10°. The thickness is roughly estimated at from 600 to 800 feet (183 to 244 meters). The next tectonic element to be considered after the andesite is the dacite. This rock, while involved in the architecture of the dome, is so irregular in its occurrence as to obscure rather than to accentuate the structure of which it is a part. The evidence of the intrusive relation of part of the dacite with reference to the andesite and older rocks is presented on page 58; it remains in this chapter to consider the form of the intrusive masses and their relation to the general structure. The most important body of dacite from an economic point of view is that lying northeast of Goldfield and containing the principal mines of the district. Although the general form of the mass, particularly when considered with reference to the domical structure, leaves little room for doubt of its intrusive character, there are, unfortunately, no exposures in which the relation of this body to the andesite is clearly displayed at any one locality. In most places the contact can be determined with an accuracy commensurate with the scale of the map (PL II), but the actual plane of separation between the dacite and the rocks which it cuts is rarely visible or is obscured by alteration. The mass, as may be seen from the geologic map, prac- tically cuts across the andesite annulus from east to west. It has the form of an irregular sheet. The thickness of the dacite is least to the east, where the sheet thins to an edge, and is greatest along a trough-like depression which extends from the vicinity of the Hazel-Goldfield shaft toward Florence Hill. (See fig. 2.) This depression (see also PI. II; PI. VIII, sections C-C' and D-D') is in the general line of prolongation of the fault southward, due allowance being made for the dip of the latter. The depth of the bottom of the dacite along this line ranges from 685 feet (209 meters) at the Hazel-Goldfield mine, to 615 feet (187 meters) at the Clermont shaft. South of the Clermont shaft the dacite has probably not yet been penetrated in its thickest part. West of this line the bottom of the sheet in general rises at an average angle of about 30°, although as shown in section C-C, Plate VIII, a part of the mass appears to extend as a dike to an indeterminate depth. It is possible that future exploration may not only establish this abyssal continuation but may reveal other connections of the sheet with its deep-seated source. Along its southern boundary the dacite sheet ends with a steep irregular intrusive contact against the Milltown andesite. There is nothing to show that it does not extend indefinitely downward along at least the western part of this contact. (See PI. VIII, section G-G'.) 80 THE GEOLOGY AND ORE DEPOSITS OF GOLDFIELD, NEVADA. That the under surface of the dacite is far from even is indicated by the data assembled in figure 2 and by the relation of the contact between this rock and the underlying formations south and southwest of Vindicator Mountain. The two deepest points yet found on the bottom of the dacite are, as already mentioned, at the Hazel-Goldfield shaft (685 feet or 209 meters) and at the Clermont shaft (615 feet or 1S7 meters). The Oddie shaft on the Combination Fraction claim has not penetrated through the dacite at 612 feet (187 meters), so that the thickest part of the sheet may be between this shaft and the Clermont. (See fig. 2.) Both east and west of this approximately north and south line, which may conveniently be referred to as the keel of the dacite mass, shafts pass out of the dacite at depths which, in a rough way. N. k 1000 2000 3000 feet Line of maximum thickness of the dacite sheet MUSHETTd D.480 C?80 rRISCO B CROOKS kD.I50C.I30 i D. 400 if. 140 B FIVE FRIENDS CONS. RED TOP d!s60 C.S60 + o D.3O0 C.300+ n KEWANA'i h' hazel- gold. I D.740 C.685 ° LACUNA RED TOP 0.400 C400 D.350 C.3O0*.0 I ■ p CHICACO^-VELVET ALTA D.536' C.380 I MOHAWK lEOGE " O. 700 C.U-50 I I B MOHAWfK 0.600 0,450 CODO D^soo c^QO + MOHAWK- JUMBO D.SOO C.SOO+B o CLERMONT D.9ZO C.6/5 SIMBULL D.200 C.I50±Z- SIMMERONE COMMONWEALTH o/fOO C.IOO± Figure 2. — Plan of the dacite mass near GoklfioM, showing positions of shafts that penetrate it, their depths in feet (D), and the depths (C) at which they go into the underlying rocks. vary inversely as the distance from the keel. There are, however, some notable irregularities, as is to be expected in an intrusive body. The Codd shaft on the St. Ives claim, for example, is in latite at 500 feet (152 meters) and is said to have gone through the dacite at about 400 feet (122 meters) or less. The St. Ives shaft, a short distance farther east and 470 feet (143 meters) deep, is still in dacite. A little farther east, the new Goldfield Merger shaft, according to a letter from Mr. II. P. Henderson, passes out of the dacite at 412 feet (125 meters). The collar of the St. Ives shaft, it is true, is about 15 feet (4.6 meters) higher than that of the Codd shaft and 25 feet (7.6 meters) higher than that of the Merger shaft. When these corrections GEOLOGIC STRUCTURE. 81 are applied, however, the data furnished by the three shafts show that the bottom of the dacite does not rise regularly to the east. Undoubtedly much remains to be learned regarding the configuration of the under surface of the dacite. This has been reached now in over a score of shafts, but these are not all so placed as to afford the most geological information. In most places the rocks at the contact are soft and the shafts closely lagged, so that for information concerning the change of formation the geologist must depend upon the memories and observations of those who performed the work of sinking; elsewhere the rocks are mineralized, as in parts of the Mohawk and Mushett mines, and their original character is thereby obscured. Some of the movements that have disturbed the rocks in this part of the district (in a manner and to an extent presently to be described) have affected the under contact of the dacite and probably in part caused the local softening which is its prevailing characteristic. The soft, gouge-like material ("mushy stuff") in the Goldfield Merger shaft is reported to be about 12 feet (3.6 meters) thick. Without much question some of the irregularity in the lower surface of the dacite is due to a step-like structure produced by faulting. It is not possible at present to identify any of these faults at the surface or to trace them from point to point underground. East of the Red Top mine a tongue-like area of Milltown andesite is shown on Plate II and figure 2 as extending into the dacite toward the Velvet mine. The relations of the rocks are here somewhat obscure. The andesite apparently underlies the dacite in part, but is here rather thin and is underlain by latite. Several shafts, including the Alta, 418 feet deep in 190S, go through the andesite into latite, although the depth of the contact could not be ascertained. The Chicago shaft, just west of the Alta, is in dacite to a depth of 3X0 feet. The contact of the dacite with the Milltown andesite and the latite must at this place therefore be very steep. It is not exposed and it is not known whether it is an intrusive contact or a fault contact. Below 3S0 feet the Chicago shaft went through about 30 feet of soft andesite or andesitic tuff and then into latite, which was the rock in the sump (410 feet) in July, 1908. As regards the original upper surface of the dacite sheet little information is available. The small area of Milltown andesite on the hill above the Mohawk mine is probably a remnant of the original cover of the laccolithic intrusion. This andesite is soft and decomposed, and since it was mapped in 1905 its surface has been largely covered up by dumps from the mines. It is evidently thin as it does not appear in the present underground workings. Of the shapes of the other masses of dacite represented in Plate II little more is known than can be learned from a study of the mapped outlines, with reference to the topographv. That they are for the most part very irregular in form is evident. Such irregularity, togetner with the distribution of the masses at variance with the rough concentric structure of the dome as a whole, is regarded as sufficient to establish the intrusive character of the dacite. Con- firmatory evidence is supplied at a locality 1 J miles east of McLaughlin's well, practically on the line of section C-C, Plate VIII, where the dacite may be seen in close igneous contact with andesite, both rocks being comparatively fresh (see p. 58); and at various points along the southern contact, as shown on page 59. Although the dacite is for the most part unquestionably intrusive, there are some indica- tions that the intrusion took place within a very moderate distance of the then existing surface. At the locality just mentioned the dacite not only shows glassy facies near the contact, but in some places exhibits flowage structure. Moreover, near Tognoni Springs the dacite, as previously shown, passes into a flow, showing that the lava in this part of the district actually broke through its thin cover and welled over the surface. Evidence of the same kind as that adduced in relation to the Morena rhyolite also supports the conclusion that the dacite intrusion was not deep-seated. The dacite is older than the Siebert formation, and so could not have served as cover. The only rocks in the district which can be supposed to have played this passive part are the andesite and older rocks cut by the dacite, and the dacite vitrophyre exposed in the southern part of the district. As stated on page 64, this dacite vitrophyre is supposed 79145— No. 66—09 6 82 THE GEOLOGY AND ORE DEPOSITS OF GOLDFIELD, NEVADA. Surface to have been erupted at nearly the same time as the dacite intrusion. It undoubtedly cov- ered a considerable part of the district north of its present exposures, and may possibly have constituted a blanket of extrusive material under which the dacite solidified as superficial intrusions from the same magma reservoir that had supplied the vitrophyre. The important dislocation which has been called the Columbia Mountain fault demands some consideration at this stage, particularly as regards its relation to the dacite intrusion. The fault, as shown in Plate II, has been traced from a point nearly east of Kendall Mountain to the eastern end of the town of Columbia, a distance of 2 miles. It dips to the east and has a normal throw, the Milltown andesite being relatively dropped against the older rhyolites and pre-Tertiary rocks of Columbia Mountain. The structural effect of the fault is the uplift of the rocks west of it relatively to those east of it. As a consequence of the general erosion of the dome these locally uplifted older rocks, including the Cambrian sediments, alaskite, and rhyolites of Columbia Mountain, now appear at the surface, whereas in other parts of the district equally distant from the center of the dome they are buried under younger formations. The fault is very poorly exposed. It is followed by an inclined shaft at the Conqueror mine, where the dip is from 20° to 25°. The shaly Sandstorm rhyolite which forms the foot wall is much disturbed and much of the andesite of the hanging wall is crushed to a soft gouge. Some of the crushed material contains pyrite and is said to yield assays up to $12 per ton. A crosscut from the bot- tom of the 55-foot verti- cal shaft of the Con- queror mine affords the section shown in figure 3, where movement along the fault plane is recorded by a tough clay gouge and much crushing of the an- desite. The same gouge is reached in a prospect shaft sunk through the andesite just south of the Conqueror workings. From this shaft southward there are no exposures of the fault plane until the southeastern slope of Columbia Mountain is reached. Here the Columbia Mountain No. 1 tunnel cuts through the fault plane, which separates crushed, fissured, and much-altered dacite from Cambrian sediments that are generally shattered and also show some Assuring approximately parallel with the main fault. The principal plane of dislocation appears to dip 45° E. South of the tunnel and north of the water tank the outcrop of the fault passes through a saddle, and on the south slope of the mountain it coincides with a little ravine eroded in the soft, crushed material of the fault zone. A crosscut from the 200-foot level of the Booth shaft, just east of this ravine, is said to reach the fault, but this shaft was closed at the time of visit in 1908. The most southerly underground exposure of the fault is in the workings of the Consoli- dated Red Top Leasing Company. This shaft is about 250 feet east of the outcrop of the fault, which is rather indistinctly exposed in a railway cut. The bottom of the shaft, 300 feet dec]), is in soft crushed dacite. A crosscut to the west, 30 feet in length, is in Cambrian shale at the face, and from this point a drift has been run south along the fault. This drift is all in soft, much-disturbed ground, shale and Kendall tuff being mingled in great confusion. The +. Andesite * .; \ "x*l / S \ ^_ w v - / *>s Shaly San ■SE. y sandstorm ■ rhyolite Columbia Mountain fault zone Figuhe 3. — Section across the Columbia Mountain fault at the Conqueror mine. GEOLOGIC STRUCTURE 83 material is apparently all within the fault zone and it is doubtful whether the real foot wall has been reached. The position of the fault on this leveltaken in connection with the exposure in the railway cut gives a dip of 55° E. When the preliminary report on the district was prepared, the most reasonable explana- tion of the obscure structure south of Columbia appeared to be the postulation of a transverse northwest-southeast fault which was supposed to offset the main fault. The latter was thought to continue southward beyond this offset past the January mine and to constitute the boundary between dacite on the east and latite on the west. Thorough revision of the geologic mapping south of Columbia Mountain in 1908, aided by the numerous shafts sunk in this part of the district since 1905, many of which gave definite information where previously the kind of rock beneath the mantle of surficial material could only be guessed, showed that the original inter- pretation was erroneous. The hypothesis of a transverse fault had to be abandoned. More- over, as shown on pages 58 to 59, the evidence bearing upon the relation of the dacite to the latite west of it, while not entirely conclusive, is more accordant with the supposition of an intrusive contact modified by many local fault slips than of juxtaposition effected primarily and chiefly by faulting. The throw of the Columbia Mountain fault can not be accurately determined. It may amount to 400 to 500 feet (122 to 152 meters). (See PI. VIII, section A-A'.) It was supposed at one stage of the investigation that the Columbia Mountain fault was younger than the dacite, but the evidence now available points to a different conclusion. Refer- ence to the geologic map (Plate II) shows the fault as ending about 600 feet (1S3 meters) north- west of the Red Top mine. At this place the dacite passes westward across the line of disloca- tion. South of the end of the fault the dacite is much fissured and the great ore bodies of the Red Top, Mohawk, Combination, Jumbo, and Florence mines occupy a zone of great disturbance which lies in the general path of the Columbia Mountain fault. Throughout this entire zone the dacite is traversed by an extraordinary number of fissures which carry soft gouge and which in the aggregate undoubtedly record much movement. So numerous are these slips, so varied in trend, and so frequently do individual fissures exhibit unexpected departures from a straight course that it is at present impossible to group them systematically or to identify any particular exposures as parts of a single dominant fault zone. The most that can be said is that the more important ones have a general north to north-northwest course. Can this Assuring record the whole of the movement represented by the Columbia Mountain fault? I believe not. It is too dispersed and irregular. There is at present no evidence that the dacite sheet as a whole has been displaced to anything like the extent it would have been had it been affected by the total movement represented by the Columbia Mountain fault. The hypotheses suggested as best accounting for the facts at present known are: (1) That the dacite was intruded after the main movement along the Columbia Mountain fault had taken place; (2) that the intruded magma to some extent followed the fault, possibly in some places coming up along it, and spread out where opportunity offered into sheetlike or laccolithic form; (3) that the Columbia Mountain fault continued, after the intrusion, to be a line of structural weakness and move- ment; and (4) that such renewed movements along the fault produced in the dacite, lying athwart the path of the dislocation, stresses which were relieved by complex Assuring of the brittle mass. Other stresses probably also contributed to this result, but it is believed that this revival of movement along the Columbia Mountain fault had a very important part in the Assuring and mineralization of the remarkable little area which has produced nearly all the gold thus far mined in the district. As stated on page 39, the boundary between the Kendall tuff and the latite, just south of Columbia, is probably a fault. No geologic examination- has been made of this contact, as it is not actually exposed at the surface, and the shafts in its vicinity had all been abandoned in 1908. This fault, like the Columbia Mountain fault, apparently ends at the dacite and is supposed to be older than that rock. South of it the Siebert formation laps over the pre- lacustrine rocks and little is known of their structure. Minor faults are certainly abundant in this part of the area and it is not improbable that future development, such as is planned by 84 THE GEOLOGY AND ORE DEPOSITS OE GOLDEIELD, NEVADA. the White Rock Mining Company, may establish the existence of structurally important dis- locations now concealed by the Siebert formation. The faults in the vicinity of Vindicator Mountain are perhaps of the same age as the Columbia Mountain fault, but there is nothing to show that they may not be considerably older or younger. They are normal faults of moderate displacement and are not very well exposed. There are undoubtedly other faults in the district that have not been mapped. Those only are shown for which there is satisfactory evidence. There are many places where structural relations might be explained by hypothetical faults drawn where exposures are wanting or where the general disturbance and alteration admit the possibility of a fault while at the same time they prevent any definite proof or disproof of its presence. Like the andesite, Sandstorm rhyolite, latite, and Vindicator rhyolite, the dacite vitrophyre is one of the annular elements of the domical structure, though apparently not a complete one. As exposed in the southern part of the district, it laps at a low angle over the andesite and is overlapped in turn by Meda rhyolite, andesite breccia, and Siebert formation. Its thickness is not accurately determinable, but is estimated at about 400 feet. If the dacite vitrophyre ever extended over the whole area now occupied by the Goldfield dome it has been eroded away from the northwestern half, where the Siebert formation rests directly upon Milltown andesite or older rocks. The youngest rocks that participated in the domical uplift are the sediments of the Siebert formation and the volcanic flows intercalated with them, particularly the Mira basalt. The Siebert beds are prevailingly soft and are readily eroded, so that in most places they are covered by detritus which has been derived in large part from the underlying formation. Consequently the detailed structure of the beds is generally concealed or. is very obscurely shown. Along the northern border of the district the Siebert beds show little disturbance other than a gentle tilt away from the center of the dome. In some places, as north of McMahon Ridge, the erosion surface upon which the sediments accumulated appears to have been fairly even. In other places, as in the northeastern corner of the district, tufTaceous sands and beds of pumice seem to have accumulated in hollows amid hills. It is impossible, however, to distinguish with certainty between prelacustrine irregularities of surface and possible local deformation connected with postlacustrine basaltic outflows. Along the western border of the district, north of Goldfield, the Siebert rocks are too poorly exposed to throw much light on their structure. That they were laid down upon an unevenly eroded surface is indicated by the character of the eastern boundary of the sediments as they lap up over the older volcanic rocks, and by the andesitic hill which rises through the lacustrine deposits near the Tonopah and Goldfield Railroad. Southeast of Goldfield the Siebert beds are well exposed in the bluffs at the edge of the basaltic mesa, where the prevailing dip is about 18° W. It is certain that in this part of the field the Siebert formation, as represented in sections D-D' and E-E', Plate VIII, has been thrown into open folds. Existing exposures, however, are insufficient to furnish the key to the details of this" folding. If the former connection between the residual masses of Mira basalt south of Myers Mountain and the main part of the intercalated flow south of Goldfield were restored, the whole would form a buckled sheet nearly horizontal or with a low dip to the northwest along its northeastern margin, but with a dip of about 18° W. where the Mira basalt passes under the mesa. (See PI. VIII, section E-E'.) On the east side of the Goldfield dome the annulus of Siebert beds is not complete. The andesite and dacite extend for 5 or 6 miles beyond the boundary of the area here described, and Ball's map (see PI. IV) shows that the Siebert formation, if present, is covered by Quater- nary deposits which overlap the Tertiary lavas. With the post-Siebert deformation the Goldfield dome came into existence. Of the stresses which produced the structure practically nothing is known. Was the region gently arched by lateral centripetal pressure or was the ascensional force mainly a direct vertical up thrust? Were the rocks actually elevated or did the central part of the dome merely la'' behind the rest of the region in a general subsidence? These are questions upon which some speculation GEOLOGIC STRUCTURE. 85 is permissible provided the lack of real knowledge be not forgotten. We do know that through- out Tertiary time the entire region was the theater of volcanic activity and of crustal disturb- ances, the present results of which differ greatly in character in localities not necessarily far apart. The elaborate faulting described by Spurr at Tonopah, for example, has no counter- part in the structure at Goldfield, and this, in turn, has little in common with the faulting in the Bullfrog district. We may conclude with some reason that diastrophism or crustal movements and volcanism were genetically connected, and, with somewhat less confidence, that in general some subsidence followed the extensive transfer of lava from subcrustal regions to the earth's surface. As different lavas were erupted at different times in different parts of the region such subsidence, if it occurred, must have been intermittent and can scarcely be conceived of a? proceeding at an equal rate over the entire tract affected by Tertiary volcanism. While one area was sinking an adjoining area might be quiescent or even rising; between the two would be developed stresses which might find relief in complex faulting. Thus the development of domical and other flexures and of local fields of faulting is in a general way susceptible of genetic correlation with volcanicity. The actual mechanism in each case, however, is entirely concealed. After the Goldfield region had been domed, erosion appears to have reduced it to a surface of comparatively low relief. This was partly covered by the postlacustrine flows, of which those of olivine basalt are most important. Subsequent erosion, extending to the present, has cut through and carried away the greater part of these flows, leaving the remnants as tab- ular cappings to buttes and mesas in outlying parts of the district. These remnants, as may be seen from Plate II, occur at various elevations and have perhaps suffered some changes in altitude by crustal warping of the region. The observed differences in elevation of the bases of the various remnants of the basaltic flows, however, are not too great to be accounted for by the flowage of the lava over an originally uneven surface. That some deformation has taken place subsequent to the basalt eruptions is shown by minor faulting southwest of Goldfield. The small hill at the mouth of Pozo Canyon is appar- ently part of a triangular fault block in which some of the rhyolite and basalt of the mesa have been dropped into the Siebert beds. Other minor faults are shown which slightly displace the rocks capping the mesa. (See PI. II.) These faults are comparable in age and character with the post-Siebert faults so abundant at Tonopah. Dislocations of this epoch, however, are of very slight structural importance at Goldfield, although perhaps not entirely confined to the one locality southwest of town. Faults of similarly small throw occurring in the older volcanic formations in the central part of the dome might escape recognition. CHAPTER IX. GEOLOGIC HISTORY AND CORRELATION. INTRODUCTION. Since the historical sequence has served in the preceding chapters as a framework for the orderly presentation of lithologic and structural description, the reader already has an insight into the geologic development of the Goldfield district. It is the purpose of the present chapter, however, to narrate the series of geologic events with greater clearness and with more regard to their broader relationships than was possible while the attention has been occupied with descriptive details — with the slow inductive steps that have led, as it were, to the crest of an eminence whence the whole region previously traversed may be comprehensively viewed. It is believed that this purpose will be served most directly by first summarizing the local geologic history with as little reference as possible to regional correlation. With the sequence of local events well in mind, the relations of the Goldfield rocks to those of the surrounding region may then be considered, and finally such conclusions will be drawn as are permissible regarding the Tertiary chronology and the succession of the lavas in this part of the Great Basin. Such is the general plan of this chapter. The pre-Tertiary rocks, however, have so little prominence in the part of the geologic record with which this paper has chiefly to do, that it seems best to depart, with respect to them, from a rigidly systematic treatment and to combine some suggestions of correlation with the local narrative. This early clears the way for the con- centration of an undivided attention upon the Tertiary. LOCAL, GEOLOGIC HISTORY. BEFORE TERTIARY TIME. The records of what took place prior to the opening of Tertiary time are fragmentary. During the early part of the Paleozoic, probably in the Cambrian, thin-bedded calcareous and quartzose sediments were laid down upon a surface of still older rocks. Of the pre-Cambrian surface no vestige is visible in the Goldfield district at the present time. Moreover, the recon- naissance of S. H. Ball ° over a region more than 8,500 square miles (22,100 square kilometers) in extent, lying mostly south and east of Goldfield, has revealed no rocks certainly older than the Cambrian. The nearest pre-Cambrian rocks shown by J. E. Spurr on his earlier reconnais- sance map6 are at the south end of the Kingston Range, in California, 150 miles (241 kilometers) south-southeast from Goldfield and in the Kern Mountains and Snake Range, 200 miles (322 kilometers) to the northeast of the district. Ball c notes that the Cambrian Prospect Mountain quartzite in the wSpecter Range, about 95 miles (153 kilometers) southeast of Goldfield, con- tains pebbles of sedimentary rock and of granite, thus giving a clue to the local character of the vanished pre-Cambrian terrane. The masses of Cambrian rocks exposed in the Goldfield district on Columbia and Vindicator Mountains are mere fragments which probably belong in the upper division of the lower Cam- brian as mapped by Ball — the Prospect Mountain limestone of Arnold Hague,d renamed by i A geologic reconnaissance in southwestern Nevada and eastern California: Bull V. S. Geol. Survey No. 308, 1 Descriptive geology of Nevada south of the fortieth parallel: Bull. U. S. Geol. Survey No. 208, 2ded., 1905, PI. I. e Op. Ctt., p. 38. i Geology of the Eureka district. Nevada: Mon. U. S. Geol. Survey, vol. 20, 1892, p. 36. LOCAL GEOLOGIC HISTORY. 87 Walcotta the Eldorado limestone. Rocks belonging to this division, according to Ball,h are extensively exposed in hills to the north, west, and south of the Goldfield district and contain a lower shale member at least 1,000 feet (305 meters) thick, an overlying limestone several thou- sand feet thick, and probably a second shale member. The Goldfield masses are thought to rep- resent remnants of the thick lower shaly member. Although it is known that Ordovician, Silurian, and Carboniferous beds were deposited in southwestern Nevada, no representatives of these periods occur within the Goldfield district, nor, so far as known, within a radius of 40 to 50 miles (64 to 80 kilometers). The history of Paleozoic time subsequent to the Cambrian is locally blank. Presumably there was deposition, the products of which were afterwards swept away by erosion. The first authentic record following that of Cambrian deposition is supplied by the intrusion of the alaskite now exposed in the central part of the Goldfield dome. The geologic date of this intrusion, which greatly disrupted the Cambrian beds, is not certainly known, but, as shown on page 35, the work of King and later observers affords a strong suggestion that it took place at the close of the Jurassic or beginning of the Cretaceous, being thus generally contemporaneous with the main granitic intrusions of the Sierra Nevada. As the alaskite has all the characteristics of a deep-seated or plutonic intrusive, it may be concluded that it solidified under a considerable thickness of other rocks. The undoubted deformation of the Cambrian rocks at the time of intrusion suggests that a mountain range may have come into existence in the Goldfield region at the opening of the Cretaceous. Clarence King,0 thirty years ago, noted the absence of Cretaceous deposits from the section of the Great Basin lying between the Wasatch and Sierra Nevada ranges, and subsequent work has all tended to support the conclusion that throughout this long period that part at least of the Great Basin included within the boundaries of Nevada was a land mass undergoing erosion.d The results of Spurr's and Ball's reconnaissances, as well as the local history recorded in the rocks at Goldfield, accord with this generalization. During the Cretaceous the region was greatly eroded. Whatever mountains may have existed on the site of Goldfield were destroyed, the once deeply buried alaskite was exposed over broad areas, and the country was character- ized at the end of the period by a topography of low rounded hills, which swelled above rolling plains or merged into open, gently sloping valleys. There is no evidence of any extensive accumulation of soil or of any vigorous growth of vegetation upon this pre-Tertiary surface. So far as appears from the few exposures available, the slopes were of rock, here and there thinly veneered with stony detritus derived mainly from the metamorphosed Cambrian shales. The landscape at the close of the Cretaceous, could one have seen it, must have been expressive of long-continued crustal stability and of the waning power of denudation concomitant with the reduction of relief. It could have afforded little suggestion of the next scene in the geologic drama. Although erosion reduced what is now the Goldfield district to comparatively low relief, Ball's work shows that no extensive peneplanation was effected over the surrounding region. His statement e is: A long period of erosion, extending at least to Eocene time, followed the post-Jurassic folding and consequent mountain building. This period was probably one of heavy rainfall and large rivers. No estimate can be formed of the amount of erosion, but it was sufficient to remove from the granite the covering beneath which it solidified. Not- withstanding the length of this erosion period, no peneplain was formed. From this it is inferred that the area was subjected to successive uplifts while being eroded. Where exposed beneath the oldest Tertiary formation, the Paleo- zoic rocks appear to have been eroded into mountain ranges, many of which have a north-south extension. Some of these mountains of Paleozoic rocks — for example, the Kawich Range — were fully as high and rugged as the present ranges. a Walcott, C D., Cambrian geology and paleontology. No. 5: Cambrian sections of the Cordilleran area. Smithsonian Miscell. Coll. No. 1 312, Washington, 1908, p. 184. & Op. cit., pp. 51-52. cTJ. S. Geol. Expl. 40th, vol. 1, Systematic geology, 1S78, pp. 29C-297. dSee also Chamberlin, T. C, and Salisbury, R. D., Geology, vol. 3, 1900,' figs. 379 and 388. e Op. cit., p. 40. 88 THE GEOLOGY AND OEE DEPOSITS OF GOLDFIELD, NEVADA. Farther north, in the Humboldt region, G. D. Louderback a found that the post-Jurassic erosion resulted in a topography of very low relief, approaching a peneplain, and comparable, apparently, with that developed in the Goldfield district. TERTIARY PRELACUSTRINE EPOCH. At a time which can not be definitely fixed, but which may provisionally be identified with the Eocene, lavas broke through the eroded surface just described, and their appearance marked the beginning of a period of active volcanism, which continued through the Tertiary. The first volcanic eruption in the Goldfield district is represented by the Vindicator rhyolite. This flow, as described on page 37, is exposed on the slopes of Vindicator Mountain and forms the summit of Columbia Mountain. Its original extent is unknown. It does not appear on the alaskite exposed near Banner Mountain, but its absence from that locality* may be due to erosion prior to the next volcanic outburst. The Vindicator rhyolite was followed in the Goldfield district by one or more flows of latite, which probably covered the older rocks completely. The vents whence the latite issued are entirely unknown. The prevalent alteration of the rock interferes with a complete deter- mination of its original character and renders comparison with rocks in neighboring districts uncertain. There is, within the Goldfield district, no definite evidence of erosion of the latite prior to the succeeding eruptions. Ball,6 however, reports an erosion unconformity in the Kawich, Amargosa, and Cactus ranges, in the Bullfrog Hills, and in the Shoshone Mountains/ between rocks supposed to be the equivalent of the latite and subsequent flows. In general accord with the views of Spurr,d he regards this unconformity as marking the division between the Eocene and Miocene, thus placing the Sandstorm and Morena rhyolites and the Milltown andesite in the Miocene. The question whether they belong there will be considered later. Following the latite, with perhaps an interval of erosion, came the eruption of the Kendall tuff and Sandstorm rhyolite/ The tuff and the character of the rhyolite indicate the proximity of a local center of explosive eruptions which it is thought lay just north of the site of Columbia Mountain. Beneath the volcanic pile which probably rose in this part of the district were intruded the masses of Morena rhyolite and the solidification of these brought to a close the second epoch of rhyolitic eruptions. As described on page 78, erosion appears to have attacked with energy the volcanic accumulations and reduced them to such an extent that the intrusive Morena rlryolite was laid bare. The Milltown andesite flows which, with some tuff and a local outpouring of basalt, record the next volcanic disturbance not only are one of the most important formations in the Goldfield district but, as Ball's map shows, are part of the largest area of such rocks in the entire region covered by his reconnaissance. Their distribution suggests that these lavas were erupted from vents within the tract now corresponding to the Goldfield Hills. The andesites of Goldfield constitute a volcanic complex in which biotitic hornblendic and pyroxenic andesites are inextricably involved, the connection in many places being apparently through an actual gradation of one variety into another. After the cessation of the andesitic eruptions the series of lavas was faulted and was invaded by dacitic magma. It is probable that erosion had already begun to attack the andes- ites before the intrusion of the dacite, but of this there is no clear evidence, and the two periods of eruption were probably separated by an interval of time geologically brief. The reasons for supposing that the dacite was a comparatively superficial intrusion which passed into extrusive flows to the eastward have been given on page 81. It has also been suggested (p. 64), although not demonstrated, that the dacite vitrophyre also represents a part of the dacite magma which, perhaps a little later, broke through the thin cover of andesite and o Basin range structure of the Humboldt region: Bull. Geol. Soe. America, vol. 15, 1904, pp. 307, 337. 6 Op. cit., pp. 32-33. c A small group of hills east of the Bullfrog district, in latitude 37°; not the Shoshone Range of the Fortieth Parallel reports. & Succession and relation of lavas in the Great Basin region. Jour. Geology, vol. 8, 1000, p. 037. ' On Ball's reconnaissance map the areas of Sandstorm ami Morena rhyolite north of Columbia are colored as ''middle Miocene rhyolite." which would make them later than the andesite and dacite of the Goldfield district. This is doubtless a mere oversight in the reproduction of the map. LOCAL GEOLOGIC HISTORY. 89 poured over the surface as lava flows. There were also minor contemporaneous eruptions of andesite, for flows of this rock (Chispa andesite) are associated with the flows of dacite vitrophyre in the southern part of the district. Next came the eruption of the Meda rhyolite, followed probably by the intrusion of the andesitic dikes which cut the dacite vitrophyre in the southern part of the district and which are provisionally correlated with the eruption of the andesitic breccia exposed at the southern edge of the mapped area. Whether there was any considerable erosion of the dacite and earlier volcanic rocks before the initiation of the lacustrine conditions next to be described is not clearly shown in the Goldfield district. LACUSTRINE EPOCH. Up to the stage in the geologic history now reached there has been no indication that the Goldfield district was at any time during the Tertiary an area of sedimentation. Erosion was presumably more or less active, but its products were either carried to the sea, which is known to have extended in Eocene time into the Mohave Desert region," or were deposited in lakes outside of the Goldfield area. After the dacitic eruptions, however, most of the area now known as the " Goldfield district " was submerged beneath the waters of a lake. This body of water was no local feature, but, as will later be shown, probably covered a large part of western Nevada and owed its existence to conditions that changed the aspect of a wide region. Since the lacustral sediments at Gold- field attain a thickness of probably 1,000 feet (305 meters), the lake was in all likelihood deep, although to some extent deposition and submergence may have gone on together. On the other hand, the character of the beds indicates that they were laid down at no great distance from land, and some of them may be regarded as shore deposits. The inference is that the submerged topography was of strong relief. The lake probably possessed a deeply indented shore line and was diversified by numerous rugged islands and peninsulas. There can be little doubt that on some of the mountainous islands and about the shores of the lake volcanoes were in intermittent eruption. Clouds of siliceous volcanic dust must at times have swept over the ruffled surface of this inland sea, and pumice either fell into the water or was brought down by streams from the volcanic slopes to drift about, to gather in sheltered bays, and finally to subside in a water-logged condition to the bottom. Occasionally flows of lava appear to have entered the lake and spread over part of the sediments previously deposited on its bottom. These were chiefly thin sheets of rhyolite, but at one time there was an important flow of quartz-bearing basalt. Throughout this epoch erosion was attacking with energy the loose volcanic material supplied to the land by the eruptions and was cutting also into the older rocks. Great quantities of sedimentary material were thus carried into the lake to mingle with and alternate with the products of ash showers and the layers of diatom frustules, while coarse imperfectly rounded fragments were dropped near shore by torrents which rushed down the mountain sides. The prevalence of diatomaceous deposits in the Siebert formation shows that the lake was fresh throughout most of its existence. The beds exposed in the district afford no suggestion of deposition under saline conditions. Finally, through changes that were associated with, if not produced by, orographic move- ments, the lake was drained, its sediments were folded, perhaps faulted, and the Goldfield dome came into existence. POSTLACUSTRINE HISTORY. With the disappearance of the lake waters erosion began to attack the sediments, and soon stripped them away from part of the domical uplift, which, indeed, they may never have entirely covered. The final result of this period of denudation appears to have been the reduc- tion of the region to a surface of low relief, with at least some local peneplanation, as is shown "See Arnold, Ralph, and Strong, A. M., Somecrystalline rocks of the San Gabriel Mountains, California: Bull. Geol. Soc. America, vol. 16, 1905, p. 188, footnote. Apparently the first recognition of the Eocene age of these rocks was by W. P. Blake in the Pacific Railroad Reports, vol. 5, 1856, map III. 90 THE GEOLOGY AND ORE DEPOSITS OF GOLDFIELD, NEVADA. by the manner in which the horizontal lava flows of the mesa southwest of Goldfield lie upon the smoothly truncated edges of the old lake beds (Siebert formation). The accumulation of the fluviatile Pozo formation belongs to this period of erosion, which was followed by a renewal of volcanic activity, recorded by the two lava flows composing the Spearhead rhyolite. Overlying the Spearhead rhyolite is the Rabbit Spring formation, consisting of rhyolitic sandstone and volcanic conglomerate, with a total thickness of about 15 feet (4.5 meters). This deposit may possibly have been laid down in a shallow transient lake, but the evidence for a return of lacustral conditions is far from conclusive. The deposit probably represents the action of shallow streams, which spread over the nearly horizontal surface of the lava flow. Whatever the origin of the Rabbit Spring formation, the time occupied in its deposition was brief, and the sedimentary material was soon covered by the Malpais basalt. Miocene! Eocene! Pre Tertiary. Malpais basalt. Rabbit Spring formation. Spearhead rhyolite. Pozo formation. Siebert formation. Mira basalt. Siebert formation. Meda rhyolite overlapped by andesite breccia. Dacite vitrophyre. + + + + + + ++ + + ■*-+ + + + ++ + ' ' ii'1 Chispa andesite. Dacite vitrophyre. Milltown andesite and intrusive dacite. Sandstorm rhyolite cut by dacite and Morena rhyolite. Kendall tuff cut by dacite and Morena rhyolite. Latite cut by dacite and Morena rhyolite. Vindicator rhyolite. Alaskite and granite intrusive into Cambrian shale. rrpMrj^iHtt WrM Wt r- f Trnm-nTm^ ^ u r A ^T~^-^-^-g^!Lyp ^ a g f rr* »+ + t + t + + + + + ± + +-±T_iy-^ /\ / 1 / v / \ / \' \ 'I/«?#}7#'' Unconformity. Unconformity. Unconformity. Unconformity. LonK erosion interval. Figure 4.— Generalized columnar section of the rocks of the Goldfield district. Since the basalt solidified the district has been subjected to some minor faulting and prob- ably also to some unequal settling or warping of its surface. Erosion has cut through the basalt, dividing what was probably once a continuous sheet into the various remnants now capping mesas and flat-topped buttes, has excavated the broad valley in which the town of Goldfield lies, and has carved the hills into their present forms. As shown on page 75, there is some evidence in the shape of gravel deposits which indicates a stage in the erosion when the drain- age was notably different from that now developed in the district. There is a possibility that this earlier drainage may have been associated with a brief lacustrine period, but the observable facts justify no more than this bare suggestion. LOCAL GEOLOGIC HISTORY. 91 The general sequence of events in the Goldfield district is summed up in the accompanying columnar section (fig. 4). For convenience in subsequent comparison and correlation, Ball's general columnar section of southwestern Nevada is reproduced as figure 5. v a, Desert travels. Older alluvium. Basalt. other alluvium, with Pliocene lake beds at base. Rhyolite. Siebert lake beds, with rhyolite and basalt Hows, Rhyolite. Basic andesite. Second rhyolite, with minor basalt H>>\\ s Monzonite porphyry and aridic andesite. First rhyolite. Pennsylvania]! limestone. Weber conglomerate. Silurian. | Lone Mountain limestone. Eureka quartzite. Pogonip limestone. Prospect Mountain limestone. Prospect Mountain quartzite. ^~ " *. *// X II — II fctt_- £ IMIIlnifllllHl m&m Unconformity. Unconformity. Unconformity. Unconformity. Unconformity. Unconformity. Unconformity. Figure.5.— Columnar section of rocks of southwestern Nevada and eastern California. After S. If. Ball (Bull. U.S. Geol. Survey No. 308, 1907, p. 27). [The extension of the Pliocene down to include the Siebert lake beds is clearly an oversight. To be consistent with the table of Bulletin 308 (reproduced on page 93) and with the text of Ball's report, the base of the Pliocene should coincide with the unconformity at the top of the Siebert. The " Prospect Mountain" limestone is now known as the Eldorado limestone. — F. L. R.] CORRELATION OF THE GOLDFIELD TERTIARY ROCKS WITH THOSE OF THE SURROUNDING REGION. INTRODUCTORY STATEMENT. Throughout that part of the Great Basin included in western Nevada marine fossils of later time than the Jurassic are unknown, and, as has previously been stated, the orogenic disturb- ances at the close of that period in all probability resulted in the final exclusion of the sea from the region. Thus definite paleontological correlation, such as is usually possible in the case of persistent and fossiliferous marine deposits, is not attainable. Recourse must be had to scanty fresh-water faunas or land floras as yet of more or less doubtful determinative value, preserved in lake sediments which, whatever may have been their original areal relations, are 92 THE GEOLOGY AND OBE DEPOSITS OF GOLDFIELD, NEVADA. now scattered and isolated deposits. Under these circumstances the physical history of the region and the lithological character of the various eruptive rocks assume an importance not accorded them where more trustworthy means of correlation are available. That great physical events, such as the post-Jurassic deformation and erosion, have far-reaching effects and may legitimately be used as datum planes in correlation is of course true; but without any satis- factory paleontological evidence it is not always possible for the observer to be sure that any event which has left a locally conspicuous record is also the mark of a geologic revolution regional in its extent. In the case of correlation by lithology the possibility of error is much greater, since carefully studied districts in Nevada reveal not only the prevailing complexity of the volcanic sequences, lavas of similar character being in some localities several times recurrent, but also the very small areal extent of many of the eruptions. In a comparison of the Tertiary portions of the various local geologic columns in south- western Nevada two horizontal datum zones of wide regional extent are preeminently con- spicuous. One is the unconformity between the Tertiary rocks and the rocks worn down by the post-Jurassic erosion interval. The other is the thick accumulation of lacustral sediments, known in different parts of the region as the Truckee group," the Esmeralda formation,6 Siebert tuff,c and Siebert lake beds.d The first datum is of so definite a character that it may be regarded chronologically as a horizontal plane. The second is less definite and, as will later appear, there is some question whether the base of these lacustrine sediments is not chronologically as well as physically a very irregular boundary, here sagging deep down into the earliest Tertiary and there rising into the latest part of that geologic period. However that may be, without further anticipation of later discussion, it is possible in the meantime to make use of the lacustrine epoch, corresponding more or less closely with King's Pahute Lake, as a datum plane in pre- liminary correlation on physical and lithologic grounds. To the details of such correlation we may now pass. PRELACUSTRINE ROCKS. The Vindicator rhyolite, the oldest of the volcanic rocks at Goldfield, is perhaps the equiva- lent of a rhyolite described by Ball* as forming the main mass of the Stonewall Range, 18 miles southeast of Goldfield, and regarded by him as representing the earliest Eocene eruption. This relation, however, does not necessarily imply that the rhyolite of the two localities ever formed a single continuous flow. According to J. E. Spurr/ rhyolite of corresponding age also occurs in the Silver Peak district, in the Panamint Range, in the Randsburg district, and near Daggett in the Mohave Desert. The latite of Goldfield appears to correspond in age and geologic position to rocks embraced under "monzonite and biotite andesite" in the correlation table of Ball,^ here reproduced (p. 96). This would make it equivalent in time of eruption and magmatic origin to the monzonite por- phyry of the Kawich Range h (50 miles (80 kilometers) east-southeast of Goldfield) and to the hornblende-biotite latite of the intervening Cactus Range. Ball's * description of the latter rock indicates a very close resemblance to the latite of Goldfield, not only in original character but in mode of alteration. n King, Clarence, U. S. Geol. Expl. 40th Par., vol. 1, 1878, p. 412. b Turner, II. W., Twenty-first Ann. Rept. U. S. Geol. Survey, pt. 2, 1900, p. 197. c Spurr, J. E., Geology of the Tonopah mining district, Nevada: Prof. Paper V. R. Geol. Survey No. 42, 1905, p. 51. rf Ball, S. H., A geologic reconnaissance in southwestern Nevada and eastern California: Bull. U. S. Geol. Survey No. 308, 1907. « Bull. U. S. Geol. Survey No. 308, 1907, pp. 32-33, 85. / Succession and relation of lavas in the Great Basin region: Jour. Geology, vol. 8, 1900, p. 633. 9 Op. cit., p. 33. h Ball, B. n., op. cit., p. 104 i Op. cit., p. 91. CORRELATION. 93 Correlations of Tertiary formations in various ranges of southwestern Nevada. <* [Symbol X shows presence of formation.] Range. Eocene or earlier. "HS Timber Mountain Mount Jackson Bare Mountain Monitor Hills Specter Range Yucca Mountain Reveille Range Lone Mountain foothills Panamint Range Hills between Cactusand Kawich J ranges I . . . Death Valley Goldficld Ili'lls Belted Range Pahute Mesa Kawich Range X Amargosa Range ■ X Bullfrog Hills X Cactus Range X Southern Klondike Hills : £ Stonewall Mountain I X | X = Gold Mountain Ridge ' -g Silver Peak Range ~ SlateRidge •§ Tolicha Peak g Shoshone and Skull mountains X IK --* r. Si SOU X , W Be ,2 ti Miocene. 73 +-> x x" 8S = a § ft O v- 3 ® 3ic' s ° c 5 >-c e>,c — X > c X X X x X X X X < ■a £ 3 « » = •a c (3 ■a c a:. 5 Si3 o a> — ,a T3 fc. rt a; S3 IS ,a > x "x" .2 M-9 3.i Q) C3C0 S§3« ('•') X X X X cX X ■ < X X X Pliocene. Pleistocene in part. 0 B ■" bo s "8 I S > P*2 EQ a tn k. = — 03 1-1 X? CR3Ci +J-3 ■.. CJ 03 'S .2 c tt a; M o c ^ tc3. cSfXn ifl a) °+j o pq X X X X X ■ X X x" x g A >, — .i ° % 1 3 £ a) 3 X X X X x X X X > ■ X X X N- "•■ > ■• X X X ■ X X X a After S. H. Ball, Bull. U. S. (ieol. Survey No. 308, 1907, p. 33. b Probably to north. e Including shore formation. d Shore fonnation only. The next physical event recognized by Ball (see his table above) is an erosion interval marked by unconformity which he has observed in the Kawich, Cactus, and Amargosa ranges, in the Shoshone Mountains, and in the Bullfrog Hills. This unconformity, which he considers as corresponding with the end of the Eocene or the beginning of the Miocene, is not distinctly shown at Goldfield. The Sandstorm and Morena rhyolites were apparently erupted contemporaneously with what Ball has called "early Miocene rhyolite," a formation which according to his reconnais- sance map is of widespread importance in southwestern Nevada, making up the greater part of the Cactus, Kawich, Reveille, and Belted ranges and of the Bullfrog Hills. It is also the principal rock of Timber and Yucca mountains east of the Bullfrog district. The rhyolite of some of these areas, according to Ball, is associated with contemporaneous flows of dacite and latite, a relation not exhibited at Goldfield. As rhyolites were erupted at least half a dozen times during the Tertiary in this general region it is evident that correlation of these lavas from one range to another is, in our present stage of knowledge, tentative. The difficulty expe- rienced in distinguishing by detailed work the 4 or 5 different rhyolites occurring in the Goldfield district shows that more than rapid reconnaissance will be necessary before it can be definitely asserted, for example, that the Sandstorm rhyolite is in part the equivalent of the much thicker series of rhyolites in the Bullfrog Hills. The Milltown andesite of Goldfield is grouped by Ball with the dacite, and this group is correlated by him with rocks in the Belted, Kawich, Cactus, and Silver Peak ranges. The oldest Tertiary rocks described by J. E. Spurr a in the Tonopah district, 30 miles (48 kilometers) north of Goldfield, are andesites which he designates "earlier" or " hornblende-biotite " andesite, and "later" or " biotite-augite " andesite. An interval of erosion is described between the two. These andesites may be of about the same age as the andesite at Goldfield, although o Geology of the Tonopah mining distri t: Prof. Paper U. S. Geol. Survey No. 42, 190o. 94 THE GEOLOGY AND OKE DEPOSITS OF GOLDFIELD, NEVADA. the unconformity has not been recognized in the hitter district and the rocks of the two areas are not petrographically identical. In the Tonopah district also Spurr describes a series of dacites and rhyolites which corre- spond to a long period of eruptive activity and for the most part are older than, or are overlain by, the Siebert lake beds. He considers, however, that the dacitic eruptions and the lake beds belong to the same general period (Miocene), and shows that the lake beds after they had been folded, eroded, and covered by basalt were intruded by dacite. Thus there is a suggestion that the dacite of Tonopah may in part be equivalent to the dacite of Goldfield. Closer examination, however, renders this correlation questionable. In the first place there is no evidence at Goldfield that dacitic eruptions continued into the lacustrine epoch, although it can not be positively asserted that they did not do so. In the second place the dacites of the two districts are distinctly different rocks; that of Goldfield is a quartz-bearing andesite or true dacite, while those at Tonopah, as Spurr a himself states, are not, strictly speaking, dacites at all, but are siliceous quartz latites and rhyolites. This difference is brought out in the following table of chemical analyses: Chemical analyses of Goldfield and Tonopah dacites. Goldfield. Tonopah. 1. 2. 3. 4. 5. 6. Si02. 59.95 15. 77 3.34 2.34 2.73 5. 84 3.07 2.52 .95 2.00 .82 .02 .26 59. 99 16.14 4.42 .13 1.51 4.17 3.04 2.82 3.35 4.06 .64 61.25 15.92 3.75 1.17 2.2S 5.39 3.19 3.23 1.08 1 . SN .71 71.71 14.00 1.06 .51 .43 2.25 3.21 4.41 .44 1.38 .28 73.00 Al .( i Feo03 FeO MgO CaO . 1.55 3.50 4.71 1.16 Na20 4.20 K20 4.50 H20 below 110° C . H20 above 110° C Ti02 Zr02 p2o^ .24 .22 .07 Cr2Oj MnO .09 .11 .13 .05 .08 BaO SrO 99.94 100.56 100.15 99.75 1. Dacite (G. 97), one-half mile (2.4 kilometers) northeast of Columbia Mountain, Goldfield district. George Steiger, analyst. 2. Dacite vitrophyre (G. 158), 1 mile (1.6 kilometers) southwest of Blackcap Mountain, Goldfield district. George Steiger, analyst. 3. Dacite (G. 83), Diamond Peak, Goldfield district. George Steiger, analyst. 4. "Dacite," Brougher Mountain, Tonopah. George Steiger, analyst. (Spurr, op. cit., p. 57.) 5. "Dacite," Butler Mountain, Tonopah. E. T. Allen, analyst. (Spurr, op. cit., p. 57.) (i. "Dacite," Golden Mountain, Tonopah. E. T. Allen, analyst. (Spurr, op. cit., p. 58.) Comparison of the three analyses of rocks from each district shows conclusively that the so-called dacites of Tonopah are quite distinct from the dacite of Goldfield. The Tonopah dacites, according to Spurr,6 all fall into the subrang toscanose of the quantitative system. H. S. Washington's r tables include in this subrang 122 entries, of which 40 were originally described as granites, 31 as rhyolite, liparite, obsidian, etc., and 9 as quartz porphyry. Among the remaining 42 entries are trachyte, akerite, quartz monzonite, toscanitc, latite, etc., but only one dacite. The positions of the Goldfield dacite and dacite vitrophyre in the quantitative system have been given on pages 57 and 63. It appears from the foregoing comparison that the dacite of Goldfield is not lithologically identical with the so-called dacites of Tonopah and that some of the latter are younger than the former. It is probable that some of the later of these Tonopah eruptions correspond in time with the thin rhyolitic flows known to be intercalated between the beds of the Siebert formation at Goldfield. On the other hand, some of the earlier "dacites" and rhyolites (i. e., Heller dacite, Fraction dacite breccia, and Tonopah rhyolite-daeite) at Tonopah, which Spurr d shows a Geology of the Tonopah mining district: Prof. Paper l". S. Geo]. Survey Xo. 42. I90S, pp. 366, 9. b Op. cit., p. 60. (Chemical analyses of Igneous rocks: Prof. Paper U. 8. Geol. Survey No. 14. 1903, pp. 159-173. <'Op. cit., p. "!. CORRELATION. 95 to have been eroded before the deposition of the lake beds, although lithologically different, may be approximately equivalent in age to the dacite vitrophyre of Goldiield. The merely tentative correlation thus far attempted in this chapter has had to do with volcanic rocks lying between the post-Jurassic erosion surface and the earliest Tertiary lacus- tral sediments. The extent to which these sediments, as now exposed in various areas, possess common lithologic, stratigraphic, and tectonic characteristics next demands attention, and the general discussion may be fitly introduced by a brief summary of the more important descrip- tive literature on the older Tertiary lake deposits of western Nevada. LACUSTRINE SEDIMENTS. King," who applied the name Pahute Lake to the great body of water which he supposed to have covered western Nevada in Miocene time, outlines the distribution of the lacustral sedi- ments (Truckee group6) as follows: The rocks of the group are limited on the east, within the boundaries of our exploration, by the one hundred and seventeenth meridian, and on the west by the abrupt wall of the Sierra Nevada. Northward they extend through Oregon and pass into Washington Territory, having their greatest development on Crooked River, the John Day, and the Malheur. South of our work they are well known in the valley of Walker River, but beyond that southward I am not aware of their having been observed. King's description of a characteristic section of the Truckee group at a locality west of Carson sink, near the Southern Pacific Railroad, is as follows: c The most important and characteristic development of this series within our limits is at the Kawsoh Moun- tains and along the southern extremity of Montezuma Range. The northern and eastern portion of the Kawsoh Mountains and the valley which lies north of them, separating their broken detached group of hills from the end of Montezuma Range, together offer a section of about 2,300 feet of Miocene beds, noting from the top as follows: 1. The upper 1,200 feet consist entirely of drab, mauve, gray, pale-buff, and white stratified trachytic tuff, inter- mixed with more or less detrital material. The beds are characterized by rapid changes of color and texture, are of very variable coarseness, and have a prevailing amount of glassy fragments, as if an enormous amount of the material were the glassy scoria and rapilli of violent and long-continued trachytic eruption. At intervals are beds of pure gray sand with a few seams of slightly marly clay. The microscope shows that this entire series is made up of angular and suban- gular fragments, many of them excessively small. There are some singular chalcedonic strata, 1 to 2 feet thick, of which the lower stratum plane is exceedingly rough, resting upon the trachytic tuff and including a great many minute fragments of the volcanic material, the upper surfaces being rudely botryoidal, the protuberances reaching the size of an egg. Toward the lower edge of this great series of trachytic tuffs, the upper limits of which are nowhere seen, the proportion of true detrital material — quartz and feldspar sand — becomes rapidly greater until the tuff is underlaid by — 2. Coarse, sandy grits, gray and yellow fragments, partially rounded, partially angular, with a Feet. slight proportion of calcific material 250 3. Saccharoidal limestone, rich in fresh-water mollusks 60 4. Marly grits, yellow and drab, rather coarse 40 5. Fine-grained, friable, buff and gray sandstone, having a peculiarly sharp, gritty feel 70 6. Variable gray sandstones 100 7. A marly grit 50 or 60 8. White and yellow infusorial silica 200 to 250 9. Palagonite tuff, base never seen, 250 feet being maximum exposure. No lower members than the bed of palagonite tuff are observed in the Kawsoh Mountains, or in the southern end of the Montezuma; but in Warm Spring Valley, a small depression in the basaltic hills a few miles north of Hawkes's station, on Carson River, the palagonites, there remarkably well developed, are seen to be underlain by a light siliceous clayey bed made up of fine silt and comminuted infusoria. It is always far less pure than the white infusorial beds above the palagonites. Here, as everywhere, the series has an inclined position, dipping 15° to 20°. . It is now well known that the rocks called trachyte in the Fortieth Parallel reports are mostly andesites, and consequently that the trachytic tuff referred to in the foregoing descriptions should be translated andesitic tuff. It may fairly be questioned, moreover, whether this a. Geol. Expl. 40th Par., vol. 1, 187S, p. 413. 6 The name "Truckee group" is not a very happy choice. Although the lake beds at Verdi, on Truckee River near the California line, arc mapped as the Truckee group in the Fortieth Parallel Atlas, the typical and best exposures, according to King, are all to the east and south of the stream from which the formation presumably takes its name. cOp. Pit., pp. 415-410. Reference to Arnold Hague's description of the Kawsoh Mountains (L". S. Geol. Expl. 10th Par., vol. 2, pp. 7(i(j-77i) shows that King combined and generalized the actual sections there observed. 96 THE GEOLOGY AND ORE DEPOSITS OP GOLDFIELD, NEVADA change entirely expresses the facts and whether a reexamination of the section would not show a large proportion of rhyolitic material in the so-called trachytic tuff. To the northeast of the section just described, in the foothills of the West Humboldt Range, the sediments, according to King,0 are less characteristically volcanic and consist largely of coarse sands and gravels. Louderback b describes these as consisting of "slightly consolidated granitic sands, diatoma- ceous earth, et cetera," dipping at about 35° and overlain by basalt. King noted0 that the Truckee beds are everywhere upturned from 10° to 25° and, where associated with basalt, are cut through and overflowed by that rock. The lake beds west of Reno and under the town of Verdi, mapped as Truckee Miocene in the Fortieth Parallel Atlas, are described by Arnold Hague as follows :d That portion of the Truckee Valley lying directly west of the Virginia Range is a broad open basin covered by a thick deposit of Quaternary sands and gravels obscuring all the Tertiary strata below; these appear, however, farther up the valley, just above the town of Reno, and extend thence westward to the California boundary. These Tertiary beds line the valley on both sides of the river, and form a distinct deposit quite unlike those described from the lower Truckee Valley. They lie inclined at angles varying from 10° to 15°, in general dipping to the southward away from Peavine Mountain, but considerably disturbed by local outbursts of volcanic rocks. Inasmuch as the beds are so highly inclined, and are older than many of the intrusive rocks of the region, they have been referred to the Miocene age, although they differ somewhat in lithological character from the Miocene strata of the Kawsoh Mountains and Montezuma Range, having much less volcanic material in their composition. They consist mainly of sandstones, with interstratified beds of friable sands, clays, and thin shales of prevailing light colors. So far as known, no animal remains have as yet been found in these beds, although stems, leaves, and partially carbonized vegetable matter are abundant in certain layers of shale. Perhaps the most characteristic feature of the basin, and one that suggests the Green River beds of the Elko region, is the presence of a number of seams of impure coal and carbonaceous shales. Outcrops of coal occur on both sides of the river north of the town of Verdi, dipping to the southward 10°. Another coal seam has been opened a long time on Dog Creek, a short distance north of Crystal Peak, but, so far as known, none of the deposits have as yet proved of any economical importance. No accurate measurements of the thickness of these Tertiary strata have been made, but there can not be less than 500 or 600 feet of conformable beds. West of the locality just noted, in Truckee Valley, California, Lindgren* has described Neocene lake beds consisting of yellowish sands and clays, the latter predominating, with brilliantly white beds, probably volcanic ash, containing diatoms. There are also several layers of coarse tuff and some seams of impure lignite. These beds, which show dips up to 10°, are capped in places with basalt, and are }^ounger than the main andesitic eruptions of the Sierra Nevada. Lindgren suggests the equivalence of these deposits with those at Verdi. D. T. Smith -^ has briefly described a series of Tertiary sediments about 1,200 feet (366 meters) thick near Yerington in' the valley of Walker River about 15 miles (24 kilometers) south of Wabuska, or 45 miles (72 kilometers) south of the Kawich Mountains, which apparently have considerable resemblance to the Truckee group and are inclined at angles up to 40°. These beds have yielded mammalian remains which W. J. Sinclair states are probably late Miocene. or Pliocene and correspond to the faunas of the Mascall and Rattlesnake formations of Oregon. In Gabbs Valley, about 60 miles (96.5 kilometers) southwest of King's type locality for the Truckee group, Spurr has noted lacustrine beds, which he describes as follows: s Near the center of the valley, just east of the low mountain spur which crosses it, and on the Reese River road, there are low ridges of gray, stratified marl containing leaf remains, alternating with gravels and more solid conglom- erates. Some of the conglomerate contains comparatively abundant silicified wood. The conglomerate, when exam- ined microscopically, proves to be volcanic. The pebbles are made up in part at least of spherulitic glass. Some pebbles contain phenocrysts of feldspar, of species indicating that the lava is andesitic, in a glassy matrix containing broken feldspar and biotite. Some of the shaly beds associated with the conglomerate are feldspathic tuff, made up of fine fibrous material, with larger broken fragments of feldspar and some shreds of biotite. These beds strike north and eouth and dip about 8° E. a. Op. cit., p. 414. See also Hague, Arnold, U. S. Geol Expl. 40th Par., vol. 2, 1877, p. 733. 6 Basin Range structure of the Humboldt region. Bull. Geol. Soc. America, vol. 15, 1904, p. 301- c Op. cit., p. 413. dUS. Geol. Expl. 40th Par., vol. 2, 1877, pp 849-850. e Truckee folio (No. 39), Geol. Atlas U. S., U. S. Geol. Survey, 1897. / Geology of the upper region of the main Walker River, Nevada: Bull. Dept. Geology Univ. California, vol. 4. 1905, pp. 10, 13. g Descriptive geology of Nevada south of the 40th parallel: Bull. U. S. Geol. Survey No. 208, 2d ed., 1905, p 107. CORKELATION. 97 Spurr correlates these sediments provisionally with King's Truckee group. A few miles south of Gabbs Valley, in the Candelaria Mountains near Sodaville, Spurr a notes — a comparatively small area of brown, yellow, sometimes purplish, limy and sandy shales, argillaceous fine sand- stones, and thin-bedded brown and yellow aphanitic limestones. This series strikes N. 65° E. and dips 65° N\V. It is probably identical with the rocks of the Esmeralda formation a few miles to the south, in the southern end of the Monte Cristo Mountains. The Esmeralda formation, described and named by H. W. Turner,6 is well displayed in the Silver Peak district on the slopes of the Silver Peak and Montezuma ranges, about 15 miles (24 kilometers) west of Tonopah and Goldfield. According to Turner,0 "The beds are composed of sandstones, shales, and lacustral marls, with local developments of breccia and conglomerate on a large scale." He further describes the formation as containing intercalated volcanic flows and, near the base, some coal. The beds, according to this observer, have the enormous aggregate thickness of 14,800 feet (4,511 meters), are folded, and are capped un- conformably by basalt. Turner suggests their correlation with the Truckee group of King. Spurr refers to the Esmeralda formation as follows :d These Tertiary deposits flank the edges of the mountains and underlie, in part at least, the Pleistocene veneer of the valleys. On account of folding and faulting since their deposition they arch upward along the sides of the moun- tains, although according to Mr. Turner they have not been found within 2,500 feet of the highest elevations. They consist of soft shales, sandstones, marls, tuffs, volcanic breccias, etc., with interbedded layers of andesitic and rhyolitic lava. The thickness of the whole accumulation is very likely several thousand feet. This mass has not yet been satisfactorily differentiated into separate members, but it undoubtedly contains materials deposited under widely varying conditions. Some of the beds are lake sediments; some appear to have been deposited in running water and were probably distributed by stream action. Others bear the marks of dry, subaerial origin. Also there is probably a great range in the period of deposition, as will be presently shown from a consideration of the fossil evidence. It is probable that practically the whole Tertiary, from the Eocene through the Pliocene, is represented. In short, it is probable that the beds are the record of the whole period of Tertiary sedimentation, beginning with the period when the Nevada land mass ceased to have free drainage to the ocean, at the close of the Cretaceous, through the whole of the climatically changing but in general arid Tertiary period, when the material eroded from the mountains was accumulated in the valleys, in lakes, or in subaerial sheets, down through the Pliocene. Both the early and more recent Pleistocene accumulations of the region are of very much the same nature as many of these Tertiary beds, and probably form a direct continuation of them; but in the Pleistocene material the proportion of lake beds does not appear to be nearly so large as in the Tertiary formations. Eight miles (13 kilometers) north of Tonopah, near Ray, Spurr found "folded gravels, tuffs, lavas, and some white, thin limestones." He states that similar beds are found at several places between Ray and Sodaville and remarks that they are (were? — F. L. R.) probably continuous with a part of the. Tertiary deposits of the Silver Peak and Monte Cristo moun- tains— that is, with the Esmeralda formation. The same writer characterizes the Siebert tuff at Tonopah rather briefly as follows: e The white stratified tuffs form a conspicuous feature of the geology near Tonopah. As a rule they are beautifully and uniformly bedded, and composed of well-assorted material. Where beds of conglomerate occur the pebbles are perfectly rounded. Since these sediments do not vary in character for thicknesses of several hundred feet, it is plain that they were laid down in a large body of standing water that lasted for a considerable length of time. That this body was a lake is indicated by numerous general considerations derived from the study of the geology of the surrounding region and by the presence of numerous fresh-water infusoria in some of the strata. In contrast to the general regular stratification, cross-bedded strata may occasionally be found, and at one place markings like those made by rills on a sandy shore were noted. These are probably shore and delta features. The Siebert tuff is unconformably overlain by basalt on Siebert Mountain, and both rocks are cut by a late intrusion of "dacite." « Descriptive geology of Nevada south of the 40tk parallel: Bull. U. S. Geol. Survey No. 208, 2d ed., 1905, p. 114. b The Esmeralda formation, a fresh-water lake deposit: Twenty-first Annual Report U. S. Geol. Survey, pt 2, 1900, pp. 187-208; also Am. Geologist, vol. 25, 1900, p. 168. «Op.eit.,p. 198. d Ore deposits of the Silver Peak quadrangle, Nevada: Prof. Paper TJ S. Geol. Survey No. 55, 1900, p. 19 ' Geology of the Tonopah mining district, Nevada: Prof. Paper TJ. S. Geol. Survey No. 42, 1905, p. 51. 79145— No. 66—09 7 98 THE GEOLOGY AND ORE DEPOSITS OF GOLDFIELD, NEVADA. There can be no reasonable doubt that the Siebert tuff of Tonopah and the Siebert forma- tion of Goldfield were once continuous deposits laid down in one lake. The two districts are less than 30 miles (48 kilometers) apart, the deposits are thick and lithologically similar, and the reconnaissance of Balla has shown that the formation is well represented in the Klondike Hills, about halfway between Goldfield and Tonopah. He found the Siebert beds making up a large part of Montezuma Peak, 7 miles (11 kilometers) west of Goldfield, where the faulted and folded lake beds attain an altitude of 8,426 feet (2,568 meters) on the summit of the peak. He also traced the formation westward to longitude 117° 30', where his area marches with the Silver Peak quadrangle, in which the Esmeralda formation was described in 1900 by Turner. Veiy curiously, Ball makes no reference to this formation, nor does he point out what would appear to be a conclusion from his own work, namely, that the Siebert Lake beds were laid down with at least a part of the Esmeralda formation in a common basin.6 Ball's description is as follows: c Prior to the deposition of the Siebert Lake beds the Cambrian rocks had a rugged topography. These beds, 17 miles north of Lida, are coarsely conglomeratic, and inliers of limestone protrude through them, and outliers of lake beds occur on the Cambrian rocks. The lake beds cover a considerable area on the western border of the region under consideration, a somewhat smaller area near Montezuma Peak, and a small area 5 miles south of Alkali Spring. The northern boundary of the largest area is approximately correct as mapped. The southern boundary is less accurately drawn and some Tertiary igneous rocks may lie between the Cambrian rocks and the lake beds. These beds, which are composed largely of rhyolitic material, consist of typically incoherent, unevenly granular, well-bedded sandstones. When unstained by iron, they are white in color, but brilliant reds and yellows are char- acteristic of many areas. Fine-grained beds alternate with conglomeratic layers containing pebbles of Cambrian rocks, quartz-monzonite porphyry, diorite porphyry, rhyolite, and igneous rocks of andesitic and basaltic affinities. The pebbles are well rounded or semiangular. Microscopic examination of several slides shows the presence of quartz and orthoclase crystals in a pyroclastic matrix. Locally the Siebert Lake beds have been indurated by silieification along joints and in irregular bodies. Quartz, chalcedony, and opal fill cavities. The silicified portions weather into wall-like masses along joints and into grotesque topographic forms where silieification has been less regular. Rhyolitic and dacitic flows are interbedded throughout the sediments, although they increase toward the bottom of the formation, and dacite appears to underlie it. The lake beds at Montezuma Peak are about 1,100 feet thick. On the western border of the area mapped they are probably 200 or 300 feet thicker. The formation was for the most part deposited in an inland lake, although some portions were possibly laid down subaerially by explosive volcanic action. Mr. R. H. Chapman found a piece of silicified wood at a point 4 miles west of Montezuma Peak. Mr. F. H. Knowlton, who kindly examined it, states that it is wood of a deciduous tree not older than the Tertiary. These sandstones are correlated with the Siebert Lake beds of Tonopah, described by Spurr. South of the Goldfield district Ball's map shows areas of lake sediments which he corre- lates with the Siebert formation extending into Death Valley in latitude 36° 30'. Ball refers to the lake beds on the west slope of the Funeral Mountains as follows :d The rather large mass of later rhyolite and biotite latite to the southeast of Staininger's ranch has between its flows layers of white or light-colored iucoherent tuffaceous sandstone, which readily breaks down into sand. The section at this point is as follows: Section southeast of Staininger' s ranch. Feet. Lava, largely biotite latite. 375 Rhyolite flows and some tuffaceous sandstone 100 Tuffaceous sandstone and thin rhyolite flows 375 Rhyolite flows 75 Tuffaceous sandstone • 225 Between the lava and the sediments are minor erosional gaps, but these are probably current erosional unconform- ities, and the series is approximately all of one age. Bedding planes from 2 inches to 20 feet apart are well developed at some places. a Geology of the Tonopah mining district, Nevada: Prof. Paper U. S. Geol. Survey, No. 42, 1905, p. 78, PI. I. t A comparison of Ball's map (Bull. U. S. Geol. Survey No. 308, 1907, PI. I) with the map of the adjoining region accompanying Spurr's report (Prof. Paper U. S. Geol. Survey No. 5.5, 1900, PI. I), and purporting to be based on a manuscript map by II. W. Turner, shows that the area of Siebert Lake beds, which Ball maps for 0 miles along his western boundary, apparently changes abruptly to "Tertiary lavas" on Spurr ssidc of the line. This discrepancy, however it may in future be explained, is not likely to affect the general conclusion that the Siebert formation and at least a part of the Esmeralda formation were once areally continuous across the region now occupied by the Montezuma Range.— F. L. K. c Bull. US (icol Survey No. 308, pp. 57-58. tfOp. cit., pp. 105-160. COKRELATION. 99 Locally the tuffaceous sandstone lies unconformably upon folded Pogonip limestone. It is closely similar to that of the Mount Jackson hills and, like it, is overlain by siliceous lavas. This formation is, without much doubt, the Siebert Lake beds. A number of small areas of conglomerate occur on the eastern slope of the Amargosa Range, east of boundary post No. 94, southeast of Daylight Spring, and north of Willow Spring. The rocks, varying from loosely to rather strongly consolidated material, consist of conglomerates and arkoses with a little shale. They range in color from green to red, yellow, or brown. Bedding planes, which are from 1 inch to 2 feet apart, are well developed. The pebbles in the conglomerate, which are very well rounded and many of them highly polished, reach a maximum diameter of 4 inches. They are derived principally from the Paleozoic rocks near by, with here and there a pebble of fine to medium grained granite, and in the area east of boundary post No. 94 some of earlier rhyolite. These rocks appear to be the shore deposits of a lake in which waves swept with considerable force. Material was transported from considerable distances, since granite does not now outcrop in the vicinity. Since the conglomerate contains pebbles of rhyolite and none of basalt, the deposits are younger than the rhyolite (early Miocene) and older than the basalt (Pliocene-Pleistocene), and in consequence of middle or late Tertiary age, presumably Miocene. They are approximately contemporaneous with the lake in which the Siebert Lake beds were deposited, and it is believed that they are shore deposits of that lake. In that part of California lying east of the Sierra Nevada and north of the San Gabriel and San Bernardino ranges Tertiary lacustral deposits have been described by G. K. Gilbert," H. W. Fairbanks,6 M. R. Campbell,0 and J. E. Spurr.d Spurr, writing of the Death Valley region just south of the area examined by Ball, describes the early Tertiary lake sediments as follows : e In the eastern part of the range, where the road crosses from the Amargosa Valley into Furnace Creek, there is found a great amount of conglomerate, forming high hills. These conglomerates are very coarse and contain rounded pebbles and bowlders of all sizes, made up of reddish and white quartzite and black and gray limestones bearing the badly preserved Paleozoic fossils above mentioned. The conglomerate is as hard and firm as the rocks from which it is derived. It is water laid and well stratified, and evidently a shore formation. The whole thickness exposed is estimated at 4,000 feet. It is sharply folded, together with the limestones from which it is derived, but it abuts abruptly against these limestones on the west. Besides these rocks there occur, as parts of the same series, semiconsolidated gravels, with clays partially hardened to slaty shales, limy clays partially consolidated to argillaceous secondary limestones, and sands partially hardened to cherty and limy sandstones, all interbedded. All these, including the conglomerate and the limestone tufa, have a general light-yellow, often greenish, color, characteristic of the series. This sedimentary series makes up the greater portion of the I^uneral Range. Along Furnace Creek Valley and on both sides of it the mountains consist chiefly of yellow-green strata capped by basalt. The lava seems to occur inter- bedded with the sedimentaries, as well as overlying them. The series is here consolidated into a hard clay rock, with occasional thin sandstone, and the general yellow-green color is changed in places to reddish, yellowish, and pinkish. The rocks are often gypsiferous and contain abundant grass remains, which are, however, indeterminable. From the yellow-green Tertiary series in the hills just east of the mouth of Furnace Creek there has been taken much borax, which occurs as borate of lime in beds in the strata. Near the summit of the pass, just east of Furnace Creek, there come in above the yellow-green Tertiary series softer, dark-brown, honeycombed conglomerates, recalling the similar rocks of Meadow Valley Canyon. Thin sheets of basalt are interbedded with the conglomerates, but the great sheets lie on top. Patches of this same upper conglomerate series were elsewhere observed, and at one place its contact with the underlying yellow-green series appeared slightly dis- cordant. The conglomerate contains pebbles and bowlders which are chiefly of lava and must have been derived from the sheets of basalt which were periodically poured out during the deposition of the beds. A rough estimate of the thickness of this whole series of slightly consolidated beds and volcanics puts it at not less than 4,000 feet, and the nature of the sediments shows that they must have been deposited in standing water. The presence in some of the beds of gypsum, borax, and calcareous tufa shows that at some periods the waters in which the sediments were deposited were evaporated. They were, therefore, those of an inclosed lake, which was probably of great dimensions. It is likely that a large portion of the beds were deposited in fresh water at a period different from that in which the chemical precipitates were laid down. Northward from Furnace Creek, at Silver Peak, are found beds of the Esmeralda formation, which are entirely similar in nearly every respect to those at Furnace Creek. Moreover, the fossils found in the Esmeralda beds indicate a nearly similar age to that indicated by fossils found in the Tertiary strata of the Mohave Desert, just west of Cajon Pass. Spurr considers it probable that the beds at Furnace Creek represent nearly the whole of the Tertiary period. They are capped by basalt, which he considers may have been poured out in a Rept. Geog. and Geol. Surveys W. 100th mer., vol. 3, 1875, pp. 142-143. b Geology of eastern California: Am. Geologist, vol. 17, 1896, pp. 67-69. c Reconnaissance of the borax deposits of Death Valley and Mohave Desert: Bull. I". S. Geol. Survey No. 200, 1902. d Descriptive geology of Nevada south of the fortieth parallel and adjacent portions of California: Bull. U. S. Geol. Survey No. 208, Zd ed., 1905. e Op. cit., pp. 189-191. 100 THE GEOLOGY AND ORE DEPOSITS OF GOLDFIELD, NEVADA. Quaternary time. In the same report are described similar lacustral deposits in the Panamint and other ranges of this region. The general conclusions which may be drawn from the observations brought together in the foregoing pages are as follows : There is in western Nevada, extending from the fortieth parallel down to about the thirty- fifth parallel, a chain of remnants of Tertiary lacustral deposits. These deposits are of great volume, estimates of total thickness in the various places where the beds are well represented ranging from a minimum of at least 600 feet (183 meters) at Tonopah a to 14,800 feet (4,511 meters) at Silver Peak.6 The materials vary from place to place, but are preponderantly volcanic. They include true tuffs, largely rhyolitic, and detrital rocks of a wide range of coarse- ness derived from all the prelacustrine rocks and probably also from volcanic masses piled up and eroded during the lake period. Diatomaceous beds appear to be rather characteristic of the deposits north of the Death Valley region, while in and south of Death Valley descriptions indi- cate a greater abundance of clays with associated beds containing gypsum and borax. Lignitif- erous beds, apparently in all cases in the basal part of the deposits, occur from Truckee River southward to the Mohave Desert. The beds are everywhere folded and faulted and in many places sheets of basalt have flowed over their eroded edges. It is clear that since the period of lacustrine deposition the region has undergone such deformation and erosion as to entirely remodel the topography; lake beds, for example, now forming the summit of Montezuma Peak, west of Goldfield. Two opposed views have been held regarding these Tertiaiy lacustrine deposits. Clarence King c regarded those with which he was familiar near the fortieth parallel as having been laid down in a single great Miocene lake which he called Pahute Lake, giving the name Truckee group, as we have seen, to the sediments. He believed that this lake stretched northward into the John Day basin in Oregon, and suggested that it extended also into the Mohave region of California. Most recent writers on the earlier Tertiary lacustrine deposits of western Nevada appear to have accepted King's conclusion that they were for the most part laid down in a single great lake. M. R. Campbell, however, writes as follows: d From the observations noted above and from descriptions of other geologists, it is apparent that lake sediments occur throughout a wide extent of territory in the Great Basin region. Some writers have supposed that the various outcrops are parts of one extensive sheet of sediment which was deposited in a widespread but shallow lake, and conse- quently that they are all of the same age. The data gathered during the present reconnaissance show that such is not the case. From the character and arrangement of the material composing these beds, it is apparent that most of the lakes occupied valleys, the bounding walls of which may be seen to-day with the coarse detrital material of the lake beds at their feet. As previously men- tioned, the lakes undoubtedly existed at different geologic epochs, and from data now at hand it seems probable that lake-forming conditions existed practically throughout the Tertiary period (Eocene, Miocene, and Pliocene); but sedimentation was interrupted at intervals by violent crustal movements that tilted the earlier sediments and materially changed the topography of the country. The truth of the matter is that it is impossible to demonstrate at the present time that a single lake covered the greater part of western Nevada in early or middle Tertiary time. Deformation and erosion have destroyed, beyond possibility of conclusive restoration, such continuity of sediments as may once have existed. Nevertheless the distribution, thickness, and character of the remnants are such as to lend strong support to the view that the greater number of them were deposited in one great water body corresponding to King's Pahute Lake. It is probable that there were other smaller lakes also, contemporaneous with Pahute Lake. More- over, submergence and sedimentation may have been going on in certain greatly depressed parts of the lacustrine basin while erosion continued long in progress over other parts much later covered with water. Whether Pahute Lake extended, as King supposed, into Oregon is a Spurr, J. E., Geology of the Tonopah mining district: Prof. Paper V . S. Geol. Survey No. 42, 1905, p. S3. b Turner, H. W., The Esmeralda formation: Twenty-first Ann. Kept. U. S. Geol. Survey, pt. 2, 1900, p. 202. <■ U. S. Geol. Expl. 40th Par., vol. 1. 1S7S, pp. 413. -1.1 1. d Reconnaissance of the borax deposits of Death Valley and .Mohave Desert: Hull. 17. S. Geol. Survey No. 200, 1902, pp. 21-22. TERTIARY CHRONOLOGY. 101 yet unknown. Between the Goldfield-Silver Peak region and the Death Valley-Mohave Desert region there is a considerable gap in the chain of lacustral deposits. There is also a change in the character of the sediments, those of the southern region containing beds indicative of saline periods which apparently are not represented in the sediments of the northern region. This difference suggests that the older lacustrine deposits of Death Valley and the Mohave Desert were laid down in a body of water which, during part of its existence at least, was not connected with Pahute Lake. Aside from the still doubtful extension of the Truckee beds northward into Oregon it is clear that Pahute Lake was a vast sheet of water, fully comparable in size with Lake Superior. King estimated the maximum thickness of the lacustrine deposits as at least 4,000 feet (1,219 meters), and it has been shown (p. 68) that the thickness of the beds in the Goldfield region is probably in the neighborhood of 1 ,000 feet ( 305 meters) . Consequently, although deposition and submergence probably went on at the same time, there is reason to suppose that the lake was by no means generally shallow. On the other hand, the submerged topography was undoubtedly one of strong relief and the lake probably possessed a deeply indented shore line and was diversi- fied by numerous islands. TERTIARY CHRONOLOGY OF THE WESTERN PART OF THE GREAT BASIN. As has previously been seen, the initial datum plane from which the beginning of Tertiary history must be reckoned is the interval of post-Jurassic deformation and erosion. The second and much less definite or satisfactory epoch is that of Pahute Lake. Knowledge of the age of the lacustral beds that in this report are provisionally correlated with the Truckee group would be a great step toward a clear understanding of Tertiary history in western Nevada. Pahute Lake was supposed by King0 to have come into existence at the dawn of the Mio- cene. This conclusion was based mainly upon the supposed direct continuity of the Truckee group with the John Day formation in Oregon, b the geologists of the Fortieth Parallel Survey realizing clearly that the scanty fresh-water fauna in the Truckee group in Nevada was not distinctive enough to determine whether the beds are Miocene or Pliocene.6 The Infusoria col- lected by Spurr c from the Siebert beds at Tonopah are of no greater distinctive value, although he appears to have accepted without question the Miocene age of Pahute Lake. As no one has yet actually established the supposed connection of the Truckee group with the mammal- bearing Miocene beds of the John Day basin, it must be admitted that the assignment of the Truckee group to the Miocene rests upon evidence that is far from satisfactory. Spurr d and Ball6 accept the view of King, but G. D. Louderback f is inclined to regard the group as Pliocene. The opinion of the last-named author is perhaps based in part upon the work of Lindgren/ who showed that lake beds in Truckee Valley, California, which he regards as probably equiva- lent to the lake beds at Verdi, Nev., are younger than the main andesitic eruptions of the Sierra Nevada, a conclusion which is suggestive of a late Tertiary age of at least some of the beds originally mapped with the Truckee group. In the lake deposits south of Wabuska, also, D. T. Smith/' as before noted, found mammalian remains, from which W.J. Sinclair concludes that " the beds are probably late Miocene or Pliocene, corresponding to the Mascall and Rattle- snake formations of Oregon; but the material is not complete enough to determine these points with certainty." «U. S. Geol. Expl. 40th Par., vol. 1, Systematic geology, 1878, p. 091. b King, Clarence, op. cit., p. 423. cOp. cit, pp. 69-70. d Prof. Paper U. S. Geol. Survey No. 42, 1905, p. 70. e Bull. U. S. Geol. Survey No. 308, 1907, p. 33. /Basin Range structure of the Humboldt region: Bull. Geol. Soc. America, vol. 15, 1904, p. 337. g Truckee folio (No. 39), Geol. Atlas U. S., U. S. Geol. Survey, 1897. A Geology of the upper region of the main Walker River, Nevada: Bull. Dept. Geology Univ. California, vol. 4, 1904, p. 10. 102 THE GEOLOGY AND ORE DEPOSITS OF GOLDFIELD, NEVADA. On the othsr hand, in the beds near Ray, Spurr° found fresh-water shells concerning which W. H. Dall reported: According to the literature the fresh-water beds from which these fossils came have been referred by Doctor White and Meek to the Wasatch, or Bear River Laramie, Eocene, which is believed to be nearly the equivalent of the lower Eocene or Chickasawan marine Eocene (Lignitic of old authors) of our southeastern coastal plain. Dall lists only three forms and is not certain of the identity of these. Consequently the paleontological evidence can scarcely be regarded as establishing the Eocene age of the beds. The Esmeralda formation has furnished molluscan, fish, and plant remains,6 but these do not fix the age of the beds, although Turner concludes that the formation as a whole is proba- bly Miocene. Spurrc believes that the Esmeralda formation was deposited under a wide range of varying conditions and probably represents the whole of the Tertiary. In the El Paso Range, California, H. W. Fairbanks'* found fossil leaves which, according to F. II. Knowlton, are undoubtedly Tertiary and "seem to belong to the Eocene." On the whole, therefore, paleontological data for the determination of the age of the Truckee group and its probably correlative deposits are both scanty and unsatisfactory. No evidence has yet come to light which discredits King's conclusion that extensive lacustrine deposition began with the Miocene. On the other hand, the basis for this conclusion must be admitted to be none of the surest, and the possibility that lacustrine conditions began in the Eocene can not be excluded. Paleontological evidence having been found inconclusive, the bearing of physical history upon the problem of the proper time subdivision of the Tertiary rocks may next be considered. In discussing the correlation of the lavas in that part of the Great Basin adjacent to the fortieth parallel, King e stated that the propylites are probably pie-Miocene and that the horn- blende andesites are distinctly earlier than the Miocene strata (Truckee group), since these abut against eroded andesitic mountains. He concluded that the dacites also probably belong in Eocene time. On the other hand, the so-called trachytes were thought by him to belong in the Miocene, because the sediments of the supposedly Miocene Pahute Lake were thought to be largely composed of "traehytie" tuffs. For a similar reason some of the augite andesites were also placed in the Miocene. Afterward G. F. Becker' showed that the propylite was merely an altered andesite. He also suggested g that the trachytes of the Fortieth Parallel report would turn out to be mainly andesites, a result soon after fully established by Hague and Iddings.* As Spurr i has pointed out, the dacites of the earlier classification are in part rhyo- lites and in part latites. Moreover, it is clear from later work in the Great Basin that King's distinction between augite andesite and hornblende andesite is largely imaginary and certainly is not applicable as a criterion for determining the chronological succession of lavas over a wide region. Hague and Iddings-' showed that the so-called augite andesites of the Great Basin nearly all contain hypersthene, and the descriptions given in Chapter IV of this report serve to illustrate what close connection and gradations between biotitic, hornblendic, and pyroxenic andesites may obtain in a small area. Thus the broad generalization regarding the succession of volcanic rocks propounded by Von Richthofen and adopted with some modification by King has crumbled to pieces. The exceptions to so simple a sequence are too numerous to be ignored. The later attempt of Spurr1' to determine the general law of succession of the lavas of the Great Basin will be referred to in its proper place. The fact of present importance is < Geology of the Tonopah mining district: Prof. Paper U. S. Geol. Survey No. 42, 1905, p. 60. (Turner, II. W., The Esmeralda formation: Twenty-first Ann. Rept. U. S. Geol. Survey, pt. 2, 1900, pp. 203-204. Knowlton, F. H., Fossil plants of the Esmeralda formation: Idem. pp. 209-220. Lucas, F. A., Description of a new species of fossil fish from the Esmeralda formation: Idem, pp. 223-224. c Ore deposits of the Silver Peak quadrangle. Nevada: Prof. Paper U. S. Geol. Survey No. 55, 1900, p. 18. A (.eulogy of eastern California: Am. Geologist, vol. 17, 1890, p. 68. 'Op. cit., pp. 991-693. / Geology of the Comstock lode: Mon. V . 8. Geol. Survey, vol. 3, 1882, pp. 81-90. pOp, cit., p. 374. >i Volcanic rocks of the Great Basin: Am. Jour. Sci., 3d ser., vol. 27, 1884, p. 450. i Geology of the Tonopah mining district: Prof. Paper U. S. Geol. Survey No. 42, 1905, p. 59. j Loo. cit. £ Succession and relation of lavas in the Great Basin region: Jour. Geology, vol. 8. 1900. pp. 621-046. TERTIARY CHRONOLOGY. 103 that King recognized a considerable group of andesitic rocks as distinctly pre-Miocene — that is, as prelacustral — and another group of rock now known to be also andesitic, as belonging to the period of the Miocene Pahute Lake, because supposedly corresponding tuffs were deposited in that body of water. As has been shown, however, the Siebert formation at Tonopah and Goldfield is not essentially andesitic. Apparently having uppermost in his mind the fact that the supposedly Miocene trachytes of King have turned out to be mainly andesites, Spurr a makes the andesitic eruptions begin just before the opening of the Miocene. He designates the andesites at Tonopah as " earlier" or " hornblende-biotite " andesite and "later" or " biotite-augite " andesite and assigns both to the Miocene, although he describes an interval of denudation and an extensive series of "dacite-rhyolite" eruptions between the eruption of the later andesite and the formation of the Miocene lake in which the Siebert beds were deposited. In view of this interval, his state- ment b that the eruption of the hornblende-biotite-pyroxene andesites was contemporaneous with the Miocene lakes is not clear. Spurr's general summary of the geologic history at Tonopah is as follows : c The oldest of the Tertiary rocks within the area of the Tonopah map are probably early Miocene, and so far as known the volcanic manifestation began with an eruption of andesite. In this andesite were formed fracture zones, along which heated waters ascended and deposited the valuable veins of the region. Another extensive eruption of similar but slightly more basic andesite followed, and then there was probably a period of volcanic rest and of denuda- tion. Eruption was resumed by the outbreak of volcanoes, which alternately ejected siliceous dacite and poured out volcanic mud and frequently pumiceous lava. Some of the material may have been accumulated in water; most of it was probably deposited upon the land. Later, more glassy dacite of a slightly different composition ascended from below in irregular channels and poured out on the surface as thin sheets, or exploded and formed tuffs. Heated ascending waters followed the intrusive contacts of this lava and formed a group of quartz veins which contain gold and silver, but which are less important as regards strength and values than the veins formed after the eruption of the earlier andesite. As these dacite-rhyolite eruptions quieted down a lake was formed in a basin, which may have been due to a depression of the crust consequent upon the previous copious eruptions. In this lake there accumulated quietly several hundred feet of sediments, with occasional light showers of ash from volcanoes, and, in the lower portions, some thin flows of dacite lava. Then the beds were lifted and became dry land. This uplift may have been due to the accumulation of additional volcanic material beneath this portion of the crust. Streams began to cut into the lake beds, the uplift was continued, and the whole district was tilted bodily to the west at an average angle of 20°. After this there were renewed outbursts, from probably new vents, which doubtless corresponded, in part at least, to the present mountains. On Brougher and Butler mountains explosive eruptions occurred, the material being dacitic, like that immediately preceding the lake deposits. Cones of ash, cinders, and bombs were built up, and there were occasional very thin and scanty glassy flows. On Siebert Mountain there was an explosive outburst of basaltic material, followed by a thin basalt flow. Subsequently columns of liquid lava welled up and stood in the vents of the volcanoes, but did not overflow. Some of these were composed of dacite, some of rhyolite. As these columns cooled, heated waters rose along their contacts and deposited chalcedony and other minerals, and mud dikes were injected into the soft intruded rocks. The explosive outbreaks and the intrusion of these large necks must have broken the rocks into blocks and displaced the blocks, for at this time many faults were formed. On the cessation of this dacite-rhyolite period of volcanic activity there was a collapse or depression around the vents. This sinking took place largely along the fault planes, and was especially prominent around the volcanic necks, which, as they sagged, dragged down blocks of the intruded older rocks with them. Since this time, which was probably somewhere in the Pliocene, erosion has been active, stripping away the debris covering from the dacite-rhyolite necks, and leaving them as hills, and in general removing the surface layers from the hills to the desert valleys. In opposition to this view of the essential contemporaneity of the andesites and lake sediments stand not only King's recognition of andesites distinctly older than Pahute Lake, but Spurr's own work at Tonopah, in which he shows clearly that a notable interval of erosion separates the "later andesite" from the Siebert lacustrine epoch. At Goldfield there is an extensive series of lavas, including the andesites, which are cer- tainly older than the lake sediments. The reconnaissance of Ball also, as appears from the a Succession and relation of lavas in the Great Basin region: Jour. Geology, vol. 8, 1900, p. 637; Geology of the Tonopah mining district: Prof. Paper U. S. Geol. Survey No. 42, 1905, p. 69. 6 Prof. Paper U. S. Geol. Survey No. 42, 1905, p. 69. c Geology of the Tonopah mining district: Prof. Paper U. S. Geol. Survey No. 42, 1905, pp. 67-08. 104 THE GEOLOGY AND OBE DEPOSITS OF GOLDFIELD, NEVADA. table on page 93 and the columnar section on page 91, shows that in the area studied by him that part of Tertiary time antecedent to lacustrine conditions was long enough for the eruption of many kinds of lava, including the andesites, and for the development of two erosion unconformities. The situation may be summed up by saying that in the Goldfield region, and probably in other parts of southwestern Nevada, extensive eruptions of andesite took place after the extravasation of lavas which most workers in the region have tentatively assigned to the Eocene and before the formation of Pahute or Siebert Lake, which has been considered Miocene by King, Spurr, and Ball. Are these andesites to be placed in the Eocene or do they belong to the Miocene? To this question, it must be admitted, no definite answer can yet be made. We know merely that a series of effusive and intrusive rocks intervenes between a pre-Tertiary terrane and a series of lake sediments and intercalated flows of questionable Miocene age. King0 regarded the beginning of the lake as coinciding with the dawn of Miocene time. The pre- lacustrine series is divided at certain horizons by unconformities and is unconformably over- lain by the lake beds. No direct paleontologic evidence is available, and for the determination of the plane between the Eocene and Miocene, supposing Pahute Lake to have been Miocene, recourse must be had to local physical history. Spurr and Ball carry the Miocene back into the prelacustrine series, the latter making the division between the two periods coincide with an unconformity which, in the local sequence at Goldfield, comes between the latite and the Sandstorm rhyolite. My own preference is to regard the initiation of lacustrine conditions as the most significant physical revolution and, with King, to make that event mark provisionally the beginning of the Miocene, or, in any case, to regard it as one of the principal division planes in Tertiary chronology. I fully realize, however, that the physical event which appears most significant and epoch-making to one student may, in the opinion of another worker, take secondary rank. Moreover, new paleontologic evidence may at any time show that the beginning of the Miocene, and what appears to be the most important break in the continuity of physical history, are not necessarily coincident. Besides, although the andesites of Goldfield and Tonopah are distinctly older than the lake epoch, this proposition can not be asserted with equal confidence in regard to the dacite and dacite vitrophyre of Goldfield and the earlier of the so-called dacites of Tonopah. Still further, the beginning of the lacustrine conditions, as has been shown, may have been far from synchronous over the whole region. So far as it goes, the evidence for an important prelacustrine epoch of volcanism and ero- sion supports the view that the lake sediments are at least not older than the Miocene. It may be considered very doubtful, however, whether it will ever be possible to correlate with precision the Tertiary events of the Great Basin with the well-recognized divisions of the marine deposits of the same period. Whether any close parallelism ever existed between the deposi- tion of sediments known as Eocene, Miocene, and Pliocene along the Pacific margin and the complex manifestations of local volcanic activity, erosion, and lacustrine sedimentation that make up the history of the interior province is open to serious question. The second great division of Tertiary time in western Nevada, provisionally called Miocene, came to an end with the disappearance of the lake and the folding of its sediments. Masked and confused as it is in some localities b}^ later disturbances, this folding, accompanied by faulting, is recognizable as a generally synchronous revolutionary movement for the whole region and was possibly contemporaneous with the post-Miocene uplift of the Coast Ranges. In the third division of the Tertiary, the provisional Pliocene of the Great Basin, King b placed the sediments of his Shoshone Lake, calling them the Humboldt group. Russell c afterward showed, however, that all the deposits described and mapped in the Fortieth Parallel reports as the Pliocene Humboldt group are really the deposits of Lake Lahontan and are a Geology of the Tonopah mining district: Prof. Paper U. S. Geol. Survey No. 42, 1905, p. 091. b U. S. Geol. Expl. 40th Par., vol. 1, 1878, pp. 434 et seq. cLake Lahontan: Mon. U. S. Geol. Survey, vol. 11, 1885, p. 145. TERTIARY CHRONOLOGY. 105 Quaternary. Thus King's Pliocene Shoshone Lake, robbed of its sediments, has with progress of time become more nearly mythical than Spurr a and Ball,6 to judge from their publications, appear to be aware. It is true that Spurr c has noted deposits which are at altitudes above the highest known level of Lake Lahontan and which he believes were deposited in a Pliocene lake; but these observations alone appear scarcely sufficient to resuscitate King's conception of the vast Lake Shoshone. If Russell is right, Lake Shoshone was merely Lake Lahontan and was Quaternary. At all events there are no deposits in the Goldfield district definitely referable to a great Pliocene lake. The Spearhead rhyolite, the Rabbit Spring formation, and the Malpais basalt are provisionally placed in the Pliocene because they are later than the folding and erosion of the supposed Miocene lake beds and have themselves suffered some deformation and much erosion. Finally, the gravels referred to on page 75 are supposed to correspond to the Quater- nary epoch of expanded lakes represented by Lakes Lahontan and Bonneville. The shore features of this epoch are well displayed about Walker Lake, but it is not clear whether actual lacustrine conditions prevailed during the Pleistocene over the Goldfield region. THE ERUPTIVE SEQUENCE. For convenience of comparison the general succession of lavas in the Great Basin region according to Spurr d is in figure 6 placed side by side with the observed succession in the Gold- field district. The order of age is from the bottom vip. The two columns in figure 6 show some general agreement in that the first rocks erupted were rhyolites and the last rhyolites and basalts. Moreover, between these earliest and latest products both columns show lavas of intermediate character. Spurr presents an elaborate two- cycle scheme of regional differentiation into which it is possible to fit most of the locally observed sequences, under the supposition that each of these represents only a part of the record. If a basic rock appears in the wrong place in one line of descent from the parent andesitic magma it may be fitted into the other divergent line; thus if the local sequence be not too full it matters little, so far as conformity with the diagram is concerned, in what order the lavas were erupted. Even the rather full sequence at Goldfield can, by disregarding the quartz-bearing basalt and the basalt of the Portland mine, be shown to have a certain conformity to this scheme. Thus "1. Rhyolite" at Goldfield may be considered equivalent to "1. Biotite rhyolite and tordril- lite;" "2. Latite" at Goldfield to "2. Latite(?)" in Spurr's scheme; "3. Rhyolite" and "4. Rhyolite" at Goldfield to "3. Biotite rhyolite;" "6. Andesite" at Goldfield to the andesitic part of Spurr's fourth group; the dacitic rocks at Goldfield to the biotite-hornblende dacite of Spurr's fourth group; and "12. Rhyolite" and "13. Olivine basalt" at Goldfield to the corre- sponding rocks in the fifth group of Spurr's succession. Furthermore, the Goldfield column may be inverted or its members may be transposed in various ways and it will still fit into the same plan of recurrent general differentiation. To some minds the conformity here shown may appeal as corroborative, but to others, impressed by the scanty representation of the numerous members of the ideal succession in any given locality, the capacity of the scheme for assimilating not only observed sequences, but imaginary ones, raises doubt whether it really represents natural processes. The basal assump- tion that every observed local sequence is a fragmentary expression of a regional two-cycle differentiation of a common magma having the composition of pyroxene-hornblende andesite is the uncertain foundation upon which the whole structure rests. a Origin and structure of the Basin Ranges: Bull. Geol. Soc. America, vol. 12, 1901, p. 246. See also, Louelerback, G. D., Bull. Geol. Soc. America, vol. 15, 1904, p. 339, footnote. 6 Geologic reconnaissance in southwestern Nevada: Bull. U. S. Geol. Survey No. 308, 1907, p. 34. c Geology of Nevada south of the iOth parallel: Bull. U. S. Geol. Survey No. 208, 2d ed., 1905, pp. 107, 117, 123-125 d Succession and relation of lavas in the Great Basin region: Jour. Geology, vol. 8, 1900 p. 643. 106 THE GEOLOGY AND ORE DEPOSITS OF GOLDFIELD, NEVADA. Study of the Goldfield district, moreover, does not indicate such parallelism between sequence and mineralogical composition as is presented by Spurr for the andesitic rocks, par- ticularly in the fourth group of his synopsis. Great Basin (J. E. Spurr) Goldfield Olivine basalt Ultra acidic rhyolite or tordrillite 13. Olivine basalt Augite basalt Biotite rhyolite (Malpais basalt) 5< Hornblende basalt Biotite-hornblende rhyolite 12. Rhyolite (Spearhead rhyolite) 1 \ / \ / Pyroxene-olivine aleutite Hornblende-biotite latite 11. Olivine basalt \ / Pyroxene aleutite Biotite-hornblende dacite (quartz bearing Mira basalt) \ / Hypersthene-hornblende aleutite Biotite-augite-hornblende-quartz latite Hornblende-pyroxene-biotite aleutite Augite-biotite-hornblende latite 10. Andesite 4.< 9. (breccia and dikes) Rhyolite \ / Pyroxene andesite Hornblende-pyroxene andesite \ / (Meda rhyolite) Dacite vitrophyre 8. ' Andesite Pyroxene-hornblende andesite 7. (Chispa andesite) Dacite 3. Biotite rhyolite Olivine basalt \ / 6. Andesite (Milltown andesite. \ / Latite (?) / Generally contem- poraneous biotitic, Dacite / \ / hornblendic, and pyroxenic varieties) Hornblende-quartz andesite Pyroxene andesite (?) Biotite andesite / 5. Olivine basalt 2.< (of Portland mine) Hornblende andesite / Hornblende-pyroxene andesite / 4. Rhyolite (Morena rhyolite) 3. Rhyolite \ / Pyroxene-hornblende andesite (Sandstorm rhyolite) 2. Latite 1. Biotite rhyolite and tordrillite 1. Rhyolite (Vindicator rhyolite) (a) Spurr's use of this name in the Tonopah report leaves the reader in some doubt as to what rock is here meant.— F.L.R. Figure 6.— Succession of lavas in the Great Basin and at Goldfield. TERTIARY CLIMATE. With the advance into the Tertiary the problem of climatic changes strongly challenges attention, not only on account of its obvious bearing on the discussion of erosion and lacu- strine episodes, but also, as will later appear, in view of its being a possible factor in the process of ore deposition. Clarence King states0 that — the Eocene, as a whole, was remarkable over the Fortieth Parallel area for the intensity, rapidity, and grandeur of its processes of disintegration and removal. Like the deposits of the Alps and the enormous Eocene field of Asia, it stands out in the Tertiary as a great interval of degradation and sedimentation. Presumably, therefore, the climate in the Great Basin region during Eocene time was com- paratively humid. The coal and fossil leaves described by H. W. Fairbanks6 in the El Paso «U. S. Geo . Expl., 40th Tar., vol. 1, Systematic geology, 1878, p. 692. b Geology of eastern California: Am. Geologist, vol. 17, 1896, p. 68. TERTIARY CLIMATE. 107 Range, California, and by H. W. Turner0 at the north end of the Silver Peak Range, point to the same conclusion, although the age of these coal-bearing beds is still not definitely known, and there is a possibility that they are Miocene. Although Tertiary lacustrine conditions appear to have begun in a period sufficiently humid for the growth of coal-producing vegetation, there are clear indications in the beds of borax and salt in the southwestern part of the Great Basin that in that part of the region at least, periods of comparatively abundant water alternated with intervals of aridity. Thus through- out the Tertiary the climate of the Great Basin probably swung back and forth between mod- erate humidity and pronounced aridity. In this connection it is important to remember that under the physiographic conditions which appear to have characterized the Great Basin since the beginning of the Tertiary the existence of extensive lakes is consistent with only moderate humidity. A very slight persistent increase of precipitation at the present time, for example, would materially enlarge the existing lakes, whose levels are determined by a delicate, fluctu- ating balance between evaporation and rainfall. As Russell points out, the Quaternary climate in the Great Basin at the time of the greatest expansion of Lake Lahontan must still have been comparatively arid, since the lake never overflowed. The life history of the former lake shows "that its shores must have been at least as desolate and lifeless as the borders of the existing lakes of the same region."6 "The Esmeralda formation: Am. Geologist, vol. 2">. 1900, p. 168. b Russell, I. C, Geological history of Lake Lahontan: Mon. U. S. Geol. Survey, vol. 11, 1885, p. 261. CHAPTER X. MINERALOGY OF THE DISTRICT. INTRODUCTION. The accompanying table presents in alphabetical order the minerals recognized in the Goldfield district. Those of doubtful occurrence are printed in italics. Following the tabular statement are fuller notes on the more important minerals taken up in the same order as that followed in Dana's System of Mineralogy. One mineral listed, namely, goldfieldite, is a new species; and it is possible that the minerals described as famatinite and bismite may also be species not hitherto recognized. Knowledge of these, however, is not as yet sufficient to justify the application to them of new names. Minerals occurring in the Goldfield district. Mineral. Albite Alum (kalinite) Akinite Amphibole Andcsine Apatite Augite Azuritc Barite Biotite Bismite Bismuthinite Bylownitc Calcite Cerargyrite Chalcanthite Chalcopyritc Chlorite Cinnabar Copper Diaspore Durdenite Emmonsite Enargite Emtatite Epidote Famatinite Galena Gold Goldfieldite (new species). Gypsum nalotrichite Hematite Hornblende Hypersthene Jarosite Kalinite Kaolinite 108 Fermula. Occurrence. NaAlSi3Os K2SOt.Al2(S04)3+24H20 K(A10)3(S04)2+3H20 (See Hornblende.) Variable mixtures of the albite and anorthite molecules ranging from AbsAni to AbiAni. (CaFJCa^POOa or (CaCl)Cm(POOs . . . Variable. Complex silicate 2CuC03.Cu(OH)2 BaSO, Complex silicate of H, K, Mg, Fe, and Al. Bi203 Bi2S3 Variable mixtures of the albite and anorthite molecules ranging from AbiAn3 to AbiAn6. CaCOa AgCl CuSO«+5HsO CuFeSs Complex silicale of H, Fe, Mg, and Al. Variable. HgS Cu AIO(OH) Fe2(Te03)3+4H20 Not known 3Cu2S. As2S3 (Mg, Fe)Si03 Complex silicate of Ca, Fe, and A 1 Cu3(Sb, As)S, PbS An 5CuS.(Sb,Bi,As)s(SeTe)3 CaSO,+2II20 FcO. Al2Os.4S03+24II20 Fe203 Variable. Complex silicate ( Ke.Mg)Si03 K2(.Fe(OH)2)0(SO4), (See Alum.) H,Al2Si20» As microperthite in alaskite. Possibly also in some of the andesitic andrhyolitic lavas. Not definitely recognized, but probably occurs in some mines in lower part of zone of oxidation. Abundant as constituent of altered volcanic rocks and in soft massive form with ores. Probably present with other feldspars in dacite and andesite. As microscopic constituent of andesite, dacite, and basalt. As constituent of andesite, dacite, and basalt. Very sparingly as blue stain in some oxidized ore. Reported from Florence and Reilly mines. Abundant with ore in Sandstorm and Kendall mines. Sparingly present in Reilly, Consolidated Red Top, and Commonwealth mines. In dacite and dacite vitrophyre; in some of the varieties of andesite and basalt; in granitic facies of alaskite. Minute pearly scales in oxidized ore of Combination, January, Sandstorm, and probably other mines. Acicular crystals in ore of mines near Goldfield. Usually associated with famati- nite and gold. Probably present in some of the andesites and basalts with other plagioclases. In some unimportant veins; as cement of some tuffs and sediments; as amygdules in basalt; in propylitically altered rocks; with alunite in altered rhyolite on Vindicator Mountain as a microscopic constituent. In oxidized ore near Diamondfield. Sparingly present near base of oxidized ore in most of the large mines near Gold- field. Reported from Sandstorm, Kendall, Combination, and Florence mines. As alteration product of biotite in propylitic dacite, latite, and andesite. Disseminated through altered andesite or andesitic tuff H miles east of Black Butte. Native. Reported in surface panning. As microscopic constituent with alunite in altered rocks. In oxidized ores near Diamondfield. Not certainly distinguishable from emmonsite. In oxidized ores near Diamondfield. Not certainly distinguishable from durdenite. In ore of the Gold Bar and Victor mines. Some of the material called famatinite in this report may be enargite. See page 117. As microscopic constituent of some varieties of andesite. In propylitically altered dacite, andesite, and latite. Characteristic of rich sulphide ore. with native gold in mines near Goldfield. Not known in ores of the principal mines. Occurs in January-White Rock lease, just east of Goldfield, and in Mushett and Consolidated Red Top leases north of the Mohawk mine. Native. The principal valuable, constituent of both sulphide and oxidized ores. Occurs intimately associated with gold, marcasite, and famatinite in some of the richest ores. Widely distributed in ores and altered rocks. Particularly associated with soft crushed material along fissures. As superficial deposits in southern part of dis- trict. As etllorescence in disused workings. As minute crystals in workings of Hat lease: probably with limonite in some iri- descent coatings on rock surfaces. Constituent of dacite, latite, and some varieties of andesite. As microscopic constituent of some varieties of andesite. In altered tuff J mile south of Myers Mountain. In altered rocks near ore bodies, ciatcd with alunite. As soft white masses with ore. Often asso- MINERALOGY. 109 Minerals occurring in the Goldfteld district — Continued. Mineral. Formula. Occurrence. Labradorite Limonite... Magnetite.. Malachite. . Marcasite. . Massicot. .. Melanterite. Muscovite. . Oligoclase.. Olivine Orthoclase . Petzite Polybasite. . Proustite . . . Pyrite Pyroxene . . Quartz Rutile Scapolitc . . . Serpentine . Sphalerite.. Sulphur Tellurides. . Tellurite... Titanite Zircon Zoisitc Variable mixtures of the albite and anorthite molecules ranging from AbiAni to AbiAn3. HeFe^Og Fe304 CuC03.Cu(OH)2 FeS2 PbO FeSO,+7H20 H2KAl3Si30i2 Variable mixtures of the albite and anorthite molecule ranging from Ab6Am to Ab3Ani. (Mg, Fe)2SiO, KAlSi3Os (Ag,Au)2Fe Ag„SbS6 Ag2AsS3 FeS2 (See Augite.) Si02 Ti02 Silicate of Ca, Na, and Al. Composi- tion variable. n Brauns, Chemische Mineralogie, Leipzig, 189S, p. 299. MINERALOGY. 113 Sphalerite occurs also in the Mohawk-Red Top and Five Friends leases and probably in other lessee workings north of the Mohawk mine. It has also been noted in a small stringer in alaskite in the Lucky Boy prospect on Vindicator Mountain and in the ore of the Loftus and Davis lease on the Great Bend, northwest of Diamondfield. CINNABAR. The very characteristic sulphide of mercury (HgS), with its cochineal-red color and ada- mantine luster, occurs in the northeastern part of the district, but is not known in the gold deposits. The cinnabar rock outcrops on the Brooklyn claim, about l\ miles east of Black Butte. The mineral forms irregular crystalline aggregates, up to an inch in diameter, rather abundantly disseminated through material which was probably once andesite or andesite tuff, but which has been intensely altered and is now a mass of cryptocrystalline secondary quartz, mottled with cinnabar and limonite. The deposit apparently is not of economic importance. > The occurrence of cinnabar in the Goldfield district, in view of the well-known association of this mineral with volcanic activity, is of interest in connection with the problem of the genesis of the gold ores, as will be more fully shown in another place (p. 174). CHALCOPYRITE. The tetragonal copper-iron sulphide (CuFeS3), sometimes called "copper pyrite" or "yel- low copper," is very rare in the Goldfield district. It has been reported in small quantity in the Sandstorm and Kendall mines, but was not seen in the course of the present investigation. E. A. Collins61 states that it has been found very sparingly in the Combination mine. A speci- men of rich ore, said to be from the Florence mine, and in the possession of Mr. F. O. Altinger, of Goldfield, was examined by Mr. G. H. Garrey, who noted the occurrence of minute crystals of chalcopyrite lining small vugs and associated with bismuthinite, ruby silver (proustite?), and a mineral resembling polybasite in crystallization. The rarity of chalcopyrite at Goldfield is remarkable, as most of the ores contain copper, and both sphalerite and galena, which often accompany this mineral in other districts, have been found in the leases north of the Mohawk mine. PYRITE. Common pyrite, the isometric disulphide of iron (FeS2) is the most abundant and ubiqui- tous sulphide in the district. It is a constituent of practically all the rocks in the region except some of the later rhyolites, basalts, and lake sediments. It is disseminated through the propy- litically altered andesite, dacite, and latite, where it has formed from the action of sulphide solutions upon biotite, hornblende, augite, and magnetite. As shown on page 179, it makes up a considerable percentage of the dacite that has undergone alunitic and kaolinitic alteration, particularly in the vicinity of the ledges. It is also finely disseminated through the altered rhyolites, although less abundant in these rocks than in those originally richer in iron-bearing silicates. Within the ledges, pyrite occurs disseminated through the altered siliceous rock forming the gangue of the ore, in the form of small bunches and metasomatic veinlets, and as crusts with gold, goldfieldite, famatinite, bismuthinite, sphalerite, quartz, alunite, and kaolinite around fragments of altered rock. In all of these occurrences the mineral usually forms aggregates. Individual crystals of free growth and large enough for the recognition of crystal habit are rare. Such faces as are visible indicate that the prevalent form is the pyritohedron, variously modified. When the crystals have been able to grow without mutual interference, as is the case in small vugs filled a. The Combination mine: Min. and Sci. Press, Sept. 28, 1907, p. 398. 79145— No. 6G— 09 8 114 THE GEOLOGY AND OEE DEPOSITS OF GOLDFIELD, NEVADA. with spongy friable quartz or in soft massive kaolinite or alunite, the usual form assumed is a sharp octahedron, in some cases modified by small cubic and dodecahedral faces. Such octa- hedral crystals were noted on the 250-foot level of the Florence mine. Small brilliant crystals embedded in alunite, from the 230-foot level of the Combination mine, show a dominant octa- hedron modified by small faces of the cube, dodecahedron and pyritohedron. Beautiful clus- ters of sharp, brilliant crystals from the Mushett lease show a similar combination, but with the pyritohedral faces dominant. The well-formed individual crystals are invariably small, most of them being less than a millimeter in diameter. Pyrite with alunite, forming pseudomorphous aggregates after orthoclase, occurs in the Morena rhyolite at the Conqueror mine. Crystallized with gypsum it is found on the 150- foot level of the Goldfield-Belmont mine. While pyrite is widely distributed in the Goldfield district, few observers familiar with other mining regions can fail to note the absence from the known Goldfield deposits of any considerable masses of this mineral. It is everywhere present but nowhere aggregated into bunches or veins of any notable size or purity. This is undoubtedly due to the fact that the pyrite has formed mainly from the ferrous silicates and magnetite in the rocks and has under- gone very little transportation or segregation. The Assuring, moreover, was not of a charac- ter to favor the accumulation of large solid masses of sulphides. The mineral is not all of one generation, as will be shown in the section on paragenesis on page 170. Whether the pyrite in the Goldfield deposits is auriferous is not easily determined. That it is not highly so is certain, since assays of the most pyritous ledge matter often show very little gold, and abundance of pyrite is generally a sign of poor, rather than rich ore. On the other hand, it is difficult to establish the absence of all gold from the pyrite, owing to the impossibility of obtaining this sulphide entirely free from other constituents of the ore in which the gold might be held. Undoubtedly pyrite might be obtained in the district which contains practically no gold; but the pyrite to which most interest attaches is that in, or close to, rich ore, and it is this selfsame pyrite which can not be separated with certainty from its associated minerals. Famatinite and bismuthinite, for example, which are known to contain particles of gold, may in turn be embedded in pyrite. In order to" obtain some light upon this problem, samples of pyritized dacite were collected from various mines and assayed. All the samples were taken within the general boundaries of the ore-bearing zones, the aim being to obtain material in which pyrite was the only sulphide and which at the same time lay as close as possible to ore. The pyrite in all of the specimens is disseminated in varying abundance through a gangue consisting chiefly of quartz and alunite. The assays were made by Ledoux & Co., New York. Assays of pyritized docile. [Ounces per ton.] Specimen. Locality. Gold. Silver. Remarks. G.624.. Florence mine, 250-foot level, north end 0.075 .030 .68 .55 .145 0.70 .13 2.60 .05 .20 Pyrite in minute crystals, abundantly dissemi- G.819 Combination mine, 230-foot level, near vertical shaft. nated. Similar to above. G.818 Pyrite verv abundant. Spurr, J. E., The ores of Goldfield, Nevada: Bull. U. S. Geol. Survey No. 260, 1905, p. 137. c Eansome, F. L., Garrey, G. H., and Emmons, W. H., Preliminary account of Goldfield, Bullfrog, and other mining districts in southern Nevada: Bull. U. S. Geol. Survey No. 303, 1907, p. 30. d King, L. M., The sampling and assaying of a car of bonanza ore: Min. and Sci. Press, vol. 94, 1907, p. 241. In an editorial in the same number the statement is made that calaverite occurs in the Mohawk ore. The method of identification is not given and the statement is probably a conclusion from the ratio of gold and tellurium found in the ores, since no distinct crystals of this mineral have been found at Goldfield so far as can be learned. 116 THE GEOLOGY AND OKE DEPOSITS OF GOLDFIELD, NEVADA. In June, 1907, W. J. Sharwood" published a drawing of a thin section of Mohawk ore in which he shows particles of native gold embedded in a dark "sulpho-telluride," which he found — gave strong reactions for sulphur, tellurium, copper, and iron, also for arsenic, antimony, gold, and silver (about 6 per cent and 1 per cent, respectively, of the two last) — a composition agreeing with the admixture of tetrahedrite and telluride suggested in the editorial referred to. To all outward appearance, however, the material seems to be uniform in character and gives no evidence of being such a mixture. In a thin section of another specimen of Goldfield ore Sharwood detected particles resembling sylvanite associated with native gold. The dark-gray mineral supposed by Sharwood to be a mixture of tetrahedrite and calaverite is further described under ''Goldfieldite." The par- ticles thought to be sylvanite may have been marcasite, the resemblance of the marcasite of this ore to sylvanite in color, luster, and striations being deceptively close. PROTJSTITE. Ruby silver (Ag2AsS3) has been noted on only a single specimen, purporting to come from the Florence mine, and preserved in a private collection in Goldfield. The identification of the mineral was made by Mr. Garrey, who examined the specimen but was unable to obtain it for confirmatory tests. The occurrence of proustite in the district can not, therefore, be regarded as established. POLYBASITE. The mineral polybasite, essentially a sulphantimonite of silver (Ag9 SbS)6, has not been identified with certainty in the Goldfield ores. Crystals of a form and color resembling polyba- site were observed by Mr. Garrey, associated with a little ruby silver, in the specimen of ore referred to in the preceding paragraph. The ore was said to have come from the Florence mine. GOLDFIELDITE. At the time of second visit to the district, in 1908, specimens' were secured of the dark tellurium- and gold-bearing material from the Mohawk mine for the purpose of determining its mineralogical and chemical character. A piece of rich ore from the Mohawk-Combination lease (a consolidation of the Sheets-Ish and Kalfus leases) was broken up and the fragments of the dark telluric crust picked as free as possible from the gangue. These were crushed to pass through a 40-mesh screen and freed from fine dust. The grains were picked over several times under a lens and a separation effected into (1) yellow grains, (2) gray grains, and (3) mixed grains and gangue. The yellow grains proved to be marcasite. The gray portion when examined under the microscope appeared homogeneous with the exception of a few minute specks of gold embedded in the gray mineral. The latter is dark lead gray with a high metallic luster. It is brittle, breaks with a conchoidal fracture, and has a hardness of 3 to 3.5, although on account of the brittleness of the material it appears to be somewhat softer when crushed. No crystal faces have been detected. The small quantity of purified material, only 1.2 grams in all, was analyzed by Doctor Palmer with the following result: Preliminary chemical analysis of goldfieldite . I i >pper 33. 49 Sulphur 21. 54 Tellurium 17. 00 Antimony 19. 26 Arsenic .68 Bismuth 6. 91 Gold.... Silver... Gangue. 0.51 .18 2.00 101. 57 Of the gold about 0.40 per cent in terms of the whole analysis is combined, presumably with tellurium, and 0.11 per cent is native. Doctor Palmer states that the mineral is essentially a cupric sulphantimonite in which part of the antimony is replaced by arsenic and bismuth and part of the sulphur by tellurium. He a Gold tellurides: Min. and Scl. Press, vol. 94, 1907, p. 7.31. MINERALOGY. 117 suggests that the analytical results approximate closely the formula 5CuS.(Sb,Bi,As)2(S,Te)3. The minerals geocronite (5PbS.Sb2S3) and stephanite (5Ag,S.Sb2S3) have analogous formulas whereas the known copper sulphantimonites and sulphantimonates are all cuprous salts. As bismuthinite is a common mineral in these ores, the possibility that the material analyzed might be an intimate mixture of bismuthinite with some other mineral has been considered. If the analysis be calculated in molecular proportions, and the constituents of bismuthinite (Bi2S3) be subtracted, the following molecular quantities remain: Cu 0.527 J As 0.009 S 624 Au 002 Te 133 Ag 001 Sb 160 For famatinite the theoretical proportions are: Cu, 0.6; S, 0.6; Sb, 0.2; so that the residue after subtraction of bismuthinite does not correspond very closely to famatinite, even if the tellurium be ignored. This constituent, it is to be observed, is far in excess of any quantity which could be accounted for as combined with the gold and silver, and a part of the gold is known to be free. While determinative work on minerals such as the sulphantimonites, which rarely show crystal form and are often intergrown with other minerals, is as a rule more or less unsatisfac- tory, there seems to be no escape from the conclusion that the present mineral is a new species. It is provisionally so regarded and "goldfieldite" is suggested as an appropriate name. It is hoped that additional material can be secured for further analytical and microscopical investi- gation in the near future. In some ore, especially that of the Mushett lease, the association of goldfieldite and famati- nite is very close, and it is possible that such ore may contain intermediate species or varieties. ENARGITE. Crusts of a dark-gray brittle compound of copper, arsenic, antimony, and sulphur are characteristic of the ore of the Victor and Gold Bar mines. The substance is similar in habit and appearance to a mineral which is commonly associated with the rich ores near Goldfield and which, as will be shown, appears to correspond more nearly to famatinite than to any other known species. It presents some differences, however. It lacks for the most part the reddish tint of the famatinite, is rather more brittle, shows more tendency toward crystalline structure, and is not associated with rich ore. The crystal habit of the mineral is prismatic, the faces being longitudinally striated. It has at least one cleavage, although the crystals are too few and imperfect to permit determination of its crystallographic orientation. Mr. W. T. Schaller was able to isolate one crystal with rather uneven faces, which gave the following goniometric readings in the prism zone : 100 A H0= 41° 30' 100 A 120= 60° 30' 100 A 110= 40° 30' TOO A 100=179° 30' These agree fairly well with the calculated angles for enargite, which are — 100 A H0= 41° 04' 100 A 120= 60° 09' TOO A 110= 41° 04' 100 A 100=180° 00' As enargite and famatinite are isomorphous, however, the measurements serve only to rule out tetrahedrite, which contains the same constituents as famatinite or enargite, although in different proportions. It will presently be shown that the composition of the mineral called famatinite in this report is not normal, but indicates a variety between that mineral and its isomorph, enargite. It is likely that at Goldfield there are various representatives of the 118 THE GEOLOGY AND OEE DEPOSITS OF GOLDFIELD, NEVADA. enargite-famatinite series separated by no sharp differences in composition. The mineral from the Gold Bar and Victor mines is probably nearer to the enargite end of the series than most of these varieties. Not all of the cupriferous material from the Gold Bar mine is of the same kind as that just described. Some of it is indistinguishable from the famatinite of the Florence and other mines nearer Goldfield. FAMATINITE. Forming part of the rich sulphide ore in most of the mines near Goldfield is a massive metallic mineral of dark-gray color, with a tinge of copper red. This has been commonly called " bornite." In the preliminary report on the district a it was shown that the so-called " bornite " contained antimony, and accordingly it was there provisionally referred to as tetrahedrite, although attention was called to the possibility of its being famatinite. In order to determine if possible the species of the mineral, a specimen of ore from the January mine was broken up, and material for chemical analysis was carefully picked out under a lens. The selected particles contained considerable quartz, a very little intergrown pyrite, and still less bismuthinite. The analysis is as follows: Chemical analysis of mineral from January mine. [By W. T. Schaller.] Quartz gangue (99 per cent Si02) 54. 60 Copper 20. 05 Sulphur 13. 64 Antimony 5. 09 Arsenic 4. 61 Iron 1. 46 Manganese .02 Silver None. Bismuth, lead, zinc Traced?). Water at 110° C .32 99. 79 By elimination of the silica and obviously unessential or negligible constituents, and by recalculation to 100, the analysis may be more simply stated as follows: Compositio7i of mineral from January mine. Copper 44. 8 Sulphur 30. 5 Antimony 11. 3 Arsenic 10. 2 Iron 3.2 100.0 For comparison the theoretical compositions of tetrahedrite, tennantite, enargite, and famatinite are given below : Theoretical compositions of tetrahedrite, tennantite, enargite, and famatinite. Tetrahe- drite. Tennant- ite. Enargite. Famati- 1 1 M ... Cu 52.1 57.5 17.0 48.3 19.1 43.3 As Sb - 24.8 23.1 27.4 s 25.5 32.6 29.3 100.0 100.0 100.0 100.0 In nature, however, the antimony and arsenic mutually replace each other, giving rise to intermediate chemical compounds. Most analyses of enargite and famatinite, show a little iron. a Bull. V. S. Oeol. Survey No. 398, 1907, p. 34. MINERALOGY. . 119 While it is possible that in some varieties of these minerals the iron may be chemically com- bined, the Goldfield material is known to contain a little inseparable pyrite, and it is probable that all the iron found in analysis is present as pyrite. By eliminating the constituents of this pyrite and recalculating the analysis to 100 the following figures are obtained for the compo- sition of the Goldfield mineral: Composition of famatinite or enargite from Goldfield. Cu 48. 0 As 11. 0 Sb 12.2 S 28. 8 100.0 This composition is intermediate between theoretical enargite and theoretical famatinite. As both minerals are orthorhombic and isomorphous, the occurrence of an intermediate variety is not surprising. Attempts to calculate a simple formula corresponding to the foregoing per- centage composition have not been successful, and it is not clear whether the copper is in the cupric or the cuprous condition. The atomic ratio of copper to sulphur in the Goldfield mineral is approximately as 7 to 8. In a formula of the stephanite type it should be as 5 to 8, in one of the famatinite type as 6 to 8, and in one of the tetrahedrite type as 9 to 8. The Goldfield material can not be definitely assigned to either enargite or famatinite. Its massive habit, reddish-gray color, and slight preponderance of antimony over arsenic suggest, however, closer affinity with famatinite than with its corresponding arsenical isomorph, and as knowledge of the variety is insufficient to justify the application to it of a new name, it will be referred to as famatinite in this report. The famatinite is comparatively abundant in the Florence, Jumbo, Combination, and January mines, where it is usually associated with rich ore and often contains visible particles of native gold. Although gold does not appear to enter chemically into the constitution of the famatinite, the association of this mineral with the richest ore is often very marked. A specimen of ore from a winze a few feet below the 250-foot level of the Florence mine was broken up and sepa- rated into two parts, one containing most of the pyrite (more abundant in this specimen than usual) , the other most of the famatinite. The portion containing the most pyrite gave on assay 2.31 ounces of gold and 1.8 ounces of silver to the ton; the portion richer in famatinite gave 53.37 ounces of gold and 3.17 ounces of silver. This result is rather remarkable, as this particular ore shows no native gold under a hand lens. A similar separation was made of some ore from the January mine, although in this case the portion containing the less famatinite was mainly quartz, with probably no more pyrite than was present in the other portion. The portion with the most famatinite afforded on assay 15.70 ounces of gold and 25 ounces of silver to the ton; the quartzose residue gave 9.32 ounces of gold and 11.08 ounces of silver. On the other hand, a sample from the 200-foot level of the Jumbo mine containing rather abundant famatinite was found on assay to contain only 0.26 ounce of gold and 0.25 ounce of silver to the ton. Thus famatinite and a high proportion of gold are not invariably associated. CERARGYRITE. Halogen compounds of silver appear to be very rare at Goldfield, owing doubtless to the fact that the proportion of silver in the ores is small. Nevertheless, it might have been expected, a priori, that in the oxidation of ores of such remarkable richness, in which the silver, though relatively unimportant, rises in some cases to over 60 ounces to the ton, noticeable quantities of cerargyrite would form. The only mines in which any chloride of silver has been distinctly recognized are the work- ings of lessees on the Gold Coin claim of the Jumbo-Extension Company and the Toplitz lease on the Daisy No. 1 claim, both near Diamondfield. Cerargyrite occurs in the oxidized ore of 120 THE GEOLOGY AND OEE DEPOSITS OF GOLDFIELD, NEVADA. the Gold Coin as minute, waxy, olive-green crystals implanted on limonite or rusty ledge matter. Owing to the high specific gravity of the mineral it can be separated with the free gold by panning. Associated with the gold, cerargyrite, and limonite are kaolinite and small quantities of an obscurely crystalline yellow mineral, which is a ferric tellurite, probably emmonsite or durdenite. The ore from the Gold Coin claim is more argentiferous than most of the Goldfield ores, some assays showing nearly 2 ounces of silver to 1 of gold. This fact probably accounts for the presence of cerargyrite in the oxidized part of the deposit. A few minute specks of light-green color noted in the ore of the Toplitz lease are probably embolite or bromyrite. The material was insufficient for chemical tests. QUARTZ. The quartz of the Goldfield district is a gray, aphanitic, flinty material bearing little resem- blance to the white, coarsely crystalline variety characteristic of typical quartz veins the world over. The coarsely crystalline mineral, such as forms the gangue of the California gold veins, has filled open fissures, having been deposited from siliceous solutions. The greater part of the Goldfield quartz, on the other hand, occupies space once filled by shattered or fissured rock. To say that this rock has been silicified only partially expresses the facts. The quartz is in large part the silica of the original dacite, andesite, or rhyolite, as the case may be, left behind, as a more or less porous mass, in the removal of other constituents. In parts of this mass, where fissures are most abundant, additional silica has been metasomatically introduced. A further increment of silica has crystallized as quartz druses on the walls of cavities which are in part interstitial and in part the result of the removal of phenocrysts by solution. In such a mass of quartz the pyrite is probably in large part derived from ferrous silicates and magnetite in the original rock. It has, however, undergone some migration and segregation. The other sulphides and the gold have been for the most part metasomatically introduced, although to a minor extent they fill small cavities. * The steps in the conversion of rock into quartz are fully described in the chapter on meta- somatic alteration, pages 176 to 186. In the Goldfield ores, quartz rarely occurs in crystals of such size as to be distinctly visible with the naked eye. They are mostly microscopic. Even in the druses of open cavities a lens is usualty necessary to distinguish the individual faces of the crystals. Under the microscope the flinty quartz appears as a finely crystalline mosaic of quartz grains. This may show no trace of the texture of the original rock, but quartz of the kind described is connected by insensible gradations with aggregates of quartz, alunite, kaolinite, and pyrite, in which the porphyritic structure of the dacite, andesite, or rhyolite is still recog- nizable. The microstructure of this cryptocrystalline quartz is illustrated in Plates XXVI and XXVII. In the Goldfield-Belmont mine the altered andesite in places is traversed by dull-white stringers composed of a cryptocrystalline aggregate of quartz and kaolinite. Some of these veinlets grade into soft, nearly pure kaolinite. In the same mine is some white quartz, carry- ing a little pale-green sericite, which more closely resembles ordinary vein quartz than does most of the mineral in the district. Close inspection, however, shows that this material is a very finely crystalline granular aggregate. Some of it is porous with a structure suggesting incrustation of a prismatic mineral since entirely dissolved. This, however, is little more than a suggestion furnished by the resemblance of the material to quartz pseudomorphs after celes- tite at Cripple Creek.3 The quartz in the upper workings of this mine has in places been crushed to a loose sugary condition. An unusual variety of quartz is found in the Gold Coin workings of the Jumbo-Extension Company, near Diamondfield. This is dark gray and cryptocrystalline. Its peculiar feature a Lindgren, W., and Ransome, F. L., Geology and gold deposits of the Cripple Creek district, Colorado: Prof. Paper U. S. Geol. Survey No.54, 1900, p. 125. MINERALOGY. 121 is a vesicular structure, the vesicles being smooth and spherical and ranging up to half an inch (12 millimeters) in diameter. Most of them are empty, but some are filled with alunite or kaolinite. The material is probably an altered, vesicular glassy volcanic rock. Whether it was originally a local vitreous facies of the andesite, which is the general country rock, or an included mass of rhyolite is not clear. The microscope shows a spotty quartz mosaic with faint suggestions of a former igneous texture. As will be shown in the section on paragenesis, the quartz associated with the ores is not all of one generation. In addition to its occurrence in the ledges, quartz is an original constituent of some of the igneous rocks of the district, particularly of the alaskite, rhyolites, and dacite. In the rhyo- lites and dacite it is present as rounded and embayed phenocrysts which, as they usually remain unchanged in the alteration connected with ore deposition and are readily distinguished from the fine-grained later quartz, serve as useful and reliable means of determining the original rock from which much of the ledge matter has been derived. On this account sections of some of the larger and more irregular quartz phenocrysts from altered dacite are shown in figure 7. Quartz also occurs as phenocrysts in the Mira basalt. (See p. 69.) BISMITE. The artificially prepared trioxide of bismuth (Bi203) crystallizes in the orthorhombic system, although accord- ing to Danaa the natural mineral is not crystallized, but is found in massive, disseminated, or earthy condition. In the Goldfield district, bismite occurs in the January, Combination, Sandstorm, and probably also in other mines, as minute pearly scales with brilliant luster and of silvery white- ness. The luster of the scales is almost metallic and suggests at first glance delicate and untarnished crystals of native silver. The mineral is limited to the oxidized zone, is usually accompanied by limonite, and is frequently associated with rich ore. It occurs as single glittering scales or specks on the walls of cavities in spongy limonite or rusty ledge matter, as delicate frost-like films on the same materials, and as spongy aggre- gates with quartz. In the last-named form it is clearly pseudomorphous after bismuthinite, the material having consisted originally of a mass of bismuthinite prisms held together by a siliceous gangue. The prismatic structure of the bismuthinite is retained as hollow casts in the quartz, lined or partly filled with scales of bismite. As natural crystals of bismite do not appear to have been found hitherto and as the mineral has been assigned to the orthorhombic system in Dana's and Hintze's mineralogies on the basis of Nordenskiold's work on artificial crystals in 1860 and 1861, considerable interest attaches to the Goldfield occurrences on account of the crystallinity of the material. When examined under the microscope in gently powdered material the crystals appear as thin colorless scales, with occasionally a suggestion of hexagonal outline. On account of their tenuity, it is rare that an edge view of a scale is obtainable. The larger fiat-lying scales are dark in all positions between crossed nicols and give a negative uniaxial figure with convergent light. There are no colored rings and the double refraction is apparently not great. The z millimeters Figure 7. — Characteristic outlines of quartz phenocrysts in dacite. a System of Mineralogy, sixth ed., New York, 1895, p. 200. 122 THE GEOLOGY AND ORE DEPOSITS OF GOLDFIELD, NEVADA. refractive index, on the other hand, is rather liigh, being greater than that of anorthite. The mineral has a perfect basal cleavage, and the scales, viewed without the analyzing nicol, com- monly show delicate interference colors due to the refraction and reflection at the surfaces of the exceedingly thin cleavage sheets. Some of the best material obtainable was analyzed in the United States Geological Survey laboratory by W. T. Schaller, as follows: Chemical analysis ofbismite. Insoluble in hydrochloric acid ; mostly quartz gangue 78. 94 Bi203 17.04 Fe203 36 Loss on ignition 3. 96 100. 30 The results show that the mineral is either bismite or else a hydrous oxide of bismuth. If the latter be the case the mineral is a new species. Attempts to isolate a sufficient quantity of the pearly scales from the gangue for separate analysis were not successful. Mr. Schaller has kindly furnished the following crystallographic note: The minute, tabular crystals are too incomplete to allow of a determination of their geometrical form by crystal- lographic measurements alone. From the uniaxiality of the crystals, their hexagonal outline, triangular markings on the base, and distribution of faces as far as seen, one seems justified in referring them to the rhombohedral division of the hexagonal system. As given in detail further along, the c axis is 0.5775. Seven faces were determined as present; the base, five positive and one negative rhombohedra. Besides these, there were indications of two more positive rhombohedra. Below is given a brief description of these forms. c (0001). Always very large, even, and highly polished. Sometimes shows triangular markings or striae, the faces parallel to these markings being taken as positive. o (10l6). Occurs on two crystals, as broad faces giving, however, poor reflections. One face was considerably striated, giving two signals a degree apart. q (10 15). Broad faces giving fairly good reflections. u (10l4). Narrow faces, one striated with a fair reflection, and one as a line face giving a very poor reflection. k (10l3). Usually as a line face, striated and giving a very poor reflection. dl (2025). A doubtful face, narrow, giving no distinct signal. ? (1012). Another doubtful face, broad, giving no distinct reflection. y (2021). Line faces, giving exceedingly faint reflections. z (OlTl). The only negative rhombohedron observed. Very faint line faces, giving no reflection. Its negative position could be determined only on crystal No. 6. The measurements of the forms are shown below: Measured. Calcu- lated. (0001):(1016).... (0001):(1015).... (0001):(1014).... (0001):(10i3).... (0001):(2021).... (0001):(0111).... Doubtful forms: (0001):(2025) (0001):(10!2) 6° 7" 9° 12" 13° 54' 35' 15' 16' 37', 6" 41' 33', 7° 36' 31', 9° 31' 11', 12° 26' 18',12M4° ,54° ,32J° -20° 6° 21' 7° 36' 9° 28' 12° 3r 53° 08' 33° 42' 14° 56' 18° 26' The value for the c axis was obtained from three measurements that were considered as the most accurate. The others gave values agreeing fairly well with the one adopted, as is shown below. The crystals were measured on the two-circle goniometer, and the p angle for these forms is the angle between that form and the base. The three best measurements are: p (10l5)=7° 33' .-. po=0.6627 Crystal No. 1. p (10l5)=7° 36' p0= .6672 Crystal No. 4. p (1014)=9° 31' p0= .6706 Crystal No. 2. Average p0= .6668; c=0.5775. MINERALOGY. 123 An average of the other measurements gave values closely agreeing. Thus: p (1016)= 6° 37' p (1016)= 6° 41' p (1014)= 9° 31' p (1013)=12° 11' p (1013)=12° 26' p (1013) =13° 18' p0 =0.6960 p0= .7031 Po = Po = Po = Po = .6706 .6477 .6614 .7102 Crystal No. 3. Crystal No. 6. Crystal No. 6. Crystal No. 6. Crystal No. 4. Crystal No. 1. Average = . 6815 po=0.69 Crystal No. 1. Po= -67 Crystal No. 2. Po= -65 Crystal No. 1. Po= -70 Crystal No. 5. Po= -64 Crystal No. 6. p0= .69 Crystal No. 1. Po= -69 Crystal No. 6. orthographic The following measurements of faces giving no distinct reflections also showed close agreement. p (1013) = 12°-14° (av. 13°) p (2025)=15° p (1012) = 16°-20° (av. 18°) p (0111)=35° p (0111)=322-° p (2021) =54° p (2021) =54° The values for p0 just given show that the interpretation of the forms is the correct one. Of the six crystals (all incomplete) that were measured, only two are here figured. In figure 8 a is an projection of a crystal (No. 1), showing the trigonal distribution of the rhom- bohedra and the triangular marking on the base, b shows a similar projection of crystal No. 6, with a negative rhombohedron . An odd feature of these crystals is that the development of the faces is so uneven that no two faces of the same form are present on the upper half of a crystal, though this is in part due to the incompleteness of each crystal. From the foregoing observations it appears that the natural bismite is not orthorhombic, but belongs to one of the uniaxial systems, probably the hexagonal. Its presence in oxidized ore appears to be "uniformly indicative of bismuthinite in the original sulphide ore. Some migration, however, has taken place during oxidation, and the scales of bismite do not always occupy the exact positions of the parent needles of bismuthinite. TELLURITE. The oxide of tellurium (Te02) occurs sparingly with a tel- luride of gold in the Goldfield-Belmont mine, north of Diamond- field, as a crystalline honey-yellow mineral with subadamantine luster. Only one small speck of the mineral was obtained, which was determined chemically by Mr. W. T. Schaller. MASSICOT. A little lead, apparently in the form of the yellow oxide (PbO), occurs in the workings of the No. 3 lease on the Commonwealth ground, a little more than 2 miles east of Goldfield. The sup- posed massicot, with probably various impurities, forms porous, sinter-like, yellow incrustations in the interstices of shattered and silicified latite, associated with kaolinite and alunite. Mr. W. T. Schaller found on chemical tests that the yellow material contains a little lead. The evidence that the metal in this earthy mixture is really in the form of massicot can not be regarded as conclusive. Figure 8. Crystal form of bismite from Goldfield. HEMATITE. The anhydrous oxide of iron (Fe203) occurs in nature as the crystalline (rhombohedral) variety known as "specularite " and in various fibrous, botryoidal, massive, and earthy forms. The latter are generally distinguished from the hydrous oxide, limonite (2Fe203.3H20), by a red 124 THE GEOLOGY AND ORE DEPOSITS OF GOLDFIELD, NEVADA. instead of a brown or yellow streak or powder and of course by the absence of any notable quantity of combined water. Between limonite and hematite, however, are the intermediate species gothite (FeO.H,0) and turgite (2Fe203.H20). As these various minerals frequently occur together, the determination of the mineral species represented in a massive aggregate of partially hydrated iron oxide is not always a simple matter. It is probable that some of the brilliant iridescent films described later under "Limonite" are in part hematite. Although apparently none of them is quite anhydrous, they for the most part give dark-red streaks. In the croppings of what is known as the "Hat lease" on the Blue Bull ground, earthy red hematite associated with ocherous and botrvoidal limonite is abundant as a cement of brecciated and silicified andesite. Close inspection of this material shows that some of the fragments are coated with thin glistening black films, which give a red streak like that of hematite. The micro- scope resolves this film into minute crystals of specularite, about 0.05 millimeter in diameter, implanted on a brown, finely botryoidal surface of a crust of limonite. These little crystals are not perfect. Some are mere rough black spherules with no distinct crystal planes. Others show one lustrous face, usually at the top of the spherule, while still others show combinations of several faces belonging apparently to flat rhombohedrons or to combinations of rhombohedrons with the basal pinacoid. Sketches of some of these faceted spherules are shown in figure 9. The crystal faces have the splendent luster of specularite. In the workings of the same lease minute specks of iron oxide occur distributed through a massive fine-grained, sandstone-like aggregate of alunite. The specks give a red streak when the material is picked or struck, and may be hematite. Turgite (2Fe203.H20) has a similar streak, however. A similar oxide occurs with jarosite or alunite on the south slope of Myers Mountain. The particles show no crystal form under the microscope and it is not pos- sible to determine whether they are hematite or turgite, or, possibly, gothite. A similar mixture of red iron oxide with alunite and F,GUke 9,-Spherules of hematite with crystal facets; X300. native g°ld foI"mS Part °f tlle OTe °f the Simmerone mine. In the Lone Star mine, alunite, red oxide of iron, and quartz in small rough doubly terminated prisms form soft sandy aggregates. RUTILE. Rutile (TiO,) forms microscopic crystals with alunite, quartz, and sulphides in some of the altered dacite of the Combination and Florence mines. It is probably distributed sparingly through much of the alunitized rocks of the district as an alteration of titanite or ilmenite by ore-depositing solutions. DIASPORE. The hydrous oxide or basic hydrate of aluminum, AIO(OH), crystallizing in the ortho- rhombic system as the mineral diaspore, has rarely been noted in connection with ore-bearing veins. It is a characteristic alteration product of corundum, and its best-known occurrences in this country are in the intensely metamorphosed rocks of Chester, Mass., Chester County, Pa., Macon County, N. C, and near Trumbull, Conn. According to Van Hise,° biotite, gibbsite, haiiynite, muscovite, nephelite, noselite, phlogopite, scapolite, and sodalite, as well as corundum, may all give rise to diaspore in the belt of weathering. Diaspore was found by Cross b associated with alunite, quartz, and kaolin in the altered rhyolite of the Rosita Hills, Colorado. It occurs also with quartz and kaolinite in altered latite in the Silverton district, Colorado/ These occurrences in altered volcanic rocks in Colorado led to a search for diaspore in the alunitic and kaolinitic rocks of Goldfield. The mineral proved to be rather widely dis- tributed as a microscopic constituent, although not present in great quantity at any one place. a A treatise on metamorphism: Mon U. S. Geol. Survey, vol. 47, 1904, p. 232. b Geology of Silver Cliff and the Rosita Hills, Colorado: Seventeenth Ann. Rept. U. S. Geol. Survey, pt. 2, 1S96, pp. 316-317. c Ransorne, F. L , Economic geology of the Si rverton quadrangle, Colorado: Bull. U.S. Geol. Survey No. 182, 1901 (reprinted in 1903), pp.121-124. MINERALOGY. 125 It has been found with alunite and kaolinite in Sandstorm rhyolite near the Sandstorm mine; in altered rhyolite from the west slope of Vindicator Mountain; with quartz, alunite, and a little rutile and sericite in altered dacite on the south slope of Preble Mountain; and with alunite, quartz, and pyrite in altered dacite from the Florence mine. In the last-named place, the pyrite, alunite, and diaspore are intimately crystallized together and are clearly of con- temporaneous origin. Diaspore occurs in the Goldfield rocks as rounded, colorless, anhedral grains which rarely exceed 0.5 mm. in greatest diameter. These have one well-marked cleavage which is parallel to the plane of the optic axes. Sections transverse to the cleavage give a biaxial interference figure. The optical character of diaspore is positive, but owing to the large optic angle (over 84°) it is not always clear when dealing with small irregular grains whether the interference figure obtained corresponds to the acute or the obtuse bisectrix. Consequently attempts to determine the optical character from interference figures are likely to yield negative results on some grains and positive on others." The index of refraction of the Goldfield mineral is about 1.7 and the birefringence is such as to give green, yellow, and red of the second order in sections about 0.02 millimeter in thickness, thus corresponding closely to y — a = 0.048, the figure given for diaspore in Michel Levy and Lacroix's table of birefringences.fc The optical properties leave little doubt of the identity of the mineral with diaspore. Additional assurance, however, is afforded by tests by Mr. Schaller in the United States Geological Survey chemical laboratory. He pulverized the rock from the Florence mine, and after removing the pyrite treated the powder with hydrofluoric acid. The undecomposable residue was microscopically examined and found to consist of particles of the mineral under investigation. These proved to have the chemical composition of diaspore. LIMONITE. The common brown or yellow hydrous oxide of iron (2Fe203.3H20) is present in varying quantities in practically all of the oxidized ores of the Goldfield district and is the most char- acteristic product of the weathering or oxidation of pyrite. As pointed out on page 124, it is sometimes mixed with hematite and it is not always possible in any given ferruginous mixture to determine exactly what proportions of the various hydrated oxides are present. Limonite as a rule is more abundant in ores having dacite or andesite for country rock than in those inclosed by rhyolite. This difference is partly accounted for by the fact that the oxidized dacitic and andesitic ores were originally more pyritic in consequence of the larger quantity of iron available in the femic minerals of these rocks than in the more siliceous rhyolites. As indicated on page 181, the pyrite of the Goldfield ores has not been introduced bodily as sulphide of iron by the ore-bearing solutions, but has to a great extent been generated by the attack of sulphurous waters upon iron silicates already present in the rocks. The limonite of the Goldfield ores is generally earthy and mixed with kaolin, quartz, alunite, and other impurities. Often it is a mere rusty film on fragments of ledge matter. In a few places, as in some nearly horizontal seams on the 50-foot level of the Watson lease on the Florence claim, nearly pure limonite forms spongy masses suggestive of bog ore. One of the most characteristic and conspicuous occurrences of limonite in the Goldfield district is that of thin coatings on the surfaces of some of the siliceous outcrops of the ledges. Such coatings are exceptionally well developed on the hilltops just east of the Blue Bull mine and on Banner Mountain, but may be observed at many other places. The films are in some places dark steel gray with rounded, highly lustrous and finely botryoidal surfaces. In other places they exhibit gorgeous iridescence, the play of colors, due to the refraction of light by thin films, ranging from deep blue through purple, crimson, and orange to bright green. These films envelop loose fragments of the croppings or cover the surface of rock in place as brilliant expanses sometimes several square feet in unbroken extent. « A supposed negative mineral resembling diaspore, referred to in an earlier paper (The association of alunite with gold in the Goldfield district, Nevada: Econ. Geology, vol. 2, p. 673), turns out to be diaspore in which the obtuse was mistaken for the acute bisectrix. 6 Les mineraux des roches, Paris, 1888. Reproduced also in Idding's Rock Minerals, New York and London, 1906. 126 THE GEOLOGY AND ORE DEPOSITS OF GOLDFIELD, NEVADA. Such extensive coatings are often visible on the walls of joints which have gaped in consequence of the partial undermining of the siliceous croppings by the erosion of the softer country rock around and under them. The iridescent limonite films are not confined to surface exposures, but occur in the oxidized ore of some of the mines, including the January and Combination. The Columbia Mountain No. 1 tunnel, on the east side of the mountain, extends for 300 feet through shattered Cambrian sediments in which the fragments are encrusted and cemented by iridescent botryoidal films of iron oxide. The material of many of these films has a red streak and gives off less water in a closed tube than does ordinary limonite. It is probable that it consists in part of hematite, with per- haps some admixture of the hydrous oxides gothite, turgite, or limonite. CALCITE. The common rhombohedral carbonate of calcium (CaC03) is not an abundant mineral in the Goldfield district, and is absent, so far as is known, from the ore deposits. Veins of yellowish, massive, and impure calcium carbonate, carrying a little oxide of man- ganese and small vugs and veinlets of clear crystalline calcite, traverse the beds of the Siebert formation on the west slope of Myers Mountain. They apparently contain neither sulphides nor gold and are probably later in age than the ore deposits. Similar veins occur in dacite, about a mile southeast of McLaughlin's well. Some of the material is porous and rusty, and the vein may prove to contain pyrite at greater depth. Calcite serves as cement for some, of the tuffs and conglomerates of the Siebert formation, and is a microscopic constituent of some of the propylitically altered andesite, latite, and dacite, as an alteration product of feldspar and augite. It occurs also as amygdules in some of the basalts and in interstices between the crystals in the same rocks. In the basalts the presence of calcite is not necessarily connected with noticeable decomposition of the primary minerals, and it is evident that in these rocks carbonate of calcium can be deposited in vesicles and miaro- litic cavities within a comparatively short time after the solidification of the lava. Calcite is also a microscopic constituent of alunitized rhyolite on the east slope of Vindicator Mountain. This is the only rock in which calcite and alunite have been found together in this district, and the association is probably not common. Its significance is discussed on page 194. FELDSPARS. The pseudomonoclinic potassium feldspar orthoclase (KAlSi308) is an important constit- uent mineral of the alaskite. In this rock it is usually microscopically intergrown with albite in the form of perthite. As the clear variety known as sanidine it is abundant in the younger rhyolites. In the older rhyolites, such as those of Columbia and Vindicator mountains, it has been extensively altered to alunite. It does not always succumb to alteration in these rocks as readily as might be expected, however; a facies of the Morena rhyolite northwest of the Conqueror mine still contains much fresh sanidine, although the rock is full of secondary quartz and the original quartz phenocrysts show broad optically continuous accretions of the same mineral. The most abundant calcium-sodium feldspars in the district are those ranging from andesine to anorthite. The anorthite occurs in the olivine basalt, and labradorite is the principal species in the dacite and andesite, and probably also in the latite, although the feldspar in the last- named rock is never fresh. In the vicinity of the ore deposits the feldspars are invariably decomposed and have given rise to aggregates of alunite, kaolinite, quartz, pyrite, and diaspore. In the propylitically altered rocks they have usually been changed to calcite and quartz. EPIDOTE. Epidote, a somewhat complex basic orthosilicate of calcium, iron, and aluminum (HCa2 (Al,Fe)3Si3013) crystallizes in the monoclinic system and has a characteristic yellow-green color. MINERALOGY. 127 It occurs at Goldfield with calcite, chlorite, and pyrite as a microscopic constituent of propy- litically altered dacite, andesite, and latite, particularly as an alteration product of augite and biotite. It is not present as a rule in the immediate vicinity of ore, but is best developed in the greenish altered dacite northeast of McLaughlin's well. In some of these rocks the aggregates of epidote pseudomorphous after the original femic minerals are visible with the naked eye. Where formed at the expense of biotite, the epidote usually occurs in lenticular lamella? alter- nating; with chlorite. MUSCOVITE (INCLUDING SERICITE). *& The white potassium mica (H2KAl3Si3012) occurs very sparingly in some of the alaskite, apparently as an alteration product of biotite and usually associated with epidote. The fine scaly variety known as sericite, abundant in close association with some of the largest and most important classes of gold-quartz veins, is rare in the Goldfield district, and its occurrence is sporadic and exceptional rather than characteristic. It is found with quartz at the Goldfield-Belmont mine and imparts a pale-green tint to that mineral. As a subordinate microscopical constituent it is present with alunite in altered dacite from the south slope of Preble Mountain. It occurs also as an alteration product of feldspar in pyritized andesite near the Florence mine. KAOLINITE. The hydrous silicate of aluminum known as kaolin or kaolinite (Al203.2Si02.2H20) crys- tallizes in the monoclinic system, but commonly occurs in soft, white massive form, in which the individual crystals are too minute for the recognition of crystal form, even under the microscope. Kaolinite is abundant in the Goldfield district, particularly in oxidized ores. It is not confined to the belt of weathering, however, but occurs also in the sulphide zone and as a con- stituent of unoxidized country rock in the vicinity of the ore bodies. The dacite from the 230-foot level of the Combination mine, of which an analysis is given on page 181, contains, for example, 24 per cent of kaolinite by weight. In such altered rocks the kaolinite forms very minutely crystalline aggregates of feeble birefringence as seen in thin section under the microscope. These aggregates have rather ill-defined boundaries and the kaolinite is inti- mately and contemporaneously crystallized with quartz, alunite, and pyrite. A very large part of the altered dacite in the vicinity of the ore bodies near Goldfield consists of these four minerals in varying proportions. A similar alteration has affected the latite penetrated by the workings west of the shaft on the bottom level (280-foot) of the January mine. Specimens from a zone of mineralization in this rock consist of quartz, kaolinite, and pyrite. In the Goldfield-Belmont mine dull-white, fine-grained aggregates of quartz and kaolinite, associated with gypsum and pyrite, form veinlets in altered andesite below the level of oxida- tion. In parts of the ledges, in the sulphide zone, particularly in the Combination and Florence mine, kaolin and pyrite form irregular bunches, such material as a rule being of little or no value as ore. With alunite, quartz, and a little diaspore, kaolinite occurs in altered rhyolite in the vicinity of the Sandstone ledge, and with quartz, alunite, and a little calcite in rhyolite on slopes of Vindicator Mountain. The occurrence of kaolinite with alunite in the Common- wealth No. 3 lease has been described on page 130. Within the oxidized ores, kaolinite is sometimes very abundant. It occurs in soft pulver- ulent condition, mixed with alunite and slightly colored with yellow oxide of iron, in the Com- bination mine. Similar impure kaolinic material, often gold-bearing, is present in most of the oxidized ore bodies near Goldfield. In some places, as in the Red Top mine, pure, white, waxy kaolinite forms irregular veins and masses in limonitic, oxidized ledge matter. In the oxidized ores of the Sandstorm and Kendall mines there is much soft white kaolinite associated with barite and native gold. BARITE. The orthorhombic sulphate of barium (BaS04) is abundant in the ore of the Sandstorm and Kendall mines associated with kaolinite. The crystals, which are occasionally over an 128 THE GEOLOGY AND ORE DEPOSITS OF GOLDFIELD, NEVADA. inch in length in the Kendall mine, are usually attached to silicified rhyolite, their free ends being embedded in the kaolinite. Some, however, are entirely surrounded by the latter mineral. The crystals are of simple tabular habit, being bounded by the unit prism (110) and the basal pinacoid (001). They are clear and colorless, with perfect cleavages parallel to the prism base. The association of the barite with kaolinite and oxidization in the Sandstorm and Ken- dall mines suggests that it may have been formed by the action of cold, percolating meteoric water. In much smaller crystals, barite occurs with kaolinite in the Commonwealth No. 3 lease, 2 miles east of Goldfield, and with alunite and pyrite in the Reilly workings. The cn*stals in both these places are barely recognizable with the naked eye. Tubular crystals up to 2 millimeters in length embedded in soft alunite with pyrite or marcasite occur in the ore of the Consolidated Red Top lease. As barite is known to form, independently of any thermal activity, in cavities in limestone and in boxes and pipes carrying certain mine waters, and as it is also deposited from the waters of both hot and cold springs,0 its mere occurrence throws little light upon the source of the solutions from which it was precipitated. GYPSUM. The monoclinic hydrous calcium sulphate (CaS04 + 2H20) occurs in various forms in the Goldfield district. About a mile southwest of Blackcap Mountain, near the Gold Crater road, are some super- ficial deposits mapped in Plate II. These are composed of very soft, porous, cream-colored material, somewhat resembling a light volcanic ash or some forms of impure diatomaceous earth. The deposits prove to be earthy gypsum and were probably formed by the evaporation of the waters of a spring now extinct or of some temporary pond in which was accumulated water rich in sulphate of calcium derived from the surrounding rocks. A deposit of similar material lies about half a mile (0.8 kilometer) east of Blackcap Moun- tain. Here the gypsum has a very porous fibrous structure strongly suggestive of the fragile frost crystals which may be seen sprouting from moist ground in winter. This also is probably a local spring deposit. In the form of clear crystals or broad plates of the variety known as selenite, gypsum is abundant at the surface along the outcrops of fissures, particularly along those accompanied by much crushed rock or gouge. Broad lustrous plates of the mineral may be obtained along the Columbia Mountain fault on the south slope of the mountain. Underground, gypsum is found in most of the mines, particularly in gouge seams and in soft crushed ground, some- times accompanied by marcasite. Its occurrence underground is not limited to the oxidized zone. It is found in the Goldfield-Belmont mine, on the 150-foot level, or 50 feet (15 meters) below the natural water level, crystallized with quartz and pyrite, and may be noted in small nests in the soft pyritized andesite or dacite of many prospecting shafts. The mineral forms small veins in altered andesite about three-fourths mile (1.2 kilometers) northeast of Myers Mountain. It also occurs in seams in partially oxidized ore on the 50-foot level of the Jumbo mine. Gypsum is not a conspicuous or characteristic constituent of the Goldfield ores, but the mineral is widely distributed over the district and occurs near the surface in connection with all the Tertiary rocks with the possible exception of the rhyolitcs and the fresh olivine basalt. MELANTERITE. Natural ferrous sulphate (FeS04 + 7H20) or iron vitriol forms in small quantities in the lower part of the zone of oxidation by the oxidation of pyrite and marcasite. It was noted as bluish-green veinlets on the 130-foot level of the Combination mine and as a silky white efflor- aHeadden, W. P., The Doughty springs: Proc. Colorado Sci. Soc, vol. 8, 1905, pp. 1-30. MINERALOGY. 129 escence in the unused workings of the Vernal mine, now part of the Goldfield-Belmont. The normal color of the salt is green, but it loses water on exposure and turns white. The material assumes its original color on moistening. CHALCANTHITE. Hydrous cupric sulphate (CuS04 + 5H20) is sparingly present in some places near the base of the oxidized zone. It may readily be distinguished underground from melanterite by taking up a particle on a bright moistened knife blade. If any chalcanthite is present a film of copper will at once be deposited on the steel. HALOTRICHITE. White or slightly yellowish fibrous incrustations, having the astringent taste common to the alum group, occur in some of the mines near Goldfield, particularly in disused workings above the water level. Such efflorescent crusts were observed in abundance on the 190-foot (intermediate) level of the January mine in 1905. Samples of the mineral collected at that time were found by Mr. W. T. Schaller to contain sulphuric acid and much ferrous iron, but no potassium, and to correspond in other respects to halotrichite (FeO.Al203.4S03 + 24H20), a monoclinic or triclinic member of the alum group. The potassium alum, kalinite (K20.A1203.4 S03 + 24H20), is also a mineral likely to occur in deposits originally containing much alunite, but it has not been definitely recognized in the Goldfield district. Alunogen (A1203.S03 + 18H20) is another mineral of probable although not yet demonstrated occurrence in this locality. ALUNITE. The hexagonal (rhombohedral) hydrous sulphate of potassium (K20.3Al203.4S03.6H20),a known as alunite or, in massive form, as alumstone, is so abundant in the Goldfield district and so generally associated with the intense alteration of the rocks in the vicinity of the ore bodies that it must be regarded as one of the most characteristic minerals of the gold deposits. It is not limited, however, to the immediate vicinity of the ore deposits, but, as will be shown in the chapter on metasomatism, occurs in practically all of the Morena rhyolite, in the rhyolite about Vindicator Mountain, in the dacite and andesite of Preble Mountain, and elsewhere. Alunite occurs at Goldfield chiefly in two forms: (1) as a soft, white or slightly pink mate- rial, closely resembling kaolinite, and like that mineral filling cavities in ledge matter or ore, and (2) as an integral constituent of altered rocks. In the earthy, massive form, alunite is very abundant in the January and Combination mines, where it plays much the same part in the sulphide zone that kaolin does in the oxidized zone. It has been found in considerable quantity also in the Lone Star mine and in leases on the Commonwealth claims, about 2 miles east of Goldfield, and is probably not entirely absent from any of the ore bodies in dacite. In the Combination mine much of the interstitial material between the nodules of rich native gold and sulphide ore near the 230-foot level is alunite. As a rule, the pure massive alunite can be distinguished from the pure kaolinite by a faint pink tint. The crystallinity of alunite, too, is usually greater than that of kaolinite, and examination with a hand lens shows tiny crystal faces with pearly luster. The texture of kaolinite on the other hand is normally too fine to show crystal planes, even under the microscope, and with a hand lens it appears uniformly dull and earthy. Inasmuch as alunite is a sulphate, its distinction from kaolinite or sericite may readily be made by simple chemical tests. While alunite is not entirely absent from the completely oxidized ores, most of the soft white material found filling crevices in the weathered zone has proved to be kaolinite. Kaol- inite and limonite often occur together, but the association of alunite with an oxide of iron is a Or, as written by Hille'oraud and Penfield in Bull. U. S. Geol. Survey No. 262, 1905, p. 38, K2 [Al(OH)2] s [SO*]i. 79145— No. 66—09 9 130 THE GEOLOGY AND OEE DEPOSITS OF GOLDFIELD, NEVADA. comparatively rare. Kaolinite and alunite occur together, however, in some of the oxidized ore of the Combination mine. The material is pulverulent and slightly yellow, the color being perhaps due to the presence of some jarosite, a mineral isomorphous with alunite, but differing from the latter in containing iron instead of aluminum." The massive alunite in many places, particularly in the Combination mine, contains abundant small, embedded crystals of pyrite. A somewhat unusual occurrence of massive alunite was observed in 1905 in a 95-foot shaft on the Commonwealth No. 3 lease, about 2 miles (3.2 kilometers) east of Goldfield. The country rock is silicified latite. This has been irregularl}' fissured and the fissures and irregular interstices are filled with faintly pink alunite, within which are embedded spherical nodules of snowy kaolinite ranging in size from that of a pea to that of a small marble. In the Dixie mine, on the west slope of Preble Mountain, massive alunite, winch in some places is very compact, with almost the texture and hardness of some varieties of opal, is abundant on the 110-foot level, filling fissures and irregular crevices in porous silicified dacite. The most coarsely crystalline form of the mineral found is in an irregular veinlet,. from a half to 3 inches (1.2 to 7.6 centimeters) in width, in altered dacite on the northeast slope of Preble Mountain. This material, as exposed at the surface, is a buff-colored aggregate of platy, irregular crystals, and resembles some forms of coarse dolomite. The greatest interest attaches to the alunite as a rock constituent. Attention was first directed to its occurrence in this form by the finding of small nests or crystalline aggregates, up to 5 millimeters in diameter, of a pale-pink mineral in a greatly altered nearly white rock exposed on the east shoulder of Vindicator Mountain, about 2 miles northeast of the town of Goldfield. The rock contains quartz phenocrysts and was probably originally a rhyolite. The microscope shows that the feldspar phenocrysts, as well as the groundmass, have been altered to an aggregate of quartz and alunite, the optical determination of the latter mineral being checked by chemical tests in the United States Geological Survey laboratory by Mr. George Steiger. With the alunite is associated a subordinate quantity of diaspore. Microscopical study of the bleached altered rocks of the district soon showed that alunite is present in nearty all of them. The rlryolite forming the summit of Columbia Mountain, just north of the towns of Goldfield and Columbia, has been altered to a quartz-alunite rock, the alunite with some quartz forming pseudomorphs after the feldspar phenocrysts, which prob- ably were originally orthoclase. Alunite is very abundant in the altered andesite and dacite of Preble Mountain and vicinity, and is present, down to the deepest workings, in practically all of the altered dacite which forms the country rock of the Mohawk Combination, Florence, January, Red Top, Jumbo, and other mines near Goldfield. Its characteristic appearance in thin sections is illustrated in Plates XXVIII, XXIX, and XXX. It is also abundant directly associated with the sulphide ores in these mines, and is in mairy cases intercrystallized with pyrite, as shown in Plate XXIX, D. As a constituent of altered rocks in the Goldfield district, the alunite does not have com- plete crystal form. It is usually tabular in habit, the basal pinacoid being well developed and the rhombohedral faces being absent or indistinct. In thin sections (see plates above referred to) it shows distinct cleavage parallel to the basal pinacoid and parallel extinction with reference to the cleavage. The birefringence is apparently rather stronger than the difference y— a = 0.018 given in the table of Michel Levy and Lacroix,6 the interference colors in good thin sections being mostly 3'ellow, but rising in places to red or blue of the first order. The mineral gives a positive uniaxial interference figure in sections showing no cleavage. The index of refraction is distinctly higher than the balsam of the slide (1.54), that given for the alunite of Tolfa being u>= 1.572 and e= 1.592.c In some thin sections alunite might, on superficial examination, be mistaken for sericite. The latter mineral, however, has higher double refraction with the color mottling character- istic of the micas, has finer cleavage, and is optically negative. The difference in optical orien- a See Uillobrand, W. F., and Penfield, S. L., Some additions to the alunite-jarosite group of minerals: Bull. U. S. Geol. Survey No. 202, 1905, pp. 32-41. 6 Les mineraux des roches, Paris, 1888. Also Iddings, J. P., Rock minerals, New York and London, 1906. c Iddings, J. P., op. cit., p. 476. MINERALOGY. 131 tation is most quickly detected by the use of gypsum plate or quartz wedge. In alunite the higher colors appear when the basal cleavage is parallel to the direction of greatest elasticity in the plate or wedge. In sericite the higher colors occur in the transverse position. The minerals most commonly associated with the alunite as constituents of the altered rocks are quartz and pyrite. Some of the andesite on the south slope of Preble Mountain has been altered to a nearly white, fine-granular aggregate consisting almost wholly of quartz and alunite. The altered dacite forming the country rock of the Goldfield group of mines consists of quartz, alunite, pyrite, and kaolinite in various proportions. In many varieties of the rock these minerals are accompanied by small quantities of diaspore. The gold, famatinite, bismuthinite, and other constituents of the richest ore are generally inclosed in quartz, not alunite. The latter mineral, however, frequently occurs in the same microscopical section less than a millimeter distant from the metallic minerals. In ore from the Jumbo-Extension mine, near Diamondfield, alunite and a telluride of gold are crystallized together, as was found by the microscopical study of thin sections. Calcite and alunite do not ordinarily occur together, but microcrystalline calcite, a little sericite, and probably some kaolinite have been found associated with much larger crystals of alunite in an altered rhyolite from the east slope of Vindicator Mountain. The molecular ratio of soda to potash in this alunite, as determined by Doctor Hillebrand, is as 40 to 45. It is possible, however, that the result obtained for potash may be high in consequence of some decomposition of the sericite by the sulphuric acid used to dissolve the alunite. The occurrence together of alunite and calcite, apparently developed simultaneously, shows that the alteration took place under conditions which did not permit the free escape of carbon dioxide. It is scarcely conceivable, for example, that calcite could form in the pres- ence of sulphuric acid percolating down from an overlying deposit of oxidizing pyrite. As shown above, part of the alunite contains considerable sodium, and the calculations of the mineralogical compositions of some of the altered rocks from their chemical analyses, as will appear in the following chapter, indicate that most of the mineral occurring in the Gold- field district is not the pure potash salt, but is intermediate between alunite proper and natro- alunite.a Alunite differing in habit from most of the mineral thus far found near Goldfield occurs in the Hat lease on the Blue Bull Mining Company's ground, 1| miles (1.4 kilometers) east of Goldfield. The country rock here is andesite. This has been locally brecciated and the frag- ments are silieified. Between the fragments, and cementing them together, is much bright red hematite, which in the croppings is partly changed to limonite. The workings when vis- ited were only about 50 feet (15 meters) deep and the hematite extends at least to that depth. Occurring as irregular bunches and streaks in this hematitic breccia is much soft, fine- grained material of light-gray color with irregular reddish gray bands. In texture this mate- rial resembles a fine sandstone. It is firm, but can be crumbled between the fingers, and gives a reddish streak when struck with a pick. Under the microscope the powdered material proves to be made up of small, sharply bounded, colorless crystals, the largest being less than 0.03 millimeter in diameter. The crys- tals are apparently octahedral, but in reality are probably combinations of a rhombohedron and basal pinacoid. They are doubly refracting and can not, therefore, belong to the isometric system. Chemical tests by Mr. W. T. Schaller show the presence of alkalies and sulphuric acid, and the mineral is without much doubt alunite, natroalunite, or an intermediate variety of this isomorphous group. The crystals are associated with microscopic rosettes of hematite, the latter giving the red streak when the material is scratched. Such ore as had been sacked for shipment at the time of visit consisted mainly of this alunitic material. The mineral is also abundant, with sulphur in altered rhyolitic pumice, near Cuprite, 12 miles south of Goldfield. a Hillebrand, W. F., and Penfield, S. L., op. oit., p. 38. 132 THE GEOLOGY AND ORE DEPOSITS OF GOLDFIELD, NEVADA. As alunite is still a comparatively rare mineral, as it has not been recognized hitherto as an important mineral in ore deposits, and as its presence with the rich ores at Goldfield sug- gests problems of great interest connected with the genesis of epigenetic ores, some reference to other occurrences and to opinions held as to the origin of the mineral may not be amiss. Alunite was first noted at Tolfa, near Rome, where it was used as early as the fifteenth century for the manufacture of potassium alum (K,O.Al203.4S03.24H20).a This salt, con- taining 2 parts less of A1203 with 18 parts more of water, is obtained from the alunite by roasting and lixiviation. The mineral is found also on some of the islands of the Grecian Archipelago, near Muszay in Hungary, on Mount Dore in France, and in a few other localities in Europe, as well as with the. opal of Queretaro, in Mexico. In the United States it has been described in the Rosita Hills,6 on Calico Peak, near Rico,c in the National Belle mine near Silverton,** and at Cripple Creek/ all in Colorado. It occurs also at Tres Cerritos, Mariposa County, CaU W. Lindgren ° found alunite in the Ryerson mine near Morenci, Ariz., associated with pyrite and kaolin. He regarded it as formed by the attack of descending sulphuric acid solutions upon sericite away from free oxygen. In Nevada alunite has been described by G. I. Adams'1 as associated with sulphur and cinnabar at the Rabbit Hole mines, and by S. H. Ball as in a silici- fied rhyolite of the Cactus Range, east of Goldfield.1 Until recently, geologists and mineralogists have regarded alunite as formed exclusively by the attack of sulphurous fumarolic vapors upon feldspathic rocks, i At Cripple Creek, how- ever, the mineral was found only in the oxidized ore, and, like the kaolinite of that district, is probably secondary with reference to the original telluride ores. De Launay,^ moreover, has recently maintained with cogency that the alunite of Tolfa is probably not, as commonly supposed, a solfataric product, but is due to the action of percolating surface water, charged with sulphuric acid by the oxidation of pyrite, upon a particularly feldspathic facies of the trachyte. It is accordingly no longer justifiable to regard the occurrence of alunite as proof of former fumarolic activity. The mineral may form under very different sets of conditions, and it is necessary in seeking the explanation of any occurrence of it to keep alternative hypotheses in mind. In all four of the Colorado localities the alunite occurs in regions which contain ore deposits. In the Rosita Hills and in the Rico and Silverton districts it is apparently not a product of super- ficial oxidation. No close kinship between this mineral and the ores, however, has been shown, although it was doubtless recognized by all the workers in those districts that there might be some genetic relation between the metallic sulphides and the volcanism of which the sporadic solfataric metamorphism of feldspathic rocks to quartz-alunite aggregates was one manifestation. It is worth noting in this connection that the indexes of two of the best and most recent works' on ore deposits contain no reference to alunite, showing that the mineral has not been commonly recognized as one intimately associated with ores. Neither is it mentioned, so far as I am aware, in C. R. Van Hise's work on metamorphism.™ J. H. L. Vogt,™ however, in discussing metaso- a For the latest account of this celebrated locality, with a bibliography, see De Launay, L., La metallogenie de 1'Italie. X. Geol. Cong., Mexico, 1906, pp. 125-132. >> Cross, Whitman, Geology of Silver Cliff and the Rosita Hills, Colorado: Seventeenth Ann. Rept. U. S. Geol. Survey, pt. 2, 1896, pp. 52-56; also Am. Jour. Sci., 3d ser., vol. 41, 1891, pp. 466^17.5. c Cross, W., and Spencer, A. C, The geology of the Rico Mountains, Colorado: Twenty-first Ann. Rept. U. S. Geol. Survey, pt. 2, 1900, pp. 92-94. d Hurlbut, 10. B., On alunite from Red Mountain, Ouray County, Colorado: Am. Jour. Sci., 3d ser., vol. 48, 1894, pp. 130-131. Also Ransome, F. I.., A report on the economic geology of the Silverton quadrangle, Colorado: Bull. U. S. Geol. Survey No. 182, 1901. ' Lindgren, W., and Ransome, F. L., Geology and gold deposits of the Cripple Creek district, Colorado: Prof. Paper U. S. Geol. Survey No. 54, 1906, p. 125. / Turner, II. W., Rocks and minerals from California: Am. Jour. Sci., 4th ser., vol. 5, 1898, pp. 424-426. g The copper deposits of the Clifton-Morenci district, Arizona: Prof. Paper U. S. Geol. Survey No. 43, 1905, pp. 119-120, J69, 193-194. h Adams, G. I., The Rabbit Hole sulphur mines near Humboldt House, New: Bull. U. S. Geol. Survey No. 225, 1904, p. 500. i Ball, S. II., A geologic reconnaissance in southwestern Nevada and eastern California: Bull. U. S. Geol. Survey No. 308, 1907, p. 48. ; Cross, W., Geology of Silver Cliff and the Rosita Hills, Colorado: Seventeenth Ann. Rept. LT. S. Geol. Survey, pt. 2, 1890, p. 314. Cross, W., and Spencer, A. C, Geology of the Rico Mountains, Colorado: Twenty-first Ann. Rept. V. S. Geol. Survey, pt. 2, 1900, p. 33. Iddings, J. P., Rock minerals, New York, 1906, p. 476. Hillebrand, W. F., and Penfield, S. L., op. cit., p. 40. * Op. cit. I Beck, Richard, Lehre von den Erzlagerstiitten, Berlin, 1901. Stelzncr, A. W., and Bergeat, A., Die Erzlagerstatten, Leipzig, 1904-1906. m A treatise on metamorphism: Mod. r. S. Geol. Survey, vol. 47, 1904. n Problems in the geology ©fore deposits: Trans. Am. Inst. Min. Kng., vol. 31, 1902, p. 150. MINERALOGY. . 133 matic vein processes, has remarked: "I would mention also the formation of alum-stone, quartz- alunite rocks, quartz-diaspore rocks, etc., and also the formation of bauxites, etc. But I do not know that these changes have been anywhere observed in genetic relation with ore veins." JAROSITE. The mineral jarosite is closely related, chemically and crystallographically, with alunite. The formula of jarosite proper is K20.3Fe203.4S04.6H20 or K2[Fe(OH)2]6[S04]4 and the crystalli- zation, like that of alunite, is rhombohedral. As Hillebrand and Penfield" have shown, the potassium jarosite is merely one member of a series of which the other known members are natrojarosite, Na2[Fe(OH)2]6[SOJ4, and the remarkable plumbojarosite, Pb[Fe(OH)2]6[SOJ4. In view of the great abundance of alunite in the Goldfield district, it might be expected that some member of the related jarosite group would be not uncommon. Such expectation, how- ever, has not been fulfilled. It is not even certain that the mineral presently to be described is really jarosite. Half a mile south of Myers Mountain Mr. W. H. Emmons collected from the Siebert forma- tion a specimen of tuff which proved to be of unusual character. It has the general appearance of a yellowish, sandy tuff which weathers red on exposed sufaces. Like the material from the Hat lease, it gives a hematite streak. A thin section shows the rock to be a tuff in which the larger fragments are irregular cuspate particles of clear volcanic glass. The bulk of the material, however, is a friable mass of microscopic yellowish crystals. The crystals are sharply bounded, and when seen in the pulverized material under the microscope resemble octahedrons. They are not isotropic in all sections, however, and are probably combinations of a basal pinacoid with a rhombohedron, giving a pseudo-octahedral form similar to that sometimes assumed by the mineral coquimbite.6 The crystals are minute, rarely exceeding 0.025 millimeter in diameter. Their color is light yellow. Chemical tests by Mr. W. T. Schaller in the United States Geological Survey laboratory showed the presence of alkalies and sulphuric acid, so that the mineral belongs without much question to the alunite-jarosite series. The yellow tint and the tendency of the rock to redden on weathering indicate that the crystals contain iron, and that therefore they are probably jarosite or some variety intermediate between jarosite and alunite. A little scattered hematite occurs with the jarosite. The tuff has evidently undergone alteration as a result of which the finer particles of volcanic glass have been changed to an aggregate of jarosite or some closely related mineral. The alteration has only slightly affected the larger glass sherds, which, as a rule, still retain their characteristic clastic outlines. Some* of them, however, have been peripherally attacked, the glass being separated from the jarosite aggregate by finely jagged suturelike boundaries. Cracked or pumiceous fragments usually contain jarosite in the cracks or vesicles. There is no evidence that the tuff ever contained any notable quantity of pyrite, and the sulphide solutions which effected the metamorphism must have had their source outside of the rock itself. It is not improbable, as pointed out by W. F. IIillebrand,c that a yellow coating on some oxidized ore collected in the district by Spurr is jarosite. EMMONSITE AND DURDENITE. Both emmonsite and durdenite are greenish-yellow or yellowish-green minerals of obscure crystallization and somewhat uncertain composition. d They are essentially hydrous ferric tellurites, in which part of the tellurium may be replaced by selenium. The theoretical com- position of durdenite is Fe203.3Te02.4H20. a Some additions to the alunite-jarosite group of minerals: Bull. U. S. Geol. Survey No. 262, 1905, pp. 32-11. b See Dana, J. D. and E. S., System of mineralogy, 6th ed., New York, 1895, p. 956, fig. 2. c Bull. U. S. Geol. Survey No. 260, 1905, p. 137. d See Hillebrand, W. F., Two tellurium minerals from Colorado: Bull. U. S. Geol. .Survey No. 262, 1905, p. 56. 134 THE GEOLOGY AND ORE DEPOSITS OF GOLDFIELD, NEVADA. At Black Butte a greenish-yellow mineral belonging to this group occurs in the oxidized parts of the ore bodies, particularly in connection with good ore. It forms tenuous crusts, often little more than a stain, along cracks in the ore, or is implanted on the walls and cavities as thin rosettes, resembling lichen growths and showing minute fibrous crystallization. It is associated with free gold, limonite alunite, and perhaps kaolinite. The mineral was determined by Dr. W. F. Ilillebrand to be a seleniferous ferric tellurite. A canary-yellow variety, also seleniferous, occurs in similar thin incrustations and specks with limonite, cerargyrite, and native gold in the oxidized ore of the Gold Coin claim near Diamondfield. Other occurrences will doubtless be noted with the increase in mining develop- ment near Diamondfield. The mineral, as at Cripple Creek, results from the oxidation of ores containing tellurides. In the Gold Coin workings the original mineral is a telluride of gold of undetermined species. In Black Butte the parent mineral has not been recognized. CHAPTER XI. THE MINES: A GENERAL ACCOUNT OF THEIR DISTRIBUTION, DEVELOPMENT, AND OPERATION, INCLUDING ORE TREATMENT. DISTRIBUTION AND UNDERGROUND DEVELOPMENT OF MINES. The important mines of the Goldfiekl district will be considered in two areal divisions, which maybe conveniently designated the "Goldfield" and " Diamondfield " groups. Of these the first has supplied over 95 per cent of the output of the district and includes such well-known mines as the Mohawk, Combination, Florence, Jumbo, January, Red Top, and Sandstorm. The belt of productive mines of the Goldfield group sweeps from Kendall Mountain on the north in a gentle curve, concave to the northeast, past Columbia Mountain and Milltown, to a point about half a mile southeast of the latter settlement. It may be subdivided into a cluster of mines on the north, including the Sandstorm, Kendall, and Conqueror, which are in rhyolite; a very important aggregation northeast of Goldfield, which is mainly in dacite, and includes the Red Top, Mohawk, Combination, January, Jumbo, and part of the Florence mines; and, finally, some mines, principally lessee workings, east of Goldfield, in the Milltown andesite. The prin- cipal underground workings of the mines near Goldfield are shown in Plate IX, and the situation of most of the important leases may be seen from Plate X. The mines of the Diamondfield group are aligned along McMahon Ridge north of the town, and stretch from Black Butte on the east for a distance of about a mile to the west. These are mainly in the Milltown andesite. Although the positions of the mines are given on Plate I, some verbal and pictorial descrip- tion will perhaps help the reader to visualize the conditions at Goldfield and to follow with greater interest a presentation of the ore occurrences which necessarily falls far short of reality. On a quiet morning when the winds are not whirling clouds of desert dust through the town, one standing on Mira Mountain, about 1£ miles south of Goldfield, and looking nearly due north has before him the scene shown in Plate VI, B. The sharp peak conspicuous in the middle ground is Columbia Mountain. Southwest of it are the towns of Columbia and Goldfield, beyond which, to the north, shimmers the desolate valley followed by the railroad to Mina and Hazen. In the distant hills behind the mountain and a little to the left of its summit is Tonopah, 30 miles (48 kilometers) away. The buildings visible on the hill just west of Columbia Mountain are at the new 100-stamp mill of the Goldfield Consolidated Mines Com- pany, of which only the foundations were completed when the view was taken. Just beyond them, but not in sight, are the Sandstorm and Kendall mines. A little east of south from the mountain and over the small basalt-capped hill in the foreground are the principal mines of Goldfield, the mill and head frame of the Florence mine being almost in line with the summit of the intervening hill. The large white dump at the right-hand side of the picture is that of the Little Florence on the south side of Florence Hill. If, before leaving Mira Mountain for a nearer view of the mines, the visitor turn to the west he may look over the basalt top of Malpais Mesa (PI. XI, A) to Montezuma Peak, about 8 miles (13 kilometers) away. On the slope under the basalt may be seen exposures of the Siebert formation and in the middle ground the road from Goldfield to Lida and Rhyolite. Leaving Mira Mountain and walking north over the Siebert beds and Milltown andesite, which is covered in most places by soil and stony detritus, the visitor who approaches the Florence mine has the view shown in Plate XI, B. In the foreground is soil-covered Milltown andesite. The near dump to the left is that of the Black Eagle lessee shaft, 290 feet (88 meters) 135 136 THE GEOLOGY AND ORE DEPOSITS OF GOLDFIELD, NEVADA. deep, the last rock on the dump being the latite which underlies the andesite. The shaft just behind this dump is the Rosebud, on the O. K. lease, 500 feet (152 meters) deep. Beyond it is Florence Hill, crowned by the Little Florence shaft, 555 feet (169 meters) deep, with five short north-south levels and lateral crosscuts to shafts on each side of the hill. This is one of the famous Florence leases" and produced about $1,500,000 from ore in the Milltown andesite. Below the Little Florence dump, and in front of a dark ledge outcrop on Atlanta ground, is the 500-foot Rogers shaft on another rich lease block of the Florence-Goldfield Mining Com- panies' ground, and to the right of this are a number of shafts, most of them about 500 feet deep, which have been sunk in the hope of finding some continuation of the rich ore mined in the Little Florence and Rogers leases. Bej^ond and just to the left of the hill are the head frame and mill of the Florence mine. The visitor may now go to the top of Florence Hill and look northwest at the view shown in Plate XII, A. Near at hand to the right is the Florence head frame. This shaft is 350 feet (107 meters) deep, with levels running generally northwest and southeast. Two levels, the 150-foot and the 250-foot, are connected with the Reilly lease shaft, which appears in the middle ground, just to the left of the center of the picture. This was a profitable lease in the northwest corner of the Florence claim and produced ore to the value of nearly half a million dollars in 1905. On the hill above and to the left of the Reilly are the Combination mine and mill. The Combination shaft, 380 feet (116 meters) deep, is connected by extensive levels with the Reilly shaft, with the January, of which the disused head frame6 appears just beyond the Combination buildings, and with the Mohawk workings, which ramify through the low hill to the right of the valley in the middle ground. The top of the head frame of the Mohawk shaft, 600 feet (183 meters) deep, barely shows over the crest of this hill. The Mohawk has levels at 245, 350, 450, and 600 feet (74, 107, 137, and 183 meters). These connect with an irregular maze of lessees' workings, mostly above the 250-foot level, and extending over the greater part of the Mohawk No. 2 claim. In the valley to the right of the Reilly and in order from southeast to northwest are the Florence- Wheeler, the California-Florence, the Combination Fraction, and the Burns shafts. (See also PI. IX.) Beyond them, near the high trestle which leads to the Mohawk ore bins, are the dumps of the Hayes-Monnette and other famous lease shafts on the Mohawk ground. These shafts have been dismantled, and their dumps are being culled over and shipped. The largest dump visible on the south side of the Mohawk hill is that of the Loftus-Davis lease shaft on the Combination Fraction claim, which connects through stopes with the Mohawk workings. Below it and to the left of the Florence head frame is the Oddie shaft', 612 feet (186 meters) deep, also on the Combination Fraction. Concealed by the Mohawk hill and between it and Columbia Mountain are many lessees' shafts on the Mohawk and Gold Wedge claims and the main shaft of the Red Top mine. The most important lease on the Goldfield Wedge claim is the Mohawk-Jumbo, with a shaft 500 feet (152 meters) deep, and extensive stopes on the deeper part of the Mohawk ledge. Just north of it is the Mohawk Ledge shaft, 700 feet deep. The Jumbo mine, 500 feet deep, is at the extreme right of the view, concealed by the Florence head frame. The shaft is now dismantled, and the old workings will be undercut from the 600-foot Mohawk level and from the Goldfield Consolidated Mines Company's new Jumbo or Clermont shaft, 860 feet (262 meters) deep in January, 1909, which is about 1,000 feet (305 meters) north-northeast of the old Jumbo shaft. Beyond the Jumbo, to the north, are the Mushett (480 feet, or 146 meters, deep), Five Friends (560 feet, or 170 meters, deep), Hazel-Goldfield (740 feet, or 225 meters, deep), Mohawk-Red Top, and other leases on the ground of the Goldfield Consolidated Mines Company. The long dark building in the middle distance is the Goldfield Clc mill. If the- visitor, still standing on Florence Hill, will now turn to the east, he will see (PI. XII, B) just below him to the left the Florence-Annex shaft, 500 feet (152 meters) deep, through oThc word "lease" Is SO generally used In the district to designate not merely a contract but a mine worked by lessees that to avoid such use would savor of pedantry. I> Since removed. 'The company uses this, the chemical symbol of chlorine, In its corporate name. US GEOLOGICAL SURVEY GEORGE OTIS SMITH. DIRECTOR PROFESSIONAL PAPER 66 PLATE IX COMBINED PLAN OF UNDERGROUND WORKINGS OF THE PRINCIPAL MINES NEAR GOLDFIELD, NEVADA. PROFESSIONAL PAPER 66 PLATE X U. S. GEOLOGICAL SURVEY * / LANE LEASE / ^s^Ci* *Z»** «jjt GOLD CM # *? *T 8&* \<M>^ /6%: if^c I t o " I t -J w / | ^~~C_ XMOHAW|< GOLD BAR M AND "'V I CO.V | « /""us «v**\« X ,t,\ .«.«- * ^ v \ \\ \>^ \v& l°\\Vx t* \ %\ \ o"o\ 5 1 f \ j-^*=^p 'A' L-co.l H * J. T*Ny I ^ ■'MRDi; a <& & *L$P 0 I «/;», l< 8 '/I H a .#\4 ,^?Q <^.*-^v^-V ^°° . -V'NSTON / * ■ '-EA^E / DAISY *'■■ ■ -fc^r^"" -'XOS -=??^»^ ^3^ LEase | ^ET3 «t ^S | S I »p«uE ano ste,n") «.*,« AN0 UAS1NG I 5JP«IitM: 'DiE S**£ FRrCt. eO^I-: R13^ JEER SOA ""CnELL-r«,RrjELO LEASE 1 I 9 i3 t)J?t IONv BULL CONSOLIDATED 1,0' OKOU^ MAP SHOWING PRINCIPAL LEASE BLOCKS IN THE VICINITY OF GOLDFIELD. Based on John Hagel's lease map for May, 1908. U. S. GEOLOGICAL SURVEY PROFESSIONAL PAPER 66 PLATE X! 1,1 #^«^v 4. MALPAIS MESA; FROM MIRA MOUNTAIN. Beyond the mesa is Montezuma Peak, composed largely of beds belonging to the Siebert formation, formation shows also in the steep slope below the basalt cap of the mesa. The same B. FLORENCE HILL; FROM THE SOUTH. U. S. GEOLOGICAL SURVEY PROFESSIONAL PAPER 66 PLATE XII A. VIEWS FROM FLORENCE HILL. A, Looking northwest; B, Looking east. DISTRIBUTION AND DEVELOPMENT OE MINES. 137 which was hoisted rich ore from the Engineers' lease to a gross value of over $1,000,000. To the right is the group of board buildings known as Milltown, and beyond the railroad is the ridge with typical ledge croppings which extends eastward beyond Preble Mountain. Nearly all the shafts visible on this ridge are prospects on the ground of the Atlanta Mining Company. Most of them are from 300 to 500 feet (91 to 152 meters) deep, with short exploratory levels. About a quarter of a mile (0.4 kilometer) beyond the shafts on the extreme right are the Gold Bar and Victor mines, about 300 feet (91 meters) deep, which thus far have been the most easterly productive mines of this belt. In the distance are the high dacitic hills, just outside of the mapped area and southeast of Tognoni Springs. One who wishes further to overlook the district before examining the individual mines will do well to continue his walk northward and climb Columbia Mountain. Thence, looking southward, he may see Goldfield spread out, with the dark edge of Malpais Mesa behind it, and will see, a little east of the town, most of the mines visible from Florence Hill, with others which are concealed from that point by the hill southeast of the Mohawk mine. If the walk be extended northward along Morena Ridge, the Sandstorm and Kendall mines come into sight to the north- west (PI. XIII, A), and to the east is an uninterrupted view (PI. XIII, B) over lower country, underlain chiefly by Milltown andesite, to Black Butte and the town of Diamondfield. McMahon Ridge, seamed with trenches cut by prospectors, shows to the left of the town and butte. The Sandstorm shaft is 400 feet (122 meters) deep, but all the ore from this and the Kendall mine, most of which has been shipped by lessees, has come from superficial workings. The deepest shaft in the Diamondfield group is the Daisy, 400 feet deep. The lateral work in this group is not extensive. In the mines near Goldfield, on the other hand, it was possible in 1908 to travel underground from the north corner of the Mohawk No. 2 claim by way of the Combi- nation mine to the south end of the Florence claim, a distance of nearly 4,000 feet (1,219 meters), with the opportunity of making long detours in the mines passed through. The following reference list, which is intended to summarize the principal shaft develop- ment in the district and to aid the reader as a key to Plate I and in looking up details regard- ing any particular shaft, aims to include, with a few exceptions, only those of 200 feet (61 meters) or more in depth. Even as regards these it is not complete, as there are many abandoned shafts in the district of which the depths, not ascertainable, may exceed 200 feet. There are also many prospect shafts of less than 200 feet in depth scattered over the district. . Of these no account is taken. In general, the shafts listed are those whose positions are shown on Plate I. The depths and geologic information given were ascertained in July, 1908, although where later information has come to hand it has been used. The names listed are in most cases those by which the shafts are generally known rather than the official designations of the companies operating them. There is considerable confusion introduced into the naming of shafts through the practice by some lessee companies (for example, the Little Florence and PVances-Mohawk) of transferring their names from the original lease to other leases in different parts of the dis- trict. Some shafts also are known under more than one name, and changes in designation are not uncommon. The list illustrates well the remarkable energy that has been displayed in searching for the rich Goldfield ore bodies. These shafts alone, regardless of all drifting and crosscutting and of the numerous unlisted openings less than 200 feet (61 meters) deep, would, if put together, have a total length of over 80,000 feet (24.4 kilometers) ; they represent an expen- diture of about .$2,000,000. 138 THE GEOLOGY AND OKE DEPOSITS OF GOLDFIELD, NEVADA. Principal shafts in the Goldfield district. [A plus sign ( + ) in the column of depths indicates that sinking was in progress when the figure was obtained or that there is reason to believe that the shaft has since been deepened.] Name. Number on Plate I. Claim. Section. Depth in feet. Surface rock. Changes in general formation. Adams 67 316 80 158 76 292 275 277 25 5 28 36 29 1 1 1 300+ Sandstorm rhyolite Milltown andesite Into Morena rhyolite. lluntch Bell No. 4.... Copper Ledge Aloha Alta Velvet 418+ 200 300 500+ Milltown andesite Into latite above 300 feet. Johnson No. 1 Atlanta B. and M Black Bear Atlanta Boom Union Jack . .do Do Atlanta-Cherokee Black Bear Milltown andesite Some dacite near bottom. Atlanta, Original (see Original A.).. 260 257 234 40 128 24 35 204 45 39 48 231 266 306 307 140 47 219 223 29 271 245 107 157 30 150 298 168 212 229 221 26 173 152 196 137 66 165 294 123 151 126 28 32 23 256 Cornishman 1 1 1 20 36 19 20 33 20 20 20 1 1 6 6 36 20 1 1 19 1 1 35 36 20 36 1 36 2 1 1 19 36 36 31 36 25 36 1 36 36 36 19 20 19 1 400 375+ 300+ Baltimore Belle Bee Fraction Milltown andesite do Do Rustler Fraction Black Butte No. 2 Mohawk No. 2 Daisy Triangle Vernal No. 2 Into latite at 260 feet. Baumgarten do 200 150+ 150 Dacite . Do Belcher Milltown andesite do Do Belmont Do. Berlin Berlin Dacite Do. Black Butte Bonanza Black Butte Extension Black Butte No. 2 Daisy Milltown andesite do Do. Black Butte Consolidated Do. ...do.. Do Black Eagle Combination No. 3 Atlanta 290+ 320 100 do Into latite at 280 feet. Blake Dacite Blue Bull (old shaft) Pig do.. Do. Blue Bull (new shaft) do ...do.. Booth.. Booth.. .. 200+ 380 400 130 350 400 "526+ 920+ 300 500 380 400 431 do. Do. Bulldog Bulldog Fraction No. 2 Combination Fraction. Florence Milltown andesite Dacite Do. Burns Do. ...do Into latite (?). Daisy No. 2 Milltown andesite Dacite Century Union Jack Do. Red King Milltown andesite Do. Pipe Dream Chicago- Velvet Velvet Dacite Cleary Cleary Milltown andesite Dacite latite at 410 feet. Clermont Into latite at 615 feet. C. 0. D C. O. D Milltown andesite Dacite St. Ives Combination No. 2 August do feet. Milltown andesite Dacite Into latite at unknown depth. Combination i raction. Daisy No. 1 Sunflower Combined Milltown andesite Dacite Do. Do Do. Do... Curlv George do Do. Tokop 400 300 400 do Into latite at probably less than 100 feet. Consolidated Red Top Lease Red Top. ...do Crackerjack Morena rhyolite Dacite Kewana No. 3 Crown Fraction Mohawk No. 2 Jumbo do Curtis 365 do Do. Do . do Do. Gold Wedge do Do. Daisy No. 1 400 210 Milltown andesite do Do. Daisy No. 2 Do. Spokane do Do. Cornishman 320 do Into dacite. Daisy L. & M. (see Toplitz).. Daly West.... 4 293 75 58 69 320 179 Dix No. 2... 18 1 30 26 25 5 36 300 285 Milltown andesite Dacite Vindicator rhyolite Sandstorm rhyolite Milltown andesite Dacite ....do None. Gold Horn Angelus Do. Do. Desert Rose Do. Black Diamond Tin Horn Do. Dixie Do. 90 34 35 20 Siebert Into latite at unknown depth. Yucca No. 1 Milltown andesite None. 280 163 254 253 258 251 301 262 248 236 243 282 259 246 Atlanta 1 36 560 350 500 330 Milltown andesite Dacite Do. Last Chance Do. Florence Milltown andesite do Dacite Florence-Annex ( Engineers') Do. ...do Do. Firelight Milltown andesite do Do. Florence-C O D C. O. D.. Do. 320 500 450 345 250 •• Dacite Do. Red King Fraction No. 1. Rustler No. 2 Milltown andesite. . do do Into latite at unknown depth. None. Florence-Goldneld Red King Into latite between 350 and 400 .do do feet. Into latite, depth unknown. None. Red King Do. Florence L. and M. (see Little Flor- ence). 108 225 121 315 35 1 36 6 480 315 500 Siebert Do. Mohawk No. 2 Frances No. 1 do Do. U. S. GEOLOGICAL SURVEY PROFESSIONAL PAPER 66 PLATE XIII .4. SANDSTORM AND KENDALL MINES. From Morena Ridge, north of Columbia Mountain. K^^3£V:v«L3fc B. VIEW LOOKING EASTWARD FROM MORENA RIDGE TO DIAMONDFIELD AND BLACK BUTTE. The principal mines near Diamondfield are on the ridge extending from Black Butte to the trenched summit of McMahon Ridge (on the Teft). DISTRIBUTION AND DEVELOPMENT OF MINES. Principal shafts in the Goldfield district — Continued. 139 Name. Frisco. Fuller Garrison General Washington Gibraltar Gold Bar Gold Bar fraction Gold Bar M. and L Goldbug Gold Coin Do Gold Crown Golden Daisy Goldfield-Bu'llion Goldfleld-Columbia Mtn. Annex.. Goldfield-Dominion Goldfleld-Fargo Goldneld-Federal Goldfield Merger Goldfield M. & Ore Red. Co Goldfield-Red Hills M. & L Goldfield-Red King M. & L Goldfield-Rosebud (see Rosebud). Goldfleld-Tombov Goldfields-Chedd". Gold Hat Gold Horn (see Lewis) Gold Mountain Gold Sovereign Gold Star Goodfriends Gordon and Ostetter Gotwaldt Graham. . Grandma. Great Bend (old) Great Bend (new) Great Bend Annex Great Bend Diadem Great Bend Extension. Greater Nevada Hall- Florence Hat. Hayes-Monnctte No. 1 Hayes-Monnette No. 2 Hazel-Ooldfield Higginson Do Highland Hooper-Manning Imperial Do Iowa January January-White Rock (see White Rock No. 5). Jinks Jumbo Jumbo-Annex Jumbo Extension L. & M Jumbo Ledge Jumbo Ledge Lease Jumbo Wonder Jupiter Kalfus Kansas City Keane Keelyn G. & G Keelyn No. 0.. Keelyn No. 22. Kendall. Kett Ke wanas Laguna (old ) Laguna (new) Laymance Lewis Little Florence (Florence L.& M.) Little Florence (on Comb. Fr.). . . Liverpool Loftus-Davis. Do Lone Star Lucky Boys. . Los Angeles. . M.andH Mackenzie Number on Plate I. 138 268 291 68 228 300 304 299 2 33 218 93 22 202 94 7 290 79 305 288 249 232 05 252 78 Claim. Booth. Jumbo Black Bear Gen. Washington No. 2 Combination No. 3 Gold Bar Morning Fraction Gold Bar Goldbug Gold Coin ....do Daisy No. 1. Big Dyke. .. Deserted Watson C. O. D Mountain Rat Moonshine Wonder September Combination No. 3. Big Lize Emma Fraction. Gold Flat 287 198 289 193 41 220 31 180 10 15 10 17 19 72 242 308 110 119 101 131 74 49 281 273 312 1 210 195 269 133 149 265 270 154 0 127 297 12 283 155 59 279 102 144 140 272 274 241 222 284 122 61 189 182 111 92 117 Golconda Johnson No. 2 Gold Star Fraction. Silver Tip Holiday Fraction. . Combination No. 2. Daisy No. 2. Grandma. . . Great Bend No. 2. ....do Red Butte No. 1 . . Great Bend No. 1. Palace : Hesperian Red King Hat Mohawk No. 2 ....do Last Chance Gold Wedge Ruby Silver Dewdrop Black Bear Union Jack Mary January. Lono Star Jumbo Gold Wedge... Polverde Atlanta Grizzly Bear. . . Polverde Red Light Mohawk No. 2. C. O. D Great Bend Zoe Polverde. Zoe Kendall. Red King Kewana No. 2 Miss Jessie do Atlanta Moonshine Red King Combination Fraction Golconda Combination Fraction Sandstorm Patrick Lucky Boy Deserted Silver Pick Mohawk No. 2 Section. 30 1 1 25 1 1 1 1 13 20 2 35 19 33 35 23 1 28 1 1 1 1 25 1 29 1 32 1 31 20 1 20 36 19 19 19 19 19 30 1 0 36 36 36 36 30 20 1 1 6 15 2 31 1 36 36 1 1 36 23 36 1 19 1 36 1 20 1 36 36 36 1 1 1 1 1 36 26 31 36 35 35 36 Depth in feet. 150+ 200 300+ 350+ 300 475+ 150 420 500 415 600 350 300 213 300+ 100 300 400 300 400 250 270 740 320+ 375 2*0 500 350 270 300 500 Surface rock. Dacite. ....do ...do Milltown andesite. ....do ....do ....do ....do ....do ....do ....do Latite Milltown andesite. Dacite Latite Milltown andesite. ....do ....do Dacite Milltown andesite. ....do ....do Sandstorm rhyolite. Milltown andesite.. ....do Mdltown andesite. . . Sandstorm rhyolite. Milltown andesite. . . Dacite Milltown andesite... ....do ....do. Dacite. Milltown andesite. . ....do ....do ....do ....do Vindicator rhyolite. Milltown andesite. . ....do Dacite do do ....do Vindicator rhyolite. Dacite Milltown andesite.. Dacite ....do Siobert Dacite Dacite do ....do ....do ....do ....do do Milltown andesite. Dacite Milltown andesite. do do 408 368 500 400 500 600 420+ 531 250 100 360 300 300 Dacite Milltown andesite. Sandstorm rhyolite. Milltown andesite. Dacite ...do ....do do ....do Milltown andesite. Dacite Milltown andesite. . . Dacite Sandstorm rhyolite. Dacite , Cambrian shale Dacite Latite Dacite , Changes in general formation. Into Kendall tuff or latite at 130 feet. None. Into andesite below 250 feet. None. Into latite at 340 feet. Into latite, depth uncertain. At dacite contact. None. Do. Do. Do. Do. Do. Into latite at unknown depth. Close to contact with Kendall tuff. None. Do. Into latite at 312 feet. None. Latite at 200 feet. None. Do. None. Into Kendall tuff. None. Do. Into dacite at 80 feet. Into latite at 250 feet. None. Into Milltown andesite at slight depth. None. Do. Do. Do. Do. Do. Do. Do. Do. Into latite at 685 feet. None. Into alaskite at slight depth. None. Do. Into latite at 280 feet. None. Do. Do. Do. Do. Do. Do. Do. Probably reaches latite. None. Into latite between 300 and 400 feet. None. Into latite between 300 and 400 feet. Into Morena rhyolite at about 150 feet. None. Into latite; depth uncertain. None. Do. Do. Do. Do. None to 450 feet; record below that unknown. None. Do. Into latite near bottom. Into alaskite. Into latite at unknown depth. None. 140 THE GEOLOGY AND ORE DEPOSITS OF GOLDFIELD, NEVADA. Principal shafts in the Goldfield district — Continued. Name. Number on Claim. Plate I. ' Section. Depth in feet. Surface rock. Changes in general formation. 319 200 203 104 207 50 54 50 132 40 322 230 124 89 109 110 240 125 113 112 130 147 102 * 7 227 27 145 101 290 201 142 100 8 220 118 129 159 190 270 150 143 11 309 235 204 104 21 323 85 247 233 277 ~43 250 244 135 100 148 224 134 114 205 239 238 02 03 115 106 88 187 188 20 Bonanza 5 32 33 30 1 21 26 26 30 20 7 1 30 35 35 35 1 36 35 35 36 36 35 29 1 19 30 35 1 32 30 36 24 1 36 36 36 31 1 30 30 19 6 1 1 35 19 8 35 1 1 1 20 1 1 30 35 36 1 36 36 33 1 1 20 26 35 3.5 35 31 31 19 195 300 Milltown andesite Magnet Gold King Hobo Kewana Fract ion Atlanta Milltown andesite Maloney Do Do.. Milltown andesite do. . Mammoth Amazon Gem Do 283 Do Do Denver Sandstorm rhyolite McNaughton Mohawk No. 2 Midnight Fraction Milltown Fraction Combination No. 3 Mohawk No. 2 Dewdrop Midnight-Pa wnee . do Milltown Fraction 220+ 600 200 300 500 Milltown andesite do Do. Mitchell-Fairfield (Stoneham) Do. Mohawk Dacite Mohawk-Annex Siebert Dacite Mohawk Consolidated Mohawk No. 1 do Mohawk Consolidated M. & L do. Do. Red King Milltown andesite Dacite Do. Mohawk-Jumbo Gold Wedge Mohawk N 0. 1 do Do. Mohawk Leasing Co. No. 1. . do Do. Mohawk Leasing Co. No. 2 do Do. Mohawk Ledge . . Gold Wedge 700 420 300 ...do... Mohawk-Red Top do Into latite at 3G5± feet. Mohawk Syndicate . Mohawk No. 1 Lou Dillon Kendall tuff Milltown andesite do Moore Combination No. 2 Daisy No. 1 Morrison 370 480 300 do Mushett Miss Jessie Dacite Into latite near 480 feet. Mohawk No. 1 Golden Eagle Kendall tuff Nevada Exploration Milltown andesite None. Nevada King. . . North Star Nighthawk East Side Dacite Do. Norcross Black Rock do Oakes Oakes Combination Fraction Mohawk No. 2 do 012 300 230 300 275 300 + Milltown andesite Do. Oddie Do. Do do Do. Oddie-Rose do Do. OKeefe Kewana No. 2 Economist Union Jack ...do Into latite. Old Kentuek Milltown andesite Dacite Into Sandstorm rhyolite at 50 Original Atlanta. feet. Into latite below. None. Original Velvet Velvet do Oro Midnight Fraction Rabbit's Foot do Do. Palace Milltown andesite ....do Do. Parker. . . . Do. Parkinson.. . Rustler Fraction Cornishman do Penn (Winston) 500 Dacite Do. Peterson's Silver Pick ....do Pierre and Pugh Thanksgiving Gift Mayflower. . . 100 Milltown andesite do feet. None. Pittsburg-Nevada Do. Pocahontas 500 440 250 200 Into Siebert. Pollard-Florence Red King Milltown andesite Siebert None. Portland Bull Con. Into Milltown andesite within Portland-Florence Emma Fraction Quartzite No. 1 September Milltown andesite ...do a few feet of surface. Into latite near 250 feet. None. Quartzite. . . . Do. Red Hill do Red King Red King . ...do Do. Red Top Red Top... 350 300 210 200 200 Dacite Into latite between 200 and 350 Red Top Fraction.. Red Top Fraction do Alaskite feet. None. Do Dacite Reilly Florence ...do Do. Rickard No. 1 Mohawk No. 2 do .do.. Do. Rickard No. 2 do Do. Rochester Lone Star. ...do Do. Rogers Red King 500 500 400 150 150 175 200 250 Milltown andesite do Do. Rosebud (O. K.) Rustler Fraction Sandstorm Do. Sandstorm (old) Sandstorm rhyolite ...do ' Into Kendall tuff at 200 feet. Sandstorm (new or Kruger) Sheetz-Ish Kruger. . . . Into Kendall tuff at bottom. Combination No. 1 Deserted Dacite None. Silver Pick do Do. Silver Pick Extension. White Streak Latite Do. Simbull Kee Dacite Into latite between !■• and -'no Simmerone Simmerone ... .do feet. Into latite at unknown depth. skylark Christmas No. 3 Latite None. Smith (see Frisco).. . Sovereign (see Gold Sovereign) Spokane 14 Snokane No. 2 . 19 1 36 Milltown andesite ...do Do. Sprague-Stein -'..7 169 Combination No. 3 St. Ives Do. St. Ives 470 Dacite Do. St. Ives Leasing (see Codd i Stoneham (see Mitchell-F.). . . Sunnvside 314 Mollie No. 1.... 6 13 1 1 19 30 31 36 1 1 25 do Do. Tacoma 3 286 29S 18 120 192 172 303 302 70 Tacoma Do. Golconda 300 ...do.. Into latite at 290 feet. Third Chance Third Chance ...do.. Dump shows dacite. Toplitz (Daisv L. & M.). 1 laisy No. 1 250 275 415 300 . .do.. Truett Mohawk No. 2 Hansbros. No. 2 Sunllower Dacite Do. United Mines Latite Dacite Vencendor Combination Milltown andesite do Close to dacite contact. Victor Sandstorm rhyolite... OPERATION OF MINES. 141 Principal shafts in the Goldfield district — Continued. Name. Number on Plate I. Claim. Section. Depth in feet. Surface rock. Changes in general formation. White Rock No. 2 209 213 214 215 216 207 White Rock 2 2 2 2 2 2 300 Siebert do Into latite at 100 feet. White Hock No. 3 White Horse Into latite; depth not ascer- tained. Do. White Rook No. 4 do do White Rock No. 5 (Januarv-W. R.) White Rock No. 6 ...do.. 400 do do Do. Blue Jay Do. White Rock No. 7 Alpha 520+ do Into latite at 280 feet. Wilbur (see White Rock No. 4) Wilkes 60 310 263 Sandstorm 26 6 1 600+ Milltown andesite Milltown andesite Dacite Close to contact with Sand- Yellow Tiger Lindsay storm rhyolite. Into latite at 510 feet. Cornishman None. The names of the following shafts were not ascertained : No. on Plate I. Claim. Section. No. on Plate I. Claim. Section. 191 31 30 20 20 2 19 8 35 35 36 35 1 19 6 32 26 36 1 36 | 32 1 35 5 321 95 98 167 153 9 51 57 185 194 44 170 171 176 208 175 97 174 16 73 Atlanta Nevada Eagle 4 36 Black Butte Extension 35 38 Black Butte No. 1 35 217 Butte Pol verde do Red Butte No. 1 Red Rock 36 25 Daisy Triangle ? 36 324 19 105 Deserted 21 103 do Rex 26 184 Frisco 36 99 Gold Banner Silver Tip 31 285 Ooleonda 20 13 Oreat Bend No. 2 St. Ives 36 311 Hidden Treasure Sunflower do 36 199 36 55 Triangle Velvet 2 181 Kewana No. 3 36 183 Lazy George 35 197 Little Brownie 2 91 36 MINING COSTS. The only mine that has recently afforded full and significant data on mining costs is the Combination! According to the report of the Goldfield Consolidated Mines Company for the year ending October 31, 1907, the normal average costs from June to October of that year, a not very favorable period, were as follows: Costs per ton at Combination mine. Mine expenses $4. 369 Office expenses 1. 778 Total mining costs (j. 147 Milling 7. 142 13. 289 For September, 1908, the mining costs were brought down to $3.15 and the milling costs to $6.13, a total of $9.28. The company expects in the near future, when the new mill is in operation, to reduce the total mining and milling cost to about $5 a ton and to be able to handle $8 ore at a profit. This is probably a somewhat optimistic estimate, although in July, 1908, ore was being broken in some of the Combination stopes at a cost of only 33 cents a ton. In the year ending November 1, 1907, the average cost of all development in the Red Top mine was $9.02, and in the Mohawk mine $11.42, a linear foot. Shaft sinking as a rule is rapid at Goldfield and costs from $20 to $30 a foot. At the end of 1905 the deepest shaft in the district was the old Jumbo, 450 feet deep, and the deepest 142 THE GEOLOGY AND ORE DEPOSITS OF GOLDFIELD, NEVADA. level then being worked was the 280-foot level of .the January mine. In July, 1908, there were at least 4 shafts 600 feet or more in depth, 18 shafts from 500 to 600 feet in depth, 22 shafts from 400 to 500 feet in depth, 39 shafts from 300 to 400 feet in depth, and probably at least 50 shafts from 200 to 300 feet in depth. As shown by the preceding table, much work has been done since that time. The Little Florence shaft, containing two hoisting compartments, with separate manway and fully timbered, was completed in thirty-nine and one-half days. In this case it was possible to work both by sinking and raising. The main Combination shaft, 380 feet deep, is said to have cost $22 a foot for the original two compartments. (The shaft has since been enlarged.) Recently the Gold Bar Fraction Mining Company contracted for 250 feet of shaft sinking at $26.50 per foot, the contractor to furnish all materials, tools, and labor. Tunneling or crosscutting usually costs from $4 to $5 a linear foot. POWER. Horse whims were used on some of the early leases in Goldfield, but were soon supplanted by the more economical and much more efficient gasoline hoists. In 1905 these hoists, ranging from 12 to 30 horsepower, were in almost universal use. The Combination and January mines at this time were hoisting with steam, the former using wood at $11 a cord for fuel, and a few mines had begun to use electric power generated at Bishop, Cal. At present this is the most generally used power in the district, and will run the new mill of the Goldfield Consolidated Mines Company. Hoisting at the main Mohawk shaft is at present done by air compressed by electric power. The air on its way to the hoist passes through the boilers, which are partly filled with water warmed by a low fire. It is the intention, however, when active work is resumed and more air is needed underground, to hoist with steam, using oil as fuel. Electricity is supplied to the Goldfield district by the Nevada-California Power Company, which has displayed much enterprise in utilizing the water power at Bishop, Inyo County, Cal., and in carrying transmission lines across wide stretches of desert. At Bishop Creek, 98 miles (158 kilometers) from Goldfield and 104 miles (167 kilometers) from Tonopah, the company has built large reservoirs and has installed dynamos capable of generating 16,000 horsepower. There are two separate transmission lines to Goldfield and Tonopah, each capable of carrying the full load, and thus providing against any long interruption of the current. The electricity is sent over these lines at 50,000 volts, is distributed to the mines at 6,600 volts, and is used for motor driving at the standard voltage of 440. In July, 1908, the power consumption in the Goldfield district was 3,500 horsepower. The power company estimated that 2,500 additional horsepower would be utilized at the beginning of 1909, when presumably the Goldfield Con- solidated mines and mill, the Florence mine and mill, and the Goldfield CI mill will all be in operation. The rates for continuous service, based on peak loads measured on the motor side of transformers, are as follows: Net rates for electric ■power per horsepower per month. I to 10 horsepower $20. 00 II to 20 horsepower 15. 00 21 to 50 horsepower, $15 less 10 per cent 13. 50 51 to 75 horsepower, $15 less 15 percent 12. 75 7G to 100 horsepower, $15 less 20 per cent 12. 00 101 to 200 horsepower, $15 less 25 per cent 11. 25 201 horsepower and upward, rates fixed by special contract in each case. Users of the power are required to furnish transformers and other connecting apparatus. WATER SUPPLY. The water supply of Goldfield was originally obtained from a well 90 feet (27 meters) deep, with lateral drifts, situated near the mouth of Pozo Canyon. This was yielding about 15,000 gallons (56,250 liters) a day in 1905, but experience with shallower wells in this vicinity had shown that the available water at any given depth was exhaustible. The present supply, furnished by the Goldfield Consolidated Water Company, comes from springs near Lida, which the company estimates can be made to yield from 500,000 to 1,000,000 gallons (1,875,000 to TREATMENT OF THE ORES. 143 3,750,000 liters) in twenty-four hours. The 7-inch riveted steel pipe line is about 30 miles (48 kilometers) in length and has a capacity of 450,000 gallons (1,687,500 liters) in twenty- four hours. This line was completed in October, 1907, and is at present (November, 1908) delivering 250,000 gallons (937,500 liters) per diem. The water flows to a point about 3 miles (5 kilometers) from Goldfield and is thence pumped over Malpais Mesa. The water supply of Columbia, which is of good quality, comes from Rabbit Spring and from a well 180 feet (55 meters) deep, just south of the old Goldfield Reduction Company's (Gardiner) mill. This well was yielding about 10,000 gallons (37,500 liters) per diem in 1908. The greater part of the water comes in from the sides above 100 feet (30 meters) in depth and at the time of visit stood within 2 feet (0.6 meter) of the surface. Since 1905 the Combination mine has had an independent water supply derived from Alkali Springs, situated 10 or 11 miles (16 to 18 kilometers) northwest. The springs are warm (about 60° C.) and the water collected by tunnels is discharged into a concrete tank of 200,000 gallons (750,000 liters) capacity, whence it is pumped to the mine. The flow from the springs is 67,500 gallons (253,125 liters) in twenty-four hours. A partial analysis of this water by A. A. Hanks shows the following constituents: Partial analysis of water from Alkali Springs." Parts per million. Silica (Si02) 42 Oxides of iron and aluminum (Fe203+Al203) 5. 3 Calcium (Ca) 46 Sodium (Na) 282 Bicarbonate radicle (HC03) 142 Sulphate radicle (S04) 501 Chlorine (CI) 64 The Florence-Goldfield Mining Company has recently constructed a pipe line from Indian Springs, about 5h miles (9 kilometers) west of Goldfield. This line, which is partly of wood and partly of steel, is expected to supply about 100,000 gallons (375,000 liters) per twenty- four hours. No pumping is necessary. TREATMENT OF THE ORES. The first important production from the district came from the Combination mine, and from December, 1903, to May, 1905, the ore was shipped to the smelters, being hauled by wagons first to Candelaria, 65 miles (104 kilometers) away, and later to Tonopah, 30 miles (48 kilometers) distant. The total shipping and treatment charges on Combination ore in 1904 averaged $57.24 a ton on ore of an average value of $419.24 a ton. During this year careful tests were made by F. L. Bosqui,6 following which a 10-stamp mill was built. This was designed originally for oxidized ore only, and was built in two symmetrical parts, the intention being to use one-half for custom work. The scheme of treatment is shown in figure 10, compiled from Bosqui's paper. Afterwards, when sulphide ores were found, 10 more stamps and the equipment shown on the right-hand side of the diagram were added. Wet crushing, amalgamation, con- centration, and cyanidation of the tailings is the general process employed, full details of which may be found in the paper above referred to and in a recent article by T. A. Rickard.c The concentrates are shipped to the smelters. The Combination mill, although not without some recognized defects in plan, has proved very successful when the character of the ore and the conditions under which milling is carried on at Goldfield are considered. According to Bosqui the total cost of milling and cyaniding in January, 1906, was $10,268 per ton, and in May of the same year $5,828. It was expected that the cost would be still further lowered, but from June to October, 1907, it averaged $7,142 per ton, and in September, 1908, was $6.13 per ton. The average recovery is 90 per cent and the daily capacity about 70 tons. a Ball, S. H., op. cit., p. 19: The analysis has been recalculated to the standard form now employed by the Survey. 6 Ore treatment at the Combination mine: Min. and Sci. Press, vol. 93, 1906, pp. 413-415, 451-454. c Goldfield, Nev., V: Min. and Sci. Press, June 20, 1908, p. 840. 144 THE GEOLOGY AND ORE DEPOSITS OF GOLDFIELD, NEVADA. w £.'/: £ i- 5 ■/. ■^X o 0» CO fc rH -i iO ^ i i c /} la 1/ a m / bo / C .'/ s V p c CD 1- V .a r: a w so £ ■"• o'l w *-* _^> g 3 C m 1 (31 bo cn a •P g n < c & fag c en 01 g --3 rt <: E a. 1 w ■O- H h a» t- cp 4> -* sg fr. rt > --!>- + S E * cu £ -> >. u at a> SB c o i c 3 g •a m c a i -Q 3 s \T1 ^ s I b 3 c ■S t- 1 ' c 9>a3 I ' > EJ5 3 E M a> 3 •r rt 1 fa ^ ^ I a, £ 3 (5 H}~' 1 a> o-a •" .2 c - ^-2- — 3 P g-m 3 •a g - -t V *■) o £,-=8 g c 3 C a> % s 2 H* t< 1 & .c X I d a 1 o i g c« Cfl fcJO !» / CD o = £ — 01 (72 3 O a U N i 5 o c >> o TREATMENT OE THE OEES. 145 Up to the latter part of 1908 the Combination mine was the only property equipped with its own mill in actual operation. The new 20-stamp mill at the Florence mine was then prac- tically complete, but was not running. At the time of first visit, in 1905, there were four custom mills and one sampler in the district. The pioneer mill was that of the Goldfield Reduction Company (Gardiner mill), situ- ated about 1,000 feet (305 meters) northeast of Rabbit Spring. The New Western Reduction Company paid 85 per cent of the assay value for ore, subtracting a charge of $12 a ton for milling. The Nevada Goldfield Reduction Company, popularly referred to as Frank's mill, bought ore outright and milled it, or, in the case of ore from the January mine, paid 95 per cent of the assay less $12 a ton for treatment. The American Milling and Water Company bought ore or milled it at an average charge of $12 a ton. The Columbia Sampling and Ore Company acted as sampler or purchaser only, shipping the ore out of the district for treatment. The total maximum capacity of the three custom mills running in 1905 was about 70 tons a day. The processes employed in these mills were similar to that used in the Combination mill, but the American Milling and Water Company's plant was the only one equipped for cyanidation. According to an estimate made by Francis A. Thomson, superintendent of the New Western Reduction Company, and published in the Goldfield Sun of September 14, 1905, the average daily production of the Goldfield mines at that time was 70 tons of shipping ore, of an average value of $200 a ton, and 100 tons of milling ore, at an average value of $40 a ton. In general, ore of lower grade than $100 a ton was milled in the district. The Combination Mines Company milled all of its ore except that exceeding $600 a ton in value, which was shipped. The freight rates on ore to San Francisco, Salt Lake City, or Denver in 1905 ranged from $8 a ton for ore under $25 in value to $22 for $300 ore. For richer ores, from 3 to 5 per cent of the value per ton in excess of $300 was added to the $22 rate. For example, on $2,000 ore the freight would be $22 plus 5 per cent of $1,700, or $107 a ton. Smelting charges were $10 a ton on all siliceous ores, with an additional charge of $1 a ton if the silica were unusually high. With the exception of the Combination, the mines either shipped their ore directly or disposed of it to one of the four reduction or sampling companies in the district. At the time of second visit, in 1908, the Combination mill was running practically as in 1906, the Florence Company had completed a 20-stamp mill, and the construction of a 100-stamp mill for the Goldfield Consolidated Mines Company, to cost $750,000, was well advanced. Some changes had taken place in the custom plants. The works of the Columbia Sampling and Ore Company, northwest of Columbia, had been remodeled by the Western Ore Purchasing Com- pany, which samples and buys ore, selling it to the smelters. No schedule of rates was obtained from this company, but their charges on 5-ounce ore from one lease in July, 1908, are known to have been $25 a ton for freight and treatment, the gold being paid for at 95 per cent of the total value figured at $20 per ounce. The Nevada Goldfield Reduction Company, although changed in personnel, was still in operation, but the other mills had closed. The following description of the Nevada Goldfield Reduction Company's plant is taken from Rickard's article (p. 841): This plant includes a sampler with a capacity of 450 tons per diem and a cyanide mill treating 100 tons per diem. The surplus ore is sold to the smelting companies. The equipment of the mill includes 20 stamps, of 1,250 pounds each, by which the ore is crushed to 12 mesh in a 0.50 to 1.25 pound KCy solution. The pulp on issuing from the mortar goes over amalgamating plates and then to eight Wilfley concentrators, classifying into three products, namely, concentrate, sand, and slime. The concentrate assays from $200 to $1,000 per ton, and is shipped to the smelters; the sand goes first to an Allis-Chalmers tube mill, 5 to 22 feet, reducing it to a screen size of less than 100 apertures per linear inch; from the tube the reground product passes over supplementary amalgamating plates and then to classi- fiers, the oversize from which is reground after going over a Wilfley. The leaching plant, which receives the pulp after the free gold and rich sulphides have been partly extracied by concentrators, includes eight vats of 22 by 5 feet and three agitator vats of 24 by 16 feet. Three vacuum filters of the Butters type strain the gold-bearing solution, which is further clarified by passage through a 5-ton American filter press, remodeled by E. S. Leaver, the superintendent of the mill. 79145— Xo. 00—09 10 146 THE GEOLOGY AND ORE DEPOSITS OF GOLDFIELD, NEVADA. A new plant, designed by John E. Greenawalt, had been built by the Goldfield CI Mill Com- pany northwest of Columbia, but was not yet open to custom. In Mr. Greenawalt's absence from Goldfield I was unable to examine these works. Mr. Rickard's visit was more fortunately timed, and his account" is here quoted: The roasting furnace is a rabble roaster of the muffle type; it has a porous hearth and is heated with producer gas manufactured from coal (coming from Helper, in Utah) enriched with crude oil (from Bakersfield, Cal.). From this furnace the roasted ore goes to a cooling cylinder, at the end of which it is moistened before delivery into a bin. From the bin it is transferred to large vats by means of a grab bucket of CO cubic feet (nearly 3 tons) capacity, operated by a traveling electric crane. The chlorination vats are of wood, sealed by a wooden cover, dipping into a launder filled with water. When silver ore is being treated 2 per cent salt is added before crushing, so as to get a good mixture. The leaching in the vats is done by a strong solution of chlorine in water — 7 to 8 pounds free chlorine per ton of solution. Leaching requires three to four days. The seven vats are each 22 feet diameter and 8 feet deep. The gold solution is withdrawn by gravity and pumped into a storage vat, and thence drawn to the precipitating boxes, resembling the zinc box of a cyanide plant. The precipitation of the gold is effected electrolytically, the anode being graphitized carbon and the cathode lead shaving containing 1 per cent zinc, the presence of the zinc hastening the corrosive action. The slime of lead, gold, and silver while still moist is mixed with flux and briquetted. The briquets are melted in a reverberatory furnace and then refined in a cupel. . The chlorine is generated electrolytically. At first salt was obtained from Hazen, in Nevada, but it was found to contain over 5 per cent silica, from sand blown across the dry lake; the salt now used comes from Salt Lake and costs $16.25 delivered. The solution of chlorine water is made in an absorbing tower; this consists of two sheet-iron stacks lined with glazed sewer pipe, with cement between the pipe and the outer iron. Inside is placed a filling of hollow clay balls, each of them having eight perforations. The chlorine gas is introduced at the bottom of the stacks and water is made to trickle down from the top, the large surface thus offered facilitating absorption. The mill has a nominal capacity of 100 tons per diem. The ore is crushed to 14 mesh and the roaster is 100 feet long. In the summer of 1908 the Goldfield Consolidated Mines Company were conducting experi- ments in the small Kinkead mill on Columbia Mountain for the purpose of devising a mode of treatment for the concentrates which would make the company independent of the smelters. The experiments were successful and the company is building a special plant on the lines sug- gested by them. According to a statement courteously furnished by Mr. J. H. Mackenzie, the general manager, the process depends on fine grinding and cyanidation. Its only peculiarity is a preliminary treatment of the concentrates to prevent the destruction of the cyanide solution by the sulphides. The new mill of this company, situated on the west slope of the ridge south of the Sand- storm mine, will probably be in operation by the end of 1908 and should greatly increase the output from the Consolidated group of mines. The flow sheet of this mill is shown as figure 1 1 . The rich ore shipped by lessees is usually hand sorted at the surface, although in some cases, as at the Engineer's lease, the ore is so free from waste that it is shipped just as it comes from the stopes. Sorting as practiced by lessees is generally a rough and wasteful process. The coarse pieces after passing over grizzleys are picked over and cobbed without any prelimi- nary washing, so that many rich lumps go on the dump. The waste piles of the successful leases are consequently valuable and are nearly always reworked, being, as a rule, picked over again by hand. The Little Florence dump, for example, was sold for $10,000, and the purchaser realized $16,152.83 from the ore culled from it between June 1 and November 30, 1908. In this case water was available and hose was used advantageously to clean the lumps before sorting. Most of the crude ore and concentrates shipped from Goldfield has gone to the smelters on San Francisco Bay ami in the Salt Lake Valley, Utah. The freight rates to these points are the same, and where ore is diverted to other smelters the difference in freight, if any, goes to the account of the smelter receiving the shipment. Prior to September, 1907, the freight schedule was as follows: a Goldfield, Nev., V: Min. and Sci. 1'ress, June 20, 1908, pp. 841-842. ' TREATMENT OF THE ORES. 147 Freight rates from Goldfield to San Francisco and Salt Lake Valley prior to September, 1907. Up to $40. $40 to $50. $50 to $60. $60 to $70. $70 to $80. $80 to $90. Actual value per ton.n Freight per ton. $7.80 10.95 11.55 12.90 14.25 15.60 Actual value per ton." $90 to $100... $100 to $150.. $150 to $200.. $200 to $250.. $250 to $300.. $300 to $1,000. Freight per ton. $17. 15 18.05 18.85 19.90 20.90 a Gross assay value less the charges for assaying, smelting, and handling at the smelter. b Add to rate for $300 ore 2 per cent of the value above $300 per ton. CONCENTRATION SCHEME OF THE GOLDFIELD CONSOLIDATED MILL Ore train Ore bin 1 (1) No. 7^ crusher v, — <1M8 by 14 screen. <2(No.4 crushers j. Automatic weighing machine Q) No. 3 Vf/.in sta mpier S%cut 26"byl5"roTls * 1 1 t \'... j \Wiii ^minkr .^ViTt -*-""wNo. 1 Vezin sampler S%rut Sample grinders Aftsayers (1) /iOoo-toTi bin (10) lO-stamp imltfri«T» Amalgam "plates Amalgam traps classifiers IM ,,:;. Launder distriin itpr (O)Dorr classifiers ClassinVrs Launder distributor Ui> Slry ir,'.iiii.tlij:.iiii plates Amalgam traps rrcnier sand pump cjzL Launder distributor Pulp thickeners (78) 6ibot Duster tables Wider tank Weak solution tank " — i Pimp storage frndts Laund^Vnsfril.iif.-r Launder drHrilmtnr (2 sets>Biittcrs t ifier frames i Launder distributor Vacuum ''pumps' i..i;„. Launder distributor Gold solution sump 4 « : j > j, -=r r Surplus walci tank Surplus s..litli..n i:tnU Sni-plns pulp tank rramp titter presses for clnrifymg; J I J T I , I. - '. i ; Launder distributor Lanndc r\Iistributnr Amalgam barrel Amalgam press Retort /in.- .lusl |iri'.-ij>i<.ilmn l.i nh . i>v„ I: t ',<}•■ .lilst p-n-i-if.ii^llcn I :i nks <^< T-.n \£ ) Frame zmr dust nreciprtationTTresses rornace T>ryin£ furnace for precipitate Distributor O' Taber du Faur furnaces tor precipitate TJastrflmtar ~i_ Laimder*3istribu tor Storagp tankpveak solution) Storage tank (strong solution) ^Solution returned to settlers caul agitators >Slag to smelter >JBul/ion to mint ^Quicksilver +7aHinys to dam Concentrate treatment plant Figuke 11.— Scheme of treatment in the new Goldfield Consolidated mill. 148 THE GEOLOGY AND ORE DEPOSITS OF GOLDFIELD, NEVADA. The smelter charges at this time were as follows; Smelter schedule prior to September, 1907. Assay value of gold and silver per ton. Charge per ton for treatment. Price paid for gold per ounce, Up to $70 $0 7 8 9 $19. 00 $7(1 to $100 19 00 $100 to $300 19 50 Over $300 19 75 In October, 1907, owing to the general financial situation, the rates were raised until the total freight and treatment charges on -11 00 ore amounted to $45.35. On December 13, 1907, the following freight schedule went into effect and was still in force in June, 1908: Freight rates from Goldfield to San Francisco and Salt Lake Valley December 13, 1907 . Actual value per ton. Freight per ton. Actual value per ton. Freight per ton. U p to $20 $6.00 7.10 7.80 10.00 11.00 12.00 13.00 $80 to $90 $14.00 $20 to $30 $90 to $100 15.00 $30 to $40 $100 to $150 16.50 $10 to $50 $150 to $200 18. 00 $50 to$(i0.. $200 to $250 19.50 $60 to $70 $250 to $300 20.90 $70 to $80 $300 to $1,000 («) a Add to rate for $300 ore 2 per cent of the value above $300 per ton. In this schedule freight agents are instructed to refer shippers offering ore of greater value than $1,000 per ton to the express companies. If accepted as freight, the following additional charges are levied: Freight on exceptionally rich ore. Actual value per ton. Freight per ton. $1,000 to $1,500 $20.90 plus 3 per cent of excess value over $300. $20.90 plus 4 percent of excess value over $300. $20.90 plus 5 percent of excess value over $300. $1,500 to $2,000. . 0 ver $2,000 It is evident from a casual inspection of these rates that they are based, not on the cost and responsibility of the service performed, but on the expectation of what the shipper may be made to pay. The railroads, unless forced to by legal proceedings, assume no greater respon- sibility on ore above $100 per ton in value and exact the additional rates for rich ore, even when expressly released from special liability.0 a As this report goes to press announcement is made of a new freight schedule promulgated by the Tonopahand Tidewater Railroad. As given in the Mining and Scientific Press for December 20, 1908, the new rates are as follows: Ore assaying— 30 .. . 3 90 40.. . 4 40 50. . . 4.80 . 5.25 0.75 80 7. 50 Ore assaying — $90 :... S8 25 0. 00 100 1 50 10. 10 200 1 1. 25 250 12. 40 300 13. 50 TREATMENT OF THE ORES. On February 6, 1908, the following smelter schedule became effective* Smeller schedule of February 6, 19<)8. GOLDFIELD ORES. 149 Assay value of gold anil silver per ton. Up to $50.. $50 to $00.. $60 to $70.. $70 to $100. Over $100. . Charge per ton for treatment. $6.50 7.50 8.50 9.50 10. 50 Price paid for gold per ounce. $19.00 19.00 19.00 ir,.oo 19. 50 In addition to above treatment charges, where gold contents exceed 5 ounces per ton, add $0.50 for each ounce or fraction thereof in excess of 5 ounces. Silver to be paid for, if 1 ounce or over, at 95 per cent of New York quotation. On ores under $60 gross value a charge of $0.25 will be made for each per cent of sulphur in excess of 3 per cent. GOLDFIELD CONCENTRATES. Assay value of gold and silver per ton Under $100 $100 to $300 Over «:«X) . Charge per ton for treatment. $10.50 1 1 . 50 12.50 Price paid for gold per ounce. $19.00 19.50 $19.75-20.00 In addition to above treatment charges, where gold contents exceed 5 ounces per ton, add $0.50 per ton for each ounce or fraction thereof in excess of 5 ounces, and where gold is under 5 ounces per ton add $1.50 for each ounce or fraction thereof under 5 ounces. The treatment charges in the foregoing table are those upon which the American Smelting and Refining Company bases its contracts. The actual charges for treatment are 50 cents less in each case — viz, $6 instead of $6.50, etc. — the not altogether luminous explanation being current that the sampling works, which act as brokers or buyers for the smelters, charge the lower rate and the smelter company "protects" them. Attention may be called also to the modifying addenda which follow the tabular parts of the schedule, particularly that under con- centrates. Here the rate for $100, or 5-ounce, concentrates is $10.50. For concentrates con- taining a fraction of an ounce less than 5 ounces of gold per ton the charge becomes $10.50 plus $1.50, or $12. For concentrates containing a fraction of an ounce over 5 ounces of gold per ton the charge becomes $11. In addition to the freight and smelting charges the shippers have to pay from $1.50 to $2 a ton for the sampling. CHAPTER XII. THE LEDGES. DEFINITION. The Goldfield deposits, in all that pertains to the genesis of the ore, are most closely allied to metasomatic fissure veins. Yet they can scarcely be included within that class. They are intimately related to Assuring, but only a small part of the ore has actually filled fractures (spaces of discission). These fractures, moreover, rarely show that regularity in form and that persistency in strike and depth which are connoted with the term "vein" or "vein fissure." Structurally the deposits are irregular masses of altered and mineralized rock traversed by multitudes of small, irregularly intersecting fractures, such fracturing passing in many places into thorough brecciation. There are exceptions to this character. Certain deposits exhibit in part more regularity of form and there is reason to suppose that at depths greater than those now reached such approaches to lode-like form may become more numerous. But within the mass of rock extending from the surface to a depth of 600 feet (183 meters), a mass which includes all the ore bodies thus far exploited, the deposits can not be called lodes or veins with- out giving to these words unusual meanings or without tacitly ascribing to the mineralized bodies a tabular form that they rarely possess. In view of these considerations, the word "ledge,"0 already in use by miners in a less definite sense than "vein," will be employed in this report to designate the masses of silicified or other- wise altered rock in which the ore bodies are found. This word, although suggested by the outcrops of such material, will be applied at all depths where any distinction is possible between an alteration intimately associated with the ores and a more extensive alteration of country rock. It will be applied, moreover, to rock which has undergone alteration of the kind char- teristic of the immediate vicinity of ore bodies, whether or not ore is known to be present. The actual ore bodies or pay shoots occur within, but are seldom coextensive with the ledges or ledge matter. The proposed usage of ledge is not intended to restrict the word to a special technical meaning but rather to avoid the use of vein and lode, which, while broadly used by miners, are employed with some definiteness in scientific writing. DISTRIBUTION. The ledges, considered as topographic features and independently of ore bodies, are extraor- dinarily abundant in the Goldfield district. To them the topography owes most of its minor roughness; many small knobs are crowned with iron-stained masses of ledge matter and the slopes of the larger hills are ridged and studded with the same material. As stated on page 16, these rough outcrops are in most, if not all, cases purely residual, and stand out, like pebbles in a clay bank, because the softer rock has been eroded from around them. Many of them in fact rest like giant pebbles on the tops of knobs and have no downward continuation into the soft rock beneath them. Some of these loose superficial masses of ledge matter east of Gold- field are shown in Plate 'XIV, A. Prospecting tunnels have been driven directly under some of them. a" In mining, ledge is a common name intheCordillcran region for the lode, or for any outcrop supposed to be that of a mineral deposit or vein. It is frequently used, as reef is in Australia, to designate a quartz vein."— Century Dictionary. "A rocky outcrop or reef. * * * Mining. A metal-bearing lock stratum; a quartz vein." — Standard Dictionary. 150 U. S. GEOLOGICAL SURVEY PROFESSIONAL PAPER 66 PLATE XIV A. LEDGE OUTCROPS IN MILLTOWN ANDESITE ABOUT 2 MILES EAST OF GOLDFIELD. *»■•■' ,"..-. ■ -4'.-. -. MH B. LEDGE OUTCROP IN DACITE BETWEEN THE BLUE BULL AND COMMONWEALTH MINES. The conspicuous white dump is alunitic material from a lease on the Lone Star ground. The rough knob on the sky line near the right side of the view is Banner Mountain. THE LEDGES. 151 On the geologic map, Plate II, an attempt has been made to show the general distribution of the ledges by plotting the principal outcrops in the field with a plane table. The result at best is only an approximation to the truth, as the boundaries between ledge matter and soft altered country rock are often indefinite and are seldom clearly exposed at the surface. For this reason, and to avoid obscuring the other geologic features of the map, the generally linear outcrops are indicated by lines and round or irregular bosses by dots. No attempt has been made to indicate the relative size of outcrops. Moreover, many small outcrops are omitted, while in some places, as on the east side of Vindicator Mountain, the alteration to ledge matter has affected areas so broad that they could only be properly indicated by washes of color or by some device of shading. But while rigid accuracy in the cartographic representa- tion of them is thus unattainable, the map serves to bring out the general distribution and some of the peculiar features of the ledges. The ledge outcrops east of Goldfield are shown on a smaller scale in figure 12. Plate II shows that a conspicuous belt of ledges, about a mile wide, stretches from the vicinity of Columbia and Goldfield in a gentle curve, at first nearly southeast but gradually sweeping to the east, past Preble and Blackcap mountains and beyond the eastern boundary of the area subjected to detailed study. As shown in Plate XV, A, which is a view eastward from Blackcap Mountain, the characteristic ledge topography continues for a mile or two beyond that summit, and merges finally into the desert plain that separates the Goldfield Hills from the Stonewall and Cactus ranges. Nowhere in the belt are the ledges more numerous or conspicuous than between Milltown and Blackcap Mountain, yet along this stretch no mines of the first rank have been developed. On the other hand, from the comparatively few ledges between Milltown and Columbia has come over 95 per cent of the gold sent out from the district. As regards geologic distribution, it is to be observed that most of the productive ledges are in the area of dacite northeast of Goldfield ; a very large number, of which only a few near Milltown have proved productive, are in andesite ; oth- ers, of which a few have been found to contain a little ore, are in the dacite mass of Preble Mountain ; and a few of no known economic importance are in the area of Espina breccia, northeast of Preble Mountain. Isolated ledges in andesite occur south of the main belt, up to the northern edge of the dacite vitrophyre, and there are a few not very prominent ones in the latter rock. A second belt of ledges is recognizable extending in a general easterly direction from the vicinity of Kendall Mountain through McMahon Ridge and Black Butte to the eastern border • 0 V 3 // CD J^ >■ 1 "*"^"1 (/) y ' 5 :• 7 ^r p >4 ' ' "^ - • • / * — ^ N4 * . * * \ /' 1. 0 » 'i{.i> '^- 'I B /. -' / *7 -r -o o 5' to vi •-1 % if) Of / /'''•' -'X • 0 ■ 'JI-QJ 5' B o p. crq rp • / f:>i : CD 0 1 o Q o f- r ' ' T 3 S ■■/j- ,\ ■ CD p- / • ^CD. . . •. a / o s5 ... . .i \ . 3T / .-.••• • • 0 CD £■' .. / i ' "D /.•'.;.: / 152 THE GEOLOGY AND ORE DEPOSITS OF GOLDFIELD, NEVADA. of the district. This belt is much less prominent than the southern or Preble Mountain belt. At its eastern extremity it spreads and becomes indefinite. It is connected rather loosely with the southern belt by scattered ledges in the neighborhood of Tognoni Springs and in the dacite east of McLaughlin's well. The northern belt of ledges is mainly in the Milltown andesite, although it crosses a mass of dacite near Black Butte. It contains some productive ore bodies in McMahon Ridge and Black Butte but no mines of the first rank. In addition to these principal belts ledges are distributed, without any particular alignment or regular grouping, over the central part of the district between the two principal belts, Banner Mountain being traversed by many of more than usual con- spicuousness and regularity (PI. XV, B). Others outcrop between Banner Mountain and Diamondfield. Vindicator Mountain exhibits much metamorphism of the ledge-forming type and many isolated outcrops of ledge matter; but dis- tinct linear ledges are not so well developed here as on Banner Mountain. Most of the scattered ledges ami groups of ledges in the central part of the district are in latite and none of them has yet proved productive. The Sandstorm, Kendall, Adams, and Conqueror ledges in rhyolite, north of Columbia Mountain, are perhaps best regarded as a group by themselves. As regards position, however, they are not sharply marked off from the northern or Black Butte belt. TREND OR STRIKE. The greater number of the ledges are irregular masses of no definite trend. Others, of which the proportion appears magnified by the method of representation adopted in Plate II and figure 12, have linear outcrops and are evidently related to fissures or fissure zones of some persistency, attaining in extreme cases a length of a quarter of a mile (0.4 kilometer). These, as a glance at Plate II will show, exhibit great diversity of direction and in some parts of the field, particularly near Milltown, ledges of various trends are linked together in complex chains. Most of the productive ledges near Goldfield have a north to northwest strike. Although diversity of strike is one of the most conspicuous features of the ledges as a whole, there is some approach to uniformity in the tendency of the longer ledges to conform in direction to the general trend of the belt in which they lie. The linear ledges are in most cases straight or but slightly curved. Others, such as the Jan- uary and Florence ledges, are sharply bent. (See PI. XVI and fig. 13.) DIP. LEGEND ViN^,/L/-i% '' :-i .'■■..>'.: Country rock Ledge matter SCALE IN FEET 100 Pay shoots Figure 13.— Plan of ledge matter and pay shoots on the 100-foot level of the Florcnee mine. t feet Cou Accurate data on the dip of a ledge are ob- scale tamable only where mining has been carried to some depth. A large number, probably most of the ledges, have nearly vertical dips. Others, such as the mass of ledge matter capping Black Butte, and the so-called Flat vein in the same hill, are nearly horizontal. (See also fig. 14.) The Mohawk ledge as a whole (see fig. 15) has Figure 14. — Vertical section through an irregular flat ledge, as seeD in the west wall of the Black Butte tunnel. U. S. GEOLOGICAL SURVEY PROFESSIONAL PAPER 66 PLATE XV A. LEDGE OUTCROPS EAST OF BLACK CAP MOUNTAIN. In the distance is Stonewall Flat with its white central playa; beyond is the Cactus Range. *-*c>* £f$£j ^^SSL: rScr- ..-.V' ... if tX' — •*■• —" -«.i» -__ J** • » -.. . ITT j||_ 4& ■£3L- ^< '»tu '-dr Jim.;.- B. LEDGE OUTCROPS IN LATITE ON BANNER MOUNTAIN. > X h- < LL X. LU Q. < Q. _J < 2 O O a. § o bb E 0) -1-! -o +j -V - ' u -\;/ v (U u UJ CC lu H H < LU C3 Q LU LU CC O LL o CO h- < _J LU CC o ui > IT 3 < O « o _l o UJ o 'V':' #f- -'~v ■ - ! i'm/ y\' ' ''" NT~~-^ / r ' ^ >i ' >.• /v^^r /.•-'.. 'Ociiv,y ^/ o /.i: -* t ** -■'--' v (J^ * /'--vV .'* JfS'" .>'>coV5:k : #,>*; o tab E '-.IT- o -5>r^$<^: r ">";'>.■ ' - C '-.W-? 4P~$f~,' J-'2\~s^' 1 '" XV 11 '0:l!\.\- J L>-'-, _ l- / ' - "_'-:••■■ ;^'J>-'--' ■ / _> - v ' ten - iH/ ^ «:;:&:;: '•:\':- wt ho E ti E ho E o x CO g H O UJ CO o <°= §> 1° to LU z < z < LU X I- LL O CO _1 LU > LU _l < a. o z CC a. LU x \- LL. o CO Z < _1 Q. THE LEDGES. 153 a dip of 35° to 45° to the east. The Combination ledge, while very irregular, also dips to the east, the angle of dip becoming very low on the deeper levels. (See PL XVII.) Most of the ledges that have been followed down for a few hundred feet show changes in dip such as are rarely found in typical veins or lodes. These changes are well illustrated in the January, Com- bination, Reilly, and Florence workings. (See Pis. XVI and XVII- and figs. 16 and 17.) SHAPE. The shape of the ledges has been partly indicated in the pre- ceding description. It has been shown that they range from roughly equidimensional, irregu- lar masses to nearly vertical or inclined, undulating, lodelike plates or sheets. Vertical pipes, of generally circular or elliptical section, such as the Anna Lee chimney of the Portland mine," may occur in theGoldfield district, but mining operations have not yet revealed any good example of this form of deposit. As examples of fairly regular, lodelike ledges may be cited parts of the main ledge of the Com- bination mine (described on p. 211), the Jumbo ledge (p. 221), and the Little Florence ledge (p. 223). The Mohawk ledge as a whole is generally lodelike, but is a very broad ill-defined mass, whose boundaries are as yet imperfectly known. Regularity observable on a given level is no guaranty of vertical regularity or persistence, as is shown by the sections of the Combination mine (see p. 212 and PI. XVII) and by the changes in dip of the Combination and Reilly ledges. a Lindgren, W., and Ransome, F. L., Geology and gold depositsof the Cripple Creek district, Colo- rado: Prof. Paper U. S. Geol. Survey No. 54, 1900, p. 447. MOHAWK-JUMBO SHAFT -MACKENZIE SHAFT- '//■ 430-FT MOHAWKJUMBO 430-FT MOHAWK-JUMBO m d'^ X % 30-FT O Jb'.vd • ' 490-FT - SECTION A — A" MOHAWK SHAF1 SECTION B-B" TRUETT SHAFT <&: -; . 275-FT 7>K- ffi=- '.--:/, p. <&;X %•-■■.■ *% 'm zzzrajou //////// ^%^ ^ ' ">, % "^ Q40I 600-FT MOHAWK ^m ^mmm^. ■a 430-FT.- MOHAWK- ■ 7- JUMBOS* !l m r> ^ SECTION C — C" Figure 15.— Sections across the Mohawk ledge on lines shown on Plate XXXIII. 154 THE GEOLOGY AND ORE DEPOSITS OF GOLDFIELD, NEVADA. Some ledges, like that of the Florence, while showing a fairly rectilinear outcrop, prove on exploitation to be exceedingly irregular in plan and to change in direction from level to level, as illustrated by the map of the Florence workings (PI. XXXV) and by figures 13 and 17. The COMBINATION SHAFT AIOS Surface' jurface /ST LEVEL ^A. too feet zoo feet Q * 77/ LEVEL 2 oo feet w Stopes ■ Ore body Figure Hi.— Sections across the Reilly pay shoot. January ledge, described indetail on page 217, best exemplifies a curved ledge and illustrates well the manifold irregularities of form characteristics of the Goldfield deposits. (See PI. XVI.) The modifications in form manifested by the ledges with increase in depth are not only of much scientific interest but are of great practical signifi- cance. The study of this feature of the deposits is ham- pered by the fact that below the zone of oxidation the distinction between ledge matter and the general country rock of the mines is less well marked than on those levels where original differences in composition and structure have been accentuated by the selective action of weathering. Moreover, the number of mines that have attained sufficient depth and horizontal extent to throw much light on this question is still small. The available data favor the view that silicification, which is the principal chemical distinction of the ledge mat- ter as a whole, becomes less as the depth increases. Accom- panying this change is a tendency of the ledges to become narrower and more lodelike. The change is not entirely regular and does not take place everywhere at the same depth. In the January mine the ledge on the 283-foot level still shows some silicification, but is much narrower than above and is straighter and more lodelike, as shown by Plate XVI. A similar simplification of form with narrowing and a notable decrease in silicification appears in the Florence ledge below the 250-foot level. (Seep. 227.) In the St. Ives mine the levels above the 150-foot show broad irregular masses of silicified ledge matter, while the 250-foot level is in soft fissured pyritized dacite showing only partial silicifi- cation along the fissures. In the Mohawk mine the ledge on the GOO-foot level, so far as could be determined from the limited exposures of it in 1908, is narrow and more lodelike than on the upper levels. Quite independently of ore and value, then, the ledges, as structures differentiated from the country rock by silicification, tend to become narrower, simpler, and more rectilinear in plan with 50 i oo feet Figure 17.— Section across the Florence pay shoot near the main shaft, showing changes in dip. > X UJ h < _l 0. LU Q. < O. W UJ u. o Cc D- n 0) D. in (J I/) 1_ CD •oo u rf^ vx«*6s£ ,'a ,<§ £ :-.V-ti( fwii fc da cite fi$&si.«: If IP > 3 CO _l < o o o _1 o UJ (3 V 0) V > > > •p o £ o co ro > ■P O 1 o 00 n X X X UJ H < z o z o I co CO UJ z z o UJ a Q UJ _l z o H < z CQ 2 o o UJ I I- co CO O cc o < co I- o UJ co U. S. GEOLOGICAL SURVEY PROFESSIONAL PAPER 66 PLATE XVIII PLANS OF LEVELS OF THE COMBINATION MINE, SHOWING APPROXIMATE HORIZONTAL DISTRIBUTION OF LEDGE MATTER AND ORE. . . . - ' ^ ^^ • ■' / // // THE LEDGES. 155 increase of depth. This suggests that below a depth of about 500 feet (152 meters) most of the ledges will show a gradual change to sulphide impregnations, or metasomatic veins, along zones of Assuring. Ledges having the form of nearly horizontal sheets occur in the district, but have not proved of much economic importance. Figure 13, page 155, illustrates a small ledge of this type inBlack Butte. Another, from which ore has been stoped, is the Flat vein on the south side of the same butte, described on page 247. In this connection attention may be directed to the tendency of the Mohawk and Combination ledges to flatten out to the east as they reach the bottom of the dacite (see fig. 15 and PI. XVII). This behavior is extremely interesting; and the bottom level of the Mohawk, as shown on page 206, just fails to answer the important questions suggested by this relation of the ledges to the dacite- latite contact. It is known that a short distance east of the Mohawk workings the bottom of the dacite in general rises toward the east. The 600-foot level of the Mohawk apparently cuts the ledge very near what may be called the keel of the dacite mass. To the west of the ledge on this level the bottom surface of the dacite dips to the east. A short distance to the east of the ledge on the 600-foot level the bottom surface of the dacite dips to the west. What becomes of the ledge below this level? Will it steepen and go down through the latite with probably some change in mineralogical character ? Is there in the latite a dike of dacite which the ledge will accompany downward? Or will the ledge be no longer traceable for any considerable distance below the main dacite sheet ? The importance of these questions is obvious, but unfor- tunately they can not be definitely answered until more underground work is done. The probability is that the ledge will continue down into the latite as a low-grade metasomatic fissure vein with pyrite as its principal metallic constituent." MATERIAL, AND MINOR STRUCTURES. As the most important ledges are in dacite, the material of those in this rock appropriately receives first attention. Within the zone of oxidation, the ledge matter is usually a rusty, shattered, or brecciated mass that commonly contains, here and there, bunches and streaks of kaolinite, which may be mixed with limonite or alunite, or both. The fragments of the breccia may be loose, with considerable interstitial limonitic or kaolinitic material, or may be cemented by quartz, limonite, or hematite. Excellent examples of such hard cemented breccias may be studied on the ridge east of the Blue Bull mine, and views of them are given in Plate XIX. The fragments of the breccias vary much in size, and it is impossible to draw any definite line between brecciation and close irregular Assuring. In many places the rock appears to have been shattered without any noticeable displacement, rounding, or trituration of the fragments. The ledge matter as a whole is porous and permits the downward percolation of atmos- pheric water, while the soft pyritized dacite on both sides is relatively impervious. Hence, oxidation extends much deeper in the ledges than in the adjoining country rock and gives rise to a sharp color-distinction between rusty ledge matter and gray pyritized dacite. The fragments in the oxidized ledge matter, which were originally dacite, are usually stained with iron oxide and now consist of gray, flinty, aphanitic quartz with a porous texture. Close inspection of this material shows occasional phenocrysts of quartz which have persisted practically unchanged while other minerals have altered to secondary aggregates around them. The pores are spaces once filled by feldspar and by femic (ferromagnesian) minerals in the original dacite. These minerals were first changed, during ore deposition, into aggregates consisting chiefly of alunite and pyrite, respectively. Later, during the progress of oxidation, the pyrite and alunite were removed and the spaces they once occupied were lined with drusy films of quartz. The removal, however, is complete only near the surface. In much of the "Since this was written the mining periodicals report (January, 1909) that the Clermont shaft has cut the Mohawk ledge at a depth of 856 feet (261 meters), or 241 feet (73 meters) below the bottom of the dacite. The ore found here is said to assay $22 per ton. The character of the ledge matter is not stated. 156 THE GEOLOGY AND OEE DEPOSITS OF GOLDFIELD, NEVADA. rusty ledge matter the fragments, when freshly broken, show pyrite and alunite. Not all of the pyrite and alunite are distinctly pseudomorphous, but these minerals are in part disseminated in minute crystals through what was once the groundmass of the dacite. Below the limit of oxidation the ledge matter is usually less siliceous, less porous, and of course is not discolored by oxides of iron. The many small fissures and interstices in the mass are commonly filled with a soft white substance which is usually alunite or a mixture of alunite and kaolinite. The material of the fragments, or between the fissures, shows more clearly than in the oxidized zone that it is altered dacite, the feldspar phenocrysts being represented by aggregates of alunite instead of by quartz-lined cavities. These changes will be more fully treated in the chapter on metasomatism (p. 176). Sheeted structure, suggestive of that in the Cripple Creek district," characterizes some parts of the Red Top, Mohawk, January, and Jumbo ledges, but is not common in the district. A small section of the Jumbo ledge in which this structure is well developed is shown on Plate XX, B. The nearly parallel fissures are for the most part mere cracks rendered more prominent by silicification of their walls. Some are perceptibly open, their walls being lined with drusy films of quartz. The plates of dacite between the fissures are partially silicified and contain pyrite and alunite. Well-marked sheeting is displayed also in the Lone Star ledge. In some ledges and parts of ledges there is no evidence of more than one period of Assuring and mineralization ; others have had a more complex history and contain fragments which show signs of an earlier Assuring and silicification. In the latter case, the ore is associated with the younger disturbance. Some ledges, also, have undergone some fissuring after the primary ore deposition, as will be shown in subsequent pages. Fissures filled with gouge which may contain gypsum, pyrite, and marcasite occur in some ledges, often as local division planes between ledge matter and country rock. The age of such fissures is not always determinable. A gouge seam may be formed very early in the history of a deposit and is likely to remain as a permanent feature, owing to the fact that gouge is relatively impervious to solutions and often retains its soft plastic character, while fissured rock alongside of it is profoundly altered. Such gouge-filled fissures remain planes of relatively easy movement and the material within them may be slowly squeezed and kneaded throughout the entire period of ore deposition. They may even continue to register such adjustments and displacements as take place in the ledges up to the present time As pointed out in another place,6 the soft condition of gouge is no proof of recent origin. In many cases it appears to be the record of continued movement which was initiated before ore deposition and continued after it had ceased. Still other fissures are plainly later than the first ore deposition and appear in the ore bodies as streaks of soft dark material, often carrying more gold than the adjacent ore. Ledges in andesite have not been so fully explored as those in dacite, but they exhibit similar structural features. The}^ are exemplified by the ledges worked in the Engineers', Little Florence, and Rogers leases in Florence Hill. The discovery of these ore bodies from 1906 to 1908 shows that andesitic ledges may contain ore fully as rich as those in dacite. The ledges near Diamondfield are mostly in the Milltown andesite. Their character below the zone of oxidation appears to be different from that of the ledges near Goldfield. They are less siliceous, being as a rule soft, crushed masses, with none of the structures so characteristic of the pay shoots of the Goldfield group of mines, presently to be described. In their oxidized portions, however, these andesitic ledges are as hard and siliceous as any in the district. The only rhyolitic ledge in which extensive work has been done is that of the Sandstorm and Kendall mines. Within the oxidized zone, the fissured rlvyolite is thoroughly silicified and the walls of fissures and the surfaces of fragments are often encrusted with barite. The interstices are filled with kaolinite, usually more or less rusty and containing in many places a See I.indgren, \V.,and Kansome, F. L., Geology and gold deposits of the Cripple Creek district: Prof. Paper U. S. Geol. Survey No. 54. 1906, p. 180. b Ransome, F. L., and Calkins, F. C, The geology and ore deposits of the Coeur d' Alene district, Idaho: Prof. Paper U. S. GeoL Survey No. 02 1908, p. 120. U. S. GEOLOGICAL SURVEY PROFESSIONAL PAPER 66 PLATE XIX A. DACITIC LEDGES MEETING ON RIDGE NEAR THE COMMONWEALTH MINE. , V - / J- <£? ^*M> ^ *■ '7' ' ;/f ' ' I 7?. NEAR VIEW OF DACITIC LEDGE NEAR THE BLUE BULL MINE; SHOWING STRUCTURE. U. S. GEOLOGICAL SURVEY PROFESSIONAL PAPER 66 PLATE XX LEDGE STRUCTURES (NATURAL SIZE). A. Vein lets of compact quartz and kaolinite in altered andesite (G. 76S); Goldfield- Belmont mine. B. Sheeted dacite and low-grade ore (G. 7,2? ■ Jumbo mine Dacite isalunitized. Fissures lined with quartz 73) ™ 1>. THE LEDGES. 157 crystals of barite. Below the zone of oxidation there is little to distinguish ledge material from the altered rhyolite in the vicinity of these mines. The origin of the Assuring constitutes a problem that will be attacked in a later chapter. It may be pointed out at this place, however, that Assuring of the kind described has all the characteristics of fracturing that has taken place close to the surface or under very slight load. The multitude of small fractures, becoming noticeably less abundant and individually more regular within a depth of a few hundred feet, is clearly the comparatively superficial expression of more deep-seated and regular dislocation. Such complex fractures, as T. C. Chamberlin a has well emphasized, are secondary phenomena related to more profound and more simple move- ments, and from the point of view of dynamics they are accessor}', not essential. A similar, although less pronounced, change in the Assuring of the rocks at Cripple Creek at various depths has been pointed out and has received like explanation.6 At Goldfield the rocks when rup- tured appear to have been under less load than at Cripple Creek. The evidence furnished by the Assuring is thus in full accord with that derived from the geologic history of the Goldfield region as presented on page 86. a The fault problem: Econ. Geology, vol. 2, 1907, p. 590. b LindgreD. W., and Ransome, F. L., Geology and gold deposits of the Cripple Creek district. Colorado: IJrof. Paper U. S. Geo). Survey No. 54, 1906. p. 167. CHAPTER XIII. THE PAY SHOOTS AND ORES. DISTRIBUTION. In a broad way the general distribution of the ores with reference to the various rock formations has been indicated in the preceding chapter. It is safe to say that over 80 per cent of the gold obtained in the district has come from the intrusive body of dacite that lies just northeast of Goldfield. In this rock chiefly are the Red Top, Laguna, Mohawk, Combination, January, and Florence ore bodies. Next in importance are the ore bodies in andesite, a class of more recent development, which includes the pay shoots of the Little Florence, Rogers, and Engineers' leases, and the deposits near Diamondfield with the exception of the Flat vein on the south side of Black Butte, which is in dacite. The only ore bodies of proved importance in the rhyolite are those of the Sandstorm and Kendall mines, and these are superficial. RELATION TO LEDGES. In some deposits ore and ledge matter are practically coextensive; but usually, and par- ticularly in the larger deposits, the ore constitutes a small part of the entire ledge. This is particularly true in the oxidized zone, where the ledges are wide and irregular and where more or less secondary concentration of the gold has taken place. In such ledges the ore may occur within the mass as irregular pods or bunches, or it may lie on one side of a body of ledge matter, with the country rock forming practically one wall. (See Pis. XVI and XVIII.) SHAPE. Description of the shape of the Goldfield ore bodies is difficult because the ore bodies them- selves are inherently vague. The pay shoots as a rule have nothing to distinguish them struc- turally from barren ledge matter. They have no boundaries other than the invisible limits beyond which the assayer's returns show stoping to be unprofitable. The change from very rich ore to practically barren ledge matter may take place within a short distance, but it is nearly always a gradation, not a definite boundary. The size of pay shoots, and to some extent their shape also, depend, therefore, upon conditions which determine the grade of ore that can be profitably treated at any given time. If the economic boundary between ore and waste be placed at $25 a ton, a given ore body will have a definite shape and size. If the limiting value be reduced to $20 a ton, the same ore bod}^ will be larger. We may assume that its shape will be somewhat similar to that defined by the higher value, but beyond this we can not go without such detailed and systematic exploration of pay shoots as is hardly ever practicable in this district. In reading the following statements as to the form and dimensions of pay shoots these conditions should be kept in mind. In general, the pay shoots are fully as irregular as the ledges with which the}'' are associated. Some of them are roughly equidimensional masses, others are lenticular, some are approxi- mately spindle shaped, with the large axis nearly vertical, and still others are tabular or plate- like, although such sheets of ore are often curiously twisted or warped. The striking feature of the ore bodies as a whole is the absence of, rather than the approximation to, any regularity of form. While many of the pay shoots conform to the trend of the inclosing ledge, others do not. Some idea of the shapes of pay shoots as determined by stoping may be had from Plate XVI, which shows plans of the ore bodies on successive levels of the January mine, with a 158 PAY SHOOTS AND ORES. 159 generalized section through the workings. The change in form in passing from one level to another is very striking, although the levels are only 50 feet (15 meters) apart. Similar changes are shown in the Combination mine, as illustrated in Plate XVIII. In both these mines the ten- dency of the pay shoots to become narrower and more regular with increase of depth, correspond- ing to the tendency already noted in connection with the ledges, is well marked. The richest ore on the upper levels of the Combination mine occurred in chimney-like shoots of short stope length. These either pinched out at slight depth (see p. 213) or merged below with shoots of different form. When the mine was revisited in 1908 it was found that the outlines of the original rich shoots had been in most places obliterated by the enlargement of the stopes in consequence of the lower grade of ore that it is now possible to mill at a profit. Details of the pay shoots of the January and Combination mines will be found on pages 211 to 219. Beyond the fact that their longer dimensions usually lie nearly in the general plane of the ledge the Mohawk pay shoots have little regularity of form, particularly on the upper levels. This may well be seen in the Hayes-Monnette stope (PI. XXI, B), easily reached from the 245-foot level of the main shaft. This is a great chamber, or rather a series of chambers, one opening unexpectedly into another, and without special illumination the visitor finds it difficult to realize its shape or size. It is over 100 feet (30 meters) in height and of very irregular plan, the total stope length being about 75 feet (23 meters). Below the 245-foot level the Hayes- Monnette shoot merges with other pay shoots stoped from the Truett and Frances-Mohawk lease shafts (see PI. XXXIII) and with an irregular chain of ore bodies extending down to the bottom of the main Mohawk workings. Only by long familiarity with the mine or by the aid of a carefully constructed model is it possible to gain any satisfactory conception of the shapes of these pay shoots as indicated by existing stopes. That they are on the whole of flat form and lie generally with the ledge and not across it is shown by figure 15 and Plate XXXIII. Among the pay shoots which approach tabular form may be mentioned the southern part of the main shoot of the Combination mine above the 130-foot level. As worked on this level in 1905, the pay shoot, then known as the No. 2 shoot, was near the hanging wall of the ledge and had a maximum width of about 6 feet (1.8 meters) and a length of 300 feet (91 meters) or more. In 1908, however, the whole ledge had been stoped to a width of 40 feet (12 meters). In spite of the regularity of the ore on this part of the 130-foot level the pay shoot, as shown by Plates XVII and XVIII, does not extend directly clown to the lower levels. The Reilly pay shoot is also of tabular or flat lenticular form, but shows striking changes in dip and strike, as illustrated in figure 16 and Plate XXXV. In the Florence mine the prin- cipal pay shoots are roughly lenticular masses of which the stope length rarely exceeds 100 feet (30 meters). The maximum stoping width of the large Sweeney shoot was about 18 feet (5.5 meters). These masses occur in a very irregular ledge (see pp. 227 to 229) and are not of great persistency in the line of pitch. Even the relatively large Sweeney shoot has a vertical range of little more than 100 feet (30 meters). (See fig. 17.) The pay shoot of the Jumbo mine appears to have more regularity than is usual in this district, but not much is yet known as to its behavior below the 250-foot level. Near the surface the ore body has a practically continuous stope length of over 500 feet (152 meters), and in one or two places is as much as 20 feet (6 meters) m width. Flattened shoots lying in the plane of the ledge, but with stope lengths so short as to sug- gest the pipelike or chimney-like form, occur in the Mushett and Engineers' leases. In the latter mine the pay shoot apparently does not extend below the 300-foot level. The pay shoots of the original Little Florence lease also are roughly lenticular with short stope lengths, and, so far as known, do not extend below a depth of 500 feet (152 meters). In addition to the larger pay shoots, small, irregular, isolated bunches of ore, often of high grade, are rather characteristic of the district. Such were the bodies mined during the early days of Goldfield in the Velvet, St. Ives, Commonwealth, Lone Star, and Simmerone mines and in some of the mines in and near Black Butte. The sudden springing into notice of some hitherto obscure mine in consequence of the discovery of a rich bunch of ore; glowing descriptions of high-grade shipments in the local newspapers; and, in a few weeks or months, 160 THE GEOLOGY AND ORE DEPOSITS OF GOLDFIELD, NEVADA. the cessation of shipments and an unheralded return to prospecting and development — these are the familiar stages of an oft-repeated story in the Goldfield district. The oxidized ore bodies hitherto worked in the Sandstorm and Kendall mines differ from most of the pay shoots of the other mines in that they do not pass downward directly into sulphide ores. As a rule, the ore bunches, which are very irregular, rest upon an uneven although generally nearly horizontal floor of hard, silicified rhyolite, which shows little sulphide miner- alization. Some of these shoots extend from this floor to the surface as nearly vertical pipes. Others are flat-lying masses in which the horizontal dimensions exceed the vertical. Up to the end of 1908 no ore had been found in these mines below a depth of 80 feet (24 meters). As compared with ore bodies of other gold districts, such as Cripple Creek, those of Gold- field are small, although the disparity in size would undoubtedly be less if the definitions of ore and waste were the same in the two districts. One of the largest stopes in the Goldfield district at the end of 1905 was the curved opening on the northern part of the January ledge, which extends from the surface nearly to the 160-foot level. The maximum stope length of this body was about 200 feet (61 meters) and the greatest width of ore about 25 feet (7.6 meters). Another large opening is the Sweeney stope in the Florence mine (PI. XXI, A). From this a lenticular body of ore about 100 feet (30 meters) in diameter and up to 18 feet (5.5 meters) in width was extracted. Of late years some large stopes have been opened in the Combination mine. The so-called "glory hole," of which a view is shown in Plate XXII, A, is an irregular opening probably over 100 feet (30 meters) long, up to 75 feet (23 meters) wide and 80 feet (24 meters) deep, while below it, as shown in Plate XVII, are continuous although narrowing stopes down to the 280-foot level. Another large stope is that east of the main shaft, which on the 130-foot level is nearly 500 feet (152 meters) long and up to 40 feet (12 meters) wide, its height being Irom 100 to 150 feet (30 to 46 meters). The Hayes-Monnette stope in the Mohawk, as already described, is also a large one, and Avhen the new mill of the Goldfield Consolidated Mines Com- pany is in operation some very large openings will undoubtedly be made in the Mohawk ledge, which as yet has supplied only high-grade ore. In comparison with such bodies of ore as were taken from stopes in granite in the Port- land, Stratton's Independence, and Ajax mines at Cripple Creek, the largest known pay shoots at Goldfield are small. The tenor of the ore mined, however, is much higher than in the Colo- rado district. RELATION TO FISSTTRING. Although, as will be fully explained in a later chapter, metasomatic replacement has played no small part in the formation of the ore deposits as a whole, that process and the ores them- selves are very closely controlled by Assuring. Such complete replacement of rock by masses of sulphides as takes place in some limestones, a replacement which in that rock may extend for considerable distances from the fissures supplying the active solutions, is not found at Gold- field. There Assuring, not relative solubility or chemical instability of the country rock, has determined the shape of the deposits. The irregularity of the ore bodies, like that of the ledges, is consequent upon the unusual complexity of the Assuring. In any ore-bearing ledge the ore is found where the Assuring has been most intense and where originally there were abun- dant openings to admit the depositing solutions. The favorable conditions are clearly rather loose, open Assuring or shattering, not followed by any such extensive movement as would squeeze the shattered material together and clog the interstices between the fragments with impervious gouge. In many places there appears to be a close connection between ore depo- sition and the intersections or junctions of divergent zones of. Assuring. Good examples of this feature are found on the 80-foot and 130-foot levels of the Combination mine (see PI. XVIII), and in the Rogers, Sandstorm, and Kendall mines. As stated on page 156, some ore bodies show recurrent Assuring; where ore is traversed by later Assures, these and the material adja- cent to them are usually richer than the rest of the ore. Such later Assuring may thus modify the original shape of an ore body. U. S. GEOLOGICAL SURVEY PROFESSIONAL PAPER 66 PLATE XXI .1. PART OF THE SWEENEY STOPE IN THE FLORENCE MINE. Note shattered ledge matter and absence of any regular boundary between ore and waste. B. THE HAYES-MONNETTE STOPE IN 1906. Afterward much enlarged. Photograph by P. E. Larson. * U^PM #W LU z LU o z LU (T O _l LU I h Ll o _l LU > H O o LL o m LU I \- X LU h h < LU C5 Q LU _l z o < z CQ o o LU I LU _l o I > cc o _l o I PAY SHOOTS AND OBES. 161 Mere character of Assuring, however, as visible within a few hundred feet of the surface, is only one of several factors determining ore deposition. The district abounds in illustrations of the fact that Assuring, apparently of the most favorable kind, is not necessarily followed by the accumulation of an ore body. The fissure complex must evidently be connected with still deeper channels in such a way as to give access to ore-bearing solutions, and probably also with lateral and superficial channels through which other solutions could pass to mingle with the waters of deep origin and precipitate their valuable constituents. Thus locality and the features of a former topography were probably both of great importance in determining whether a given mass of shattered rock should become an ore body. That some further modifications of the original shapes of pay shoots take place in the course of oxidation is highly probable, although the steps of such change can not usually be traced. Oxidation implies changes in volume of the constituents of the mass with more or less gravitative readjustment or settling, minor Assuring, and some migration of material by resolution and redeposition. EFFECTS OF FAULTING. So far as known the ore bodies have not as a rule been greatly modified by faulting subse- quent to ore deposition. In this respect they differ in striking fashion from the veins of Tonopah. It must be pointed out, however, that the difficulties in the way of the recognition of notable faulting at Goldfield are very great. The ability to recognize important dislocations depends very largely upon the degree to which the faulted structures were initially regular and persistent. When, for example, a well-defined regular vein which has been followed for some hundreds of feet ends abruptly at a fissure filled with attrition products, faulting is at once suggested and in many cases is easily demonstrated. At Goldfield, however, the initial regu- larity is lacking. It is known that ore bodies in this district show unexpected and erratic changes in direction and may terminate abruptly without faulting. There is in many cases no a priori ground for supposing that beyond the apparent end of an ore shoot is another body, once continuous with it, but now displaced. The evidence of movement both in and around the Goldfield ore bodies is abundant, but the interpretation of this movement — the discrim- ination between slips of structural importance and those whose total displacement is measurable in inches rather than feet — is as a rule impossible or inconclusive. If a pay shoot ends at a seam of gouge, and if a few hundred feet away another pay shoot is found on the other side of a similar gouge-filled fissure, there is as a rule no means of identifying the two bodies as origi- nally part of the same mass, nor can it be assumed in this district, where gouge seams are known to bend through angles of 90° or more, that the gouge in contact with the two masses of ore occupies one continuous fissure. The difficulty in the way of identifying gouge-filled fissures from point to point by means of a few isolated exposures is well illustrated by the plan (fig. 18) of the 350-foot level of the Mohawk mine, a level on which the so-called hanging wall of the ledge is visible at more places than elsewhere in the mine. Near the upper Curtis shaft this wall, which is defined by a gouge seam dividing ore or ledge matter from soft, altered dacite, has a curved but generally northerly course. Near the Mohawk shaft the hanging wall swings to the east and a similar seam of gouge traverses the ledge matter, passing through the shaft. The two fissures must join or intersect about 100 feet south of the main shaft. Near the Mohawk-Jumbo stope the hanging wall turns northwest. As a whole it is a very sinuous curve. The hanging wall is probably not a single fissure, but a series of fissures, each one of which serves as hanging wall for a short distance and then passes either into ledge or country rock. The significance of this is that the hanging wall is probably as erratic in section as it is in plan. Neither in plan nor section can its true course be drawn from a few isolated exposures. The conditions as regards faulting may perhaps be best understood by keeping in mind the facts that the ledges as a whole are hard, brittle masses of irregular contour, and that the altered country rock in which they lie is as a rule soft and plastic. The result of any compe- tent compressive stresses applied to the whole system would be to cause more or less slow 79145— No. 66—09 11 PLATE XXIII. Ore Structures (natural size). A. Very rich ore (G. 604). Combination mine. Polished face of altered dacite (d). Part of a fragment coated with gold and sulphides. The inner dark band to the right is gold in quartz. The outer dark band, separated from the gold by a narrow indistinct film of quartz, is famatinite. The external coating is chiefly alunite and pyrite. The photomicrograph of Plate XXVI, A, is from the same specimen. B. Marcasite (G. 643). Florence mine. Incrusts a fragment of altered dacite. The white material partly cov- ering the botryoidal marcasite is alunite. C. Rich ore (G. 809). January mine. Polished face. The gray matrix is quartz. The irregular dark inclusions in the right-hand third of the specimen are famatinite; those in the left-hand third are bismuthinite; those in the middle zone are mostly bismuthinite, but some are famatinite. D. Rich ore (G. 641). Florence mine. Polished face. Shows fragments of altered dacite coated with gold and sulphides. Interstices are filled with spongy quartz. Order of deposition from within out is gold, pyrite, famatinite, quartz. Gold is not visible in all of the fragments and in none of them forms a complete envelope. The specimen illustrates modification of shape of original dacite fragments by alteration and solution. Most of them have, inside of the sulphide shells, a shadowy envelope of cryptocrystalline quartz. This grades irregularly toward thecenterinto alunitized dacite, which still retains traces of its original texture. The gold particles are for the most part clustered in this siliceous envelope. E. Ore (G. 628). Florence mine. Polished face. Shows part of a fragment of altered dacite with shell of sul- phides and quartz on left-hand side. The dacite fragment records at least two periods of Assuring and quartz depo- sition prior to the deposition of the sulphide shell. F. Ore (G. 88). January mine. Polished face. Shows a fragment of altered dacite with outline modified by solution, incrusted with quartz, famatinite, bismuthinite, and pyrite. Gold is probably present, but is not visible. The dacite kernel contains alunite pseudomorphs after feldspar and, like the specimen illustrated by figure E, was fissured and at least partly altered prior to the envelopment of the fragment by sulphides. The peripheral shells, from within out, are (1) a thin film of quartz, (2) a thin film of pyrite, and (3) an aggregate of quartz, bismuthinite, and famatinite much like that in figure C. PLATE XXIV. Ore Structures (natural size). A. Rich nodular ore (G. 642). Florence mine. Fracture surface. A kernel of altered dacite is enveloped (1) by a not wholly continuous film of pyrite, (2) by a shell of famatinite, and (3) by a thick crust of dark cryptocrys- talline quartz carrying famatinite, bismuthinite, and native gold. B. Oxidized ore (G. 718). Red Top mine. Shows cavernous texture of cryptocrystalline quartz. 164 U. S. GEOLOGICAL SURVEY PROFESSIONAL PAPER 66 PLATE XXIII D .'3 ORE STRUCTURES. U. S. GEOLOGICAL SURVEY PROFESSIONAL PAPER 66 PLATE XXIV ORE STRUCTURES. PAY SHOOTS AND ORES. 165 MINERALOGICAL AND CHEMICAL CHARACTER OF THE SULPHIDE ORES. The typical unoxidized ore as it occurs in the dacite or andesite near Goldfield, particu- larly in the mines south of the Mohawk, consists of pyrite, bismuthinite, and a reddish-gray cupriferous mineral having the general composition of an arsenical famatinite (seep. 118), in a rather dark gray, flinty, quartz gangue. Native gold is usually associated with these min- erals, particularly with the bismuthinite and famatinite, and in the rich ore may be easily visible. In ore of the Mohawk type, however, the gold is as a rule less conspicuous. The native gold is in many ores embedded chiefly in the quartz, but it may occur also in minute particles in bismuthinite, goldfieldite, or famatinite. Concentric shells of ore minerals about greatly altered rock fragments are rather charac- teristic of the best ore. (See Pis. XXIII, XXIV, and XXV.) Specimens from the Combina- tion mine (PI. XXIII, A) show an inner zone of free gold and quartz up to an eighth of an inch in thickness. This is covered by a shell of famatinite and this by an outer crust of pyrite. In the Florence mine similar fragments (PI. XXIV, A) show, first, a shell of pyrite, then one of famatinite, and, finally, a thick crust of quartz speckled with native gold, famatinite, and pyrite, and transfixed by needles of bismuthinite. Some of the particles of gold are embedded in the compact quartz, others are inclosed in the bismuthinite. The different crusts are not in every case sharply defined nor are they necessarily continuous. In the ore of the Engineers' lease two distinct crusts of gold have been observed. Thus in the specimen illustrated in Plate XXV, B, there is, next to the fragment of altered andesite, a thin discontinuous film of famatinite covered in places by a similar film of gold. Outside of this is a relatively thick layer of quartz and bismuthinite needles. Incrrsting this is a second shell of gold particles in quartz about one-sixteenth of an inch in thickness. This in turn is covered by a skin of drusy quartz or is succeeded by a mass of cemented fragments of flinty quartz containing gold, famatinite, bismuthinite, and pyrite irregularly distributed through it. Another specimen from the same lease is shown in Plate XXV, A. Here the andesite frag- ments, which are silicified and full of fine pyrite, are coated first with pyrite, then with famatinite, ami then with bismuthinite, all in very thin shells. Outside of these is an envelope of gold and outside of this envelope a thick shell of dark-gray dense quartz carrying gold and needles of bismuthinite. Both specimens are shown in natural size. The native gold of these ores is often in particles so fine and so closely crowded in the gangue that the precious metal resembles a streak of yellow ocher, and it is only under a lens that the luster of the particles appears truly metallic. Opportunities for examining the richest Mohawk ore in place were not paiticularly good at the time of the visit in 1908. Specimens which were seen, however, show the same habit of crustification around fragments of rock as has been described. In the Mohawk ore, however, the most valuable crust is not a yellow aggregate of quartz and gold, but a dark-gray mixture of goldfieldite, and native gold, closely associated with marcasite, as described on page 116. The ore of the Mushett lease on the Miss Jessie claim northeast of the Red Top mine is structurally and mineralogically one of the most interesting in the district. The proportion of sulphides to gangue is greater than in most of the mines. The metallic minerals noted are pyrite, famatinite, bismuthinite, sphalerite, and a dark-gray mineral identical in appearance wTith that analyzed and described on page 116, and probably like it the new species goldfieldite. This material is rich in gold, specimens which to the naked eye show not a particle of the native metal yielding over $8,000 a ton on assay. The crustification in the Mushett ore is not very regular, but the minerals have formed in the following general succession: (1 ) Pyrite; (2) fama- tinite, bismuthinite, goldfieldite; (3) sphalerite; and (4) pyrite. The sphalerite in some places forms botryoidal crusts over the prisms of bismuthinite, which attain a larger size in this ore body than in other known occurrences in the district. The material forming the extreme outeV crust of the nodular ores of Goldfield or filling interstices between the altered and incrusted rock fragments is in most places a soft mixture of alunite and pyrite. 166 THE GEOLOGY AND ORE DEPOSITS OF GOLDFIELD, NEVADA. The appearance of some of the typical rich ores in thin section under the microscope is illustrated in Plates XXVI and XXVII, which are accompanied by full descriptive notes. The very fine grain of the flinty quartz gangue is shown in these photomicrographs. The proportion of silver in the Goldfield ores is usually rather small, the average of 34 assays of rich ore from the Mohawk mine, made for Mr. J. W. Finch, at one time general manager, giving 330 fine ounces of gold and 46.5 ounces of silver to the ton. In the Florence mine the ore of the deeper levels contains more copper and silver than that near the surface. A shipment from the 250-foot level in 1905 contained 100.8 ounces of gold and 3.5 ounces of silver per ton, and 3.5 per cent of copper. The highest silver assays from the upper levels, according to Mr. Frank Oliver, formerly superintendent of the mine, was less than 2 ounces per ton. There are some indications of a similar change in the Combination mine as regards the relation of silver and gold. A specimen of heavily pyritized dacite collected in 1905 from the 230-foot level was sent to E. E. Burlingame & Co., Denver, for assay. This material, apparently consisting entirely of pyrite, quartz, and a little alunite, afforded 0.68 ounce of gold and 2.72 ounces of silver per ton. The sample was chosen in an attempt to find material representative of a type of ore likely to prevail at greater depths than 500 feet (152 meters). The ores near Diamond- field generally contain a larger proportion of silver than those near Goldfield. Tests and chemical analyses of the ores made for scientific and technical purposes have from the first nearly all shown a little tellurium, although no tellurium mineral was recognized in the mines close to Goldfield until the discovery of the Mohawk ore bodies. Tellurides of gold, not sufficiently well crystallized for a determination of their species, occur in the Jumbo Exten- sion and Goldfield-Behnont mines, near Diamondfield, and both tellurite and emmonsite (or durdenite) were found in 1905 in the oxidized ore of neighboring properties." W. F. Hillebrand has detected some selenium with the tellurium of these minerals. The tellurides are in some cases intergrown with native gold. Most of the analyses of Mohawk ores made in connection with the prosecution of ore thieves show about 2 per cent of tellurium, which, as explained on page 116, is probably due mainly to the presence of goldfieldite. The first sphalerite found in the ores of the district appears to have been a small speck noted in the Goldfield-Belmont mine by Mr. W. H. Blackburn in 1905. The mineral has since been found to be abundant in the Mushett and neighboring leases near Goldfield, where it formed sub- sequently to the rich ore. Galena was unknown in the Goldfield district in 1905. It has latterly been observed in several leases, as noted on page 112. Chalcopyrite, a common mineral in most mining districts, was not found at Goldfield in the course of the present investigation, but it is said to occur sparingly in the Sandstorm and Florence mines. E. A. Collins6 notes very small quantities of chalcopyrite and zinc blende in the Com- bination ore. The common gangue of the unoxidized ore is quartz. This is usually compact, almost flinty, in texture, although porous in mass, and in most cases bears unmistakable evidence of having resulted from the silicification of dacite, andesite, or latite. Large vugs and conspicu- ously crystalline quartz, such as are found in typical veins the world over, are practically absent from the Goldfield district, where the free development of quartz crystals in open spaces is repre- sented only by drusy films, lining pores left by the solution of phenocrysts, or incrusting small interstitial cavities in brecciated material. The appearance of typical quartz gangue as seen in thin section under the microscope is shown in Plates XXVI and XXVII. Even where the quartz, as in Plate XXIII, C, does not appear to have directly replaced a mass of rock, it is always cryptocrystalline and is usually full of little vugs. In such cases it appears to have filled spaces an inch or two across by the slow concretion of thin films on projecting crystals of bis- muthinite and by the final coalescence of these films, leaving only a few small vugs. In other " Ransome, F. L., Preliminary account of Goldfield, Bullfrog, and other mining districts in southern Nevada: Bull. U. S. Geol. Survey No. 303, 1907, p. 36. & The Combination mine: Min. and Sci. Press, September 28, i907, p. 398. PLATE XXV. PLATE XXV. Ore Structures (natural size). A. Rich nodular ore (G. 995). Engineers' lease. Polished surface. Fragments of altered andesite, silicified and pyritized, with an envelope of at least six layers. Next to the andesite is a thin irregular shell of pyrite. Outside of this is a shell of farnatinite. Outside of the famatinite is a nonnietallic film, probably alunite and quartz, which shows as a white line in the illustration. Outside of this is a thin layer of quartz containing particles of famatinite. Enveloping this is another shell of quartz containing minute gray needles which are probably bismuthinite. Cover- ing this is a yellow envelope of quartz and gold. Last is a thick outer shell of quartz, bismuthinite, and gold. B. Rich ore (G. 994). Engineers' lease. Polished surface. At top is a fragment of altered andesite. Under this is a thin film of famatinite, gold, and quartz. This is succeeded by a broad dark band, which is an aggregate of quartz and bismuthinite. Below this is a second band of gold and quartz. The lower part of the specimen is a mass of cemented flinty quartz fragments carrying famatinite, bismuthinite, pyrite, and gold. The white areas are alunite. U S GEOLOGICAL SURVEY PROFESSIONAL PAPER NO. 66 PLATE XX\ ■ ■ ■ ORE ST1U"( Tl'KKS PAY SHOOTS AND ORES. 167 cases the films have started from fragments of rock lying in the cavity or fissure and have gradually thickened until the space became filled. Associated with the quartz in much of the ore are soft white substances, such as the miners commonly call "talc." Chemical and microscopical tests of the white material show that in most cases it is either alunite or kaolinite or a mixture of the two." Sericite, supposed when the preliminary report6 on the district was written to be also abundant, proves on further study ■ to be very rare and is certainly nowhere an abundant or characteristic mineral in the ore deposits. Gypsum, while not known with actual sulphide ore, is very abundant in the altered rocks within a hundred feet or so from the surface, and does occur crystallized with quartz and pynte in the Goldfield-Belmont mine, below the belt of oxidation. As a rule, the gold and auriferous sulphides are embedded in quartz. Alunite, however is often so close to the gold as to appear in the same microscopic field, and the telluride of gold in the Jumbo Extension mine is partly embedded in alunite. Some idea of the chemical composition of typical rich dacite ore may be had from the following analyses of unoxidized ore from the Mohawk mine kindly furnished by Mr J W Finch, consulting geologist for the Goldfield Consolidated Mines Company, and by Mr Charles S. Thomas, jr. These analyses are given in the form reported by the analysts to the company smce in most cases they contain ambiguities, like "iron oxide," not safely translatable into more scientific expressions. Analysis of composite sample of nine lots of Mohawk ore shipped early in 1907. [Lochiel M. King, analyst. Reported February 13, 1907.] Water (combined) 7_ 00 Silica (Si02) 6a 30 Copper (Cu) 2. 08 Bismuth (Bi) 35 Tellurium (Te) 2. 42 Antimony (Sb) Traces. Ir°n (Fe) 3 83 Alumina (Al20.t) 9 09 Zinc (Zn) Very slight traces. Lime (CaO) 0 00 Magnesia (MgO) 24 Sulphur (S) 6' 30 Gold (Au) 2.00 Silver (Ag) 25 Unaccounted for 14 100. 00 It may be noted in connection with the foregoing analysis that 2 per cent of gold is equiva- lent to 40 pounds avoirdupois, or 541.4 fine ounces per ton. Analyses of Mohawk ore. [W. D. Arnett & Co., analysts. Reported December 17, 1906.] Silica Iron oxide Aluminum oxide Magnesium oxide Manganese oxide Calcium oxide Potassium oxide Sodium oxide Copper Gold Silver .'. Bismuth Tellurium Water Carbon dioxide Sulphur 66.65 6.05 9.27 .054 .18 .95 2.71 3.16 1.76 1.004 .078 .67 .42 .71 .61 5.76 100. 036 77.08 5.18 4.96 .067 .15 .71 1.42 3.22 .37 .45 .07 Trace. .14 .64 .93 4.80 100. 187 65.87 03.63 4.29 3.96 6.20 11.62 .04 . 068 .22 .16 .58 1.17 1.66 1.50 3.21 4.07 1.548 1.014 1.062 .633 .084 .111 .82 1.09 .74 1.21 .73 .63 .66 .72 12.69 8.86 100. 354 51.31 7.80 11.28 .072 .34 1.34 1.82 4.66 2.563 .733 .185 2.91 1.07 .76 1.74 11.98 100. 446 100.563 «E A. Collins, in his recent good description of the Combination mine (Min. and Sci Press vol 95 1907 n scsi ,of»,.„ t ♦,, 7, of soft kaolinized material and hard dacite." The « kaolinized material - is chiefly alunite * ?" >' ^ ^ M a mixture & Bull. U. S. Geol Survey No. 303, 1907, p. 35. PLATE XXVI. Photomicrographs of ores. A. Very rich ore (G. 604). Combination mine. Right-hand side of section shows altered dacite, consisting of quartz, kaolinite (k), alunite, and finely disseminated pyrite. To the left of this is a band (about 3 inches wide in the illustration), consisting of finely divided native gold, famatinite, and bismuthinite in a gangue of minutely granular quartz. The gold, famatinite, and bismuthinite all appear black in the microphotograph, but over 75 per cent of these black areas represent gold. To the left of this band the quartz is a little more coarsely crystalline and contains bismuthinite and famatinite, with subordinate native gold. The specimen from which this section was made is shown in Plate XXIII, A. Nicols crossed. Magnified 40 diameters. B. Rich ore (G. 389). Combination mine, 180-foot level. The large black area, a little to the right of the center of the photomicrograph, is chiefly pyrite (p). The smaller black areas above it, however, are famatinite (t), inclosing particles of native gold. Some of the smaller black specks are gold alone. The matrix or gangue is dacite, altered to an aggregate of quartz, alunite, and probably some kaolinite. A few of the original quartz phenocrysts (q) appear in the illustration, while larger and more characteristic ones occur in parts of the thin section not included in the photograph. Nicols crossed. Magnified 40 diameters. PLATE XXVII. Photomicrographs of Ores. A. Rich ore (G. 627). Intermediate or 300-foot level of Florence mine. The order of deposition is from the lower left-hand corner of the photomicrograph to the upper right-hand corner. The large black areas in the lower left-hand corner are pyrite (p) and famatinite (t), forming a crust on silicified dacite (dq). The famatinite generally envelops the pyrite. Deposited upon these is a crust of fine granular quartz (q) and irregular prismatic crystals of bismuthinite (b). Holes in section (h). No gold is visible in this particular section. Nicols crossed. Magnified 40 diameters. B. Ore (G. 87). January mine. Illustrates structure resulting from silicification of much brecciated dacite. The black areas are famatinite (t) and pyrite (p), in many places intergrown. These are surrounded by a very fine- grained aggregate of quartz. The more coarsely crystalline quartz (q) contains a few vugs (h). Nicols crossed. Mag- nified 40 diameters. 168 U. S. GEOLOGICAL SURVEY PROFESSIONAL PAPER 66 PLATE XXVI PHOTOMICROGRAPHS OF ORES. U. S. GEOLOGICAL SURVEY PROFESSIONAL PAPER 66 PLATE XXVII 7 . ;..' -,'>^h.iv::y\ [XQMjlTI ^ WTOM ■VrfJSfcfc* i. -2£3£ is2Y?ij^l6ii'^ K^^^x 4rt£r^5^Bp3 < W&$3* RB^SL^MHBK. ^JuJPWw^ "• HrS?f^ t P i nl is? " IK J ;':: P "* t r 1/^ -f > ; •■"■ »" ■**■■!■ i ■•fcjRX PHOTOMICROGRAPHS OF ORES. PAY SHOOTS AND ORES. 169 Analyses of Mohawk ore — Continued. LVou Schulz & Low, analysts. Reported February 27, 1907.] Silica Iron Alumina Manganese Bismuth Lead Copper Nickel and cobalt. . . Arsenic Antimony Gold Silver Zinc Magnesium oxide. . . Calcium oxide Sodium oxide Potassium oxide Barium oxide Sulphur..., Phosphorus Tellurium Moisture (at 110° C.) Undetermined a G7. 24 5.55 5.85 .14 1.20 Trace. 2.38 .05 .14 .26 1.20 .24 .13 .14 .45 .10 .27 .10 5.44 .06 2.03 .02 7.15 100. 00 07. 10 5.82 5.02 .10 1.25 Trace. 2.56 .06 .10 .21 1.21 .23 . 16 .20 .42 .15 .22 .27 5.33 .08 2.21 .01 7.19 66.70 5.35 5 34 .14 1.27 Trace. 2.50 .07 .15 .32 1.24 .23 .11 .12 .41 .12 .28 .24 5.46 .07 2.07 .04 7.77 100. 00 100.00 9. 68. OS 5.65 5.25 .12 1.32 Trace. 2.53 .07 .14 .32 1.22 .24 .19 .19 .47 .14 .22 .17 5.38 .08 2.11 .02 6.19 100. 00 a This is probably in part combined water and in part oxygen combined with various bases.— V. S. & L. All of the foregoing analyses were made on material recovered from thieves or "high- graders." Those which follow were made on ore taken by Mr. Thomas from the 220-foot level of the Hayes-Monnette workings. Analyses of Mohawk ore. [Von Schulz & Low, analysts. Reported April 22, 1907.] Silica Iron Alumina Manganese Bismuth Lead Copper Nickel and cobalt... Arsenic Antimony Gold Silver Zinc Magnesium oxide. . . Calcium oxide Sodium oxide Potassium oxide Barium oxide Sulphur Phosphorus Tellurium Moisture (at 110° C.) Undetermined 10. 64.28 6.92 6.18 .12 1.22 Trace. 2.35 .06 .11 .30 1.22 .28 .14 .19 .49 .12 .27 .19 5. 39 .07 2.11 .03 8.16 100. 00 11. 68.46 5.21 5.04 .12 1.25 Trace. 2.42 .05 .10 .25 1.30 .25 .11 .17 .45 .12 .26 .21 5.24 .08 2.10 .02 5.79 12. 1. 67.27 5.82 5.65 .18 1.36 Trace. 2.29 .08 .15 .36 .49 .29 .16 .20 .45 .15 .26 .14 5.26 .05 2.27 .02 6.10 100. 00 100 00 13. 68.40 5.61 5.44 .15 1.21 Trace. 2.49 .07 .12 .28 1.33 .25 .19 .19 .42 .14 .25 .21 5.48 .06 2.06 .04 5.61 100. 00 14. 67.20 5.47 5.82 .10 1.18 Trace. 2.36 .07 .15 .26 1.37 .25 .17 .10 .46 .11 .24 .24 6. 44 .06 2.14 .03 6.69 100. 00 15. 67.98 5.28 5.86 .11 1.20 Trace. 2.39 .06 .15 .35 1.34 .26 .14 .18 .46 .14 .27 .20 5.45 .08 2.12 .03 5.98 100. 00 PARAGENESIS. The paragenesis or order of formation of the minerals in the unoxidized ores is, as in most ore bodies, complex. In general the deposition of pyrite, quartz, and alunite appears to have gone on throughout the entire period of ledge formation. On the other hand, there is abundant evidence to show that much of the gold, tellurides, bismuthinite, goldfieldite, marcasite, and famatinite were introduced after considerable progress had been made in the special kind of rock alteration which produced the ledges. It appears that some at least of these siliceous masses were fractured and that the richest ores were deposited in the shattered portions. 170 THE GEOLOGY AND ORE DEPOSITS OF GOLDFIELD, NEVADA. The following sequences have been observed in the rich crustified ore : Combination mine: (1) Altered latite; (2) marcasite and goldfieldite; (3) gold and quartz; (4) famatinite and bis- mutbinite. (1) Altered dacite; (2) pyrite; (3) quartz; (4) pyrite; (5) alunite. (1) Altered dacite; (2) gold and quartz; (3) famatinite; (4) bismuthinite and quartz. (1) Altered dacite; (2) gold and quartz; (3) famatinite, bismuthinite, famatinite, and gold in quartz; (4) pyrite and alunite. Florence mine: (1) Altered andesite or dacite; (2) pyrite; (3) famatinite and gold; (4) bismuthinite, gold, and quartz with some pyrite and famatinite. (1) Altered dacite; (2) pyrite; (3) famatinite and quartz. (1) Altered dacite or andesite ; (2) pyrite; (3) famatinite; (4) bismuthinite and quartz; (5) pyrite, quartz, and alunite. Mushett lease: (1) Altered dacite; (2) goldfieldite; (3) famatinite, bismuthinite, and quartz; (4) pyrite, sphalerite, and alunite. (1) Altered dacite; (2) pyrite; (3) sphalerite; (4) alunite. (1) Bismuthinite; (2) pyrite, sphalerite, and alunite; (3) sphalerite; (4) alunite. (1) Bismuthinite, telluride (?), and famatinite; (2) sphalerite; (3) pyrite and alunite. Engineers' lease: (1) Altered andesite; (2) famatinite; (3) pyrite and famatinite in massive aggregate. (1) Altered andesite; (2) famatinite; (3) bismuthinite, quartz, and a little gold; (4) gold and quartz; (5) gold, bismuthinite, and quartz. (1) Altered andesite; (2) famatinite; (3) gold and quartz; (4) bismuthinite and quartz; (5) gold and quartz; (6) quartz; (7) alunite. Rogers lease: (1) Altered andesite; (2) gold and quartz; (3) bismuthinite, famatinite, gold, and quartz. (1) Altered andesite; (2) gold and dark quartz; (3) white quartz. Little Florence lease: (1) famatinite; (2) bismuthinite and quartz; (3) gold and quartz; (4) pyrite and alunite. (1) pyrite, quartz, and alunite; (2) famatinite; (3) bismuthinite and quartz. Consolidated Red Top lease: (1) pyrite and quartz; (2) famatinite; (3) pyrite or marcasite, alunite, and barite. Attempts to fit the foregoing observations into a single definite general sequence have not been successful. In some specimens there are repetitions not found in others. In some speci- mens certain of the minerals have formed in definite succession while in others these same constituents have crystallized together in a single crust. The altered rock on which the first crust is deposited generally contains abundant alunite and disseminated pyrite. In some varieties of ore the boundary between this nucleus and the first crust is definite (see PI. XXIII) ; in others there is more or less gradation, the disseminated p}Trite in some cases becoming more abundant near the surface of the rock fragment and merging with the first pyritic crust. As a rule famatinite has formed before the bismuthinite, although both minerals are indiscrimi- nately distributed through some crusts. When marcasite is present as a constituent of rich ore it is closely associated with famatinite or goldfieldite. The free gold and bismuthinite are generally in close association, although in some specimens the greater part of the gold is of earlier generation than the bismuthinite and in others is later. Sphalerite, galena, and mar- casite, where present with rich ore, belong to a period of deposition later than that of the gold or gold-bearing constituents. MINERALOGICAL CHARACTER OF THE OXIDIZED ORES. Oxidized ores have supplied a large part of the gold produced, and in some mines, particu- larly the Sandstorm and Kendall, no sulphide ores are as yet known. As a rule the oxidized ore is a soft, shattered, more or less earthy material usually stained brown by oxide of iron. Fragments of rusty porous quartz are mingled with kaolin, alunite, gypsum, alum (halotrichite), oxide of iron, and various earthy mixtures of no definite mineral composition. Some of the rich ore, as in the Sandstorm mine, is a nearly white, impure kaolin, gritty from the presence of minute crystals or grains of quartz, and containing all through it abundant specks of free gold. Barite, in crystals up to an inch in length, is abundant in this ore, but may be an original con- stituent. In the Red Top mine some of the richest ore being taken out in 1905 was a firmgritty ocher, of bright yellow color, containing abundant very fine particles of gold. This yellow PAY SHOOTS AND ORES. 171 material is perhaps in part jarosite.a In the January and Combination mines some of the most characteristic rich ore consists of porous rusty quartz (silicified dacite), in which the pores and crevices are partly filled with yellow, earthy limonite and tiny pearly scales of bismite, the oxide of bismuth. In some specimens these scales form pseudomorphs after bismuthinite. They are usually a sign of rich ore, but are occasionally found in low-grade or barren material. Halotrichite, a member of the alum group, and alunite are rather abundant in the oxidized ore of the January mine. In the mines at Black Butte the richest oxidized ore usually shows little greenish-yellow specks of a ferric tellurite, which Dr. W. F. Hillebrand has determined to be either emmonsite or durdenite. The presence of this mineral shows that the original sulphide ore contained one or more tellurides. Tellurite, a honey-yellow crystalline mineral, which is the oxide of tellurium and should not be confused with the salts of tellurous acid known to chemists as tellurites, was noted in a partly oxidized telluride ore from the Goldfield-Belmont mine near Black Butte. Melanterite (hydrous ferrous sulphate), in some cases mixed with a very little chalcanthite (hydrous copper sulphate) , occurs in the partly oxidized ore of the Combination and Florence mines. The valuable constituent of the oxidized ores is native gold. Native silver and halogen compounds of silver have not, so far as known, been noted in the mines of the Goldfield group, but cerargyrite and probably a little embolite occur in some of the Diamondfield ores. The gold, which has undoubtedly undergone some concentration in the process of oxidation, is in most of the ores finely divided, and even in the richest ores might easily be overlooked by one not accustomed to its appearance. Some of the Sandstorm ore on close examination resembles a fine, somewhat rusty sandstone having gold as the cementing material. VALUE OF THE ORES. As a whole the ores thus far mined at Goldfield are unusually rich. Prior to January 1, 1905, the Combination mine shipped a total of ] ,166 tons of ore, having an average assay value of $419 per ton. This ore averaged 20.22 ounces of gold and 2.68 ounces of silver per ton. The best ore from the mine was taken from the small No. 3 shaft, which afforded about 309 tons, valued at $159,000, or $514 per ton. Approximately 59 tons of this averaged, according to Mr. Edgar A. Collins, 54.8 ounces of gold per ton, which is equivalent to a value of nearly $1,100. This ore, which was oxidized, contained only 1 ounce of silver to each 20 ounces of gold. J. E. Spurr 6 estimated in 1904 that the average value of the ores mined in the Goldfield district was from $200 to $300 per ton or more. In 1905 the average value of shipping ore was about $200 per ton and of milling ore from $40 to $50 per ton. Shipments averaging over $1,000 per ton are by no means uncommon. One of 14£ tons from the Kendall mine is said by Spurr c to have yielded $45,783 net in the preliminary milling, while the tailings still contained about $1,000 a ton. A shipment of sulphide ore from the Florence mine, made in 1905, just before the date of visit, averaged 100.8 ounces of gold, 3.5 ounces of silver, and 3.5 per cent of copper, giving a gross value of over $2,000 per ton. The silver in this shipment was unusually high for an ore from this part of the district. Some extremely rich ore was obtained from the Reilly lease, occasional specimens several inches in diameter being nearly one-half gold. Several shipments from this lease are said to have assayed $20,000 a ton, and, according to Mr. Frank Oliver, one lot of over 4 tons was worth $6,000 to $7,000 a ton. Some of the ore from the vicinity of Diamondfield carries a greater proportion of silver than that from the mines near Goldfield. A specimen containing famatinite, taken from the Quartzite mine of Black Butte, yielded on assay 11.06 ounces of gold and 115.70 ounces of silver per ton. Samples of mineralogically similar ore from the Goldfield-Belmont mine assay, a Spurr, J. E., Ores of Goldfield, Nev.: Bull. U. S. Geol. Survey No. 260, 1905, p. 137. b Bull. U. S. Geol. Survey No. 260, 1905, p. 136. c Op. cit., p. 136. 172 THE GEOLOGY AND ORE DEPOSITS OF GOLDFIELD, NEVADA. according to Mr. W. H. Blackburn, yielded 1 to 2 ounces of gold and from 30 to 60 ounces of silver per ton. A similar high proportion of silver is found in the ore of the Jumbo Extension mine. Some bunches of ore in the Blue Bull mine also show a very high proportion of silver, one assay giving 382 times as much silver as gold." Some ore from the Hat lease on the Blue Bull ground assayed 174 ounces of silver and 4 ounces of gold to the ton. Such ratios, how- ever, are very uncommon. Although, as is to be expected in a new district, much of the very rich ore has been oxi- dized, yet some of the sulphides in the mines near Goldfield have exceeded in value anything found in the oxidized zone above them. Such was the case in part of the Combination mine, and in the Reilly workings. A still more striking example of the wonderful richness of some of the sulphide ores is furnished by the Hayes-Monnette Mohawk lease. From the ore body discovered by these lessees there was shipped in January, 1907, to the Selby Smelting and Lead Company, the richest carload of ore ever sent out of the district. The net weight of this ore was 95,537} pounds. It assayed (dry) 609.61 ounces of gold and 75.38 ounces of silver per ton. The gold was paid for at $20 an ounce on the assay return; the silver at 68f cents an ounce, after deduction of 5 per cent for loss in smelting. Cost of treatment was $10.50 per ton, sampling and assaying $150, refining $327.22, and expressage $8,810.50. The net proceeds received by the shippers from the smelter were $574,958.39 for the single car of ore. Even richer ore (620 ounces of gold to the ton) was being sacked under the old Reilly workings, on the 280-foot level of the Combination mine, in 1908. One of the richest carloads of unsorted ore shipped from the district was from the lease of the Florence Annex Company on the Cornishman and Firelight claims in the latter part of 1907. This lot weighed 40 tons and assayed $948 per ton, corresponding to a total gross value of $37,920. AREAL VARIATIONS IN THE ORES. Although all of the Goldfield ores have certain mineralogical and chemical features in common, there are some well-marked differences in the ores from different parts of the district. Some of the most interesting and important changes are those which may be observed in pass- ing from the Rogers lease at the south end of the Goldfield bonanza belt to the Mushett lease at the north end, a distance of a little less than a mile. By this it is not meant that no rich ore occurs north or south of these leases, but merely that these mark the limits of the most productive area as at present known. From the Rogers lease to the Combination mine the ore of the rich pay shoots is all much alike, although as a rule the product of each mine has slight individual peculiarities whereby one thoroughly familiar with the different workings can identify it. The essential characteristics of this ore are the presence of visible native gold, so distributed through the flinty quartz as to form the dull yellow crusts already described, the presence of abundant bismuthinite and famatinite, and the absence of recognizable tellu- rides, sphalerite, or galena. The quartz varies in color from nearly white, as in some of the Rogers ore, to a dark gray, as in some of the Engineers' ore. The famatinite or bismuthinite are not equally prominent in all of the ore, nor is the relation of the gold to these minerals exactly the same in each pay shoot. The gold in some stopes may occur in the hardest and most flinty parts of the quartz; in others, as in the Reilly stope on the 280-foot level of the Combination mine, part of the free gold may be in a mixture of al unite and pyrite which can be crumbled in the fingers. Notwithstanding these differences the rich ore of the Combination, Reilly, Florence, Engineers', Little Florence, and Rogers mines is as a whole very similar. With the opening of the Mohawk mine ore of a different type was found. In the typical rich Mohawk ore native gold, bismuthinite, and famatinite are less conspicuous than in the mines to the south. So far as I am aware this mine has never produced specimens showing such broad bands of finely divided yellow gold as have come from the other mines mentioned and as are figured in Plates XXIII and XXV. Instead, the best ore has the dark telluric crusts described on page 116, which are mixtures of goldfieldite and marcasite. Free gold may or may not be visible. a Spurr, J. E., op. cit., p. 137 (footnote). PAY SHOOTS AND ORES. 173 The change between the typical Combination ore and the typical Mohawk ore is not entirely abrupt, for ore of the Mohawk character has been found in what is known as the 316 stope on the 280-foot level of the Combination mine. From the same stope, also, has come ore intermediate between the two types. North of the Mohawk mine there is a change to ore of the Mushett type, in which gold- fieldite is associated with sphalerite and a little galena. From the Mushett lease to the mines near Diamondfield there is an interval of about 3 miles, in which no rich sulphide ores of any consequence have been found. Mineralogically the Diamondfield ores resemble those of the Mushett and neighboring leases rather than those of the mines south of the Mohawk. Most of them, however, are soft crushed masses with little of the interesting crustification which is so marked a feature near Goldfield. The pro- portion of sulphides to gangue is less at Diamondfield than in the Mushett lease. East of the Rogers lease is another gap of three-quarters of a mile to the Gold Bar and Victor mines, which have still another variety of ore. The best of this is of relatively low grade. The cupriferous constituent, which is abundant, is apparently nearer to enargite than to famatinite. No tellurides have been recognized, and neither visible native gold nor bis- muthinite is common. OBSERVED CHANGES IN DEPTH. Observations to determine what changes, if any, take place in the unoxidized ores with increase of depth are limited to a vertical range of about 450 feet (137 meters), which is the distance from the base of the oxidized zone to the bottom of the Mohawk mine. Within this rather short range the mineralogical changes are not very marked. The minerals associated with the very rich ore at depths of 200 or 300 feet (61 or 91 meters) have been found also at lower levels. Alunite, as a constituent of the altered rocks, is as abundant in the deepest parts of the ledges yet reached as it is nearer the surface, and it appears from this that there was no essential change in the general chemical character of the ore-bearing solutions. As a soft interstitial filling, however, the mineral is slightly less abundant on the 600-foot level of the Mohawk than it is at higher levels in this and other mines. The explanation of this is thought to be physical rather than chemical. It is to be expected that spaces formed by fracturing in the deeper parts of a ledge would be smaller and less numerous than where the strained material is under a lighter load. Some pay shoots have shown a decided diminution in value before reaching a depth of 500 feet (152 meters), but the changes in both horizontal and upward directions from the kernel of a bonanza may be fully as notable, and where deposits have shown themselves to be so irregular as those of Goldfield caution is prescribed in deducing a general law from a few examples. To assume, because one pay shoot ends at a depth of 200 feet (61 meters), that no more ore will be found below it would, in this district, be much like relinquishing as useless all prospecting beyond the horizontal limits of the same body. From the condition of the mines in the latter part of 1905 an observer would have had some ground for supposing that little if any ore of 5-ounce or better grade would be found below a depth of 300 feet (91 meters). Subsequent events have shown that such a sweeping conclusion would have been erroneous. A tendency, however, toward a decrease of tenor below a depth of about 300 feet was noted in the preliminary report on the district,3 where it was also stated that ' ' there is considerable evidence in favor of the conclusion that ores of the grade now required for shipment are not likely to extend to as great a depth as 1,000 feet." These figures obviously were not intended to represent actual depths below the collars of individual shafts, but are round figures referable to a mean or generalized surface. Later observations are in full accord with this earlier state- ment, which is far from an assertion that no rich ore occurs at a greater depth than 300 feet (91 meters). In the Mushett lease very rich ore is known to extend to a depth of 429 feet (131 meters) and in the Rogers lease to 550 feet (168 meters). These deposits, however, are thus far rather exceptional. There is good ore on the 600-foot level of the Mohawk, but it is a Bull. U. S. Geol. Survey No. 303, 1907, p. 38. 174 THE GEOLOGY AND ORE DEPOSITS OF GOLDFIELD, NEVADA. of much lower grade than that shipped from the Hayes-Mormette stope above the 250-foot level. Ore has recently been found also at 718 feet (219 meters) in the Hazel-Goldfield lease, but its character and quantity are as yet undetermined. On the whole, observation indicates a general although not uniform decrease in the tenor of the ores in the deeper workings. The gold, goldfieldite, bismuthinite, and, to a less extent, famatinite become less conspicuous, while pyrite is relatively more abundant. The bearing of this change and its interpretation as regards the future development of the mines will be con- sidered in a subsequent chapter. ORIGINAL DEPTH OF THE ORES NOW VISIBLE. It is important, before taking up the problem of genesis, to obtain if possible some idea of the relation of the present surface to that which existed when the ores were precipitated. How many vertical feet of rock, in other words, have been removed since ore deposition began? As a rule the investigator .of a mining district is fortunate if he can form an estimate of such erosion that he is reasonably sure comes within a few thousand feet of the truth. At Gold- field the data permit a probable approximation within a few hundred feet. The dacite near Goldfield rests partly on the Milltown andesite, but mostly on latite. Immediately after its intrusion, therefore, the dacite may have been covered by the greater part, possibly 700 or 800 feet (213 or 244 meters), of the Milltown andesite. This cover was doubtless much broken by the force of the intrusion, and in consequence was easily eroded. The presence of abundant dacitic fragments in the basal part of the Siebert formation between Goldfield and Columbia indicates that before the lacustral epoch closed the dacite had been laid bare and was being actively eroded. The presence of this coarse littoral material suggests further that the site of the future mines was not one of the deepest parts of the lake, but for a time at least was unsubmerged land. At the close of the lake epoch, therefore, the present productive area of dacite must have been buried under considerably less than the 1,000 feet (305 meters) of sediments estimated on page 68 as the maximum local thickness of the forma- tion. With the disappearance of the lake, erosion began, and this may have further thinned the overlying sediments before ore deposition ceased. At the most, however, this erosion did not reduce the surface below the general level of the peneplain at the base of the Spearhead rhyolite (see PI. VIII, sections D-D' and E-E'), since the completion of the peneplain, as shown by the alunitized fragments in the Pozo formation already referred to, must have been subse- quent to ore deposition. A rough restoration of this plain over the site of the present mines would carry it about 300 feet (91 meters) above the existing surface of the dacite, indicating at least that amount of erosion since the ores were deposited. On the whole, therefore, and without referrence to any regional changes of level, it appears that the surface of that part of the district containing the principal ore bodies was not more than 1,000 feet (305 meters) higher than at present, and the difference may have been some hundreds of feet less. The general geologic relations of the deposits, therefore, indicate comparatively superficial origin. The structure and the mineralogical character of the deposits point to the same conclusion. The intricacy, irregularity, and lack of persistency of the Assuring are indicative of rupture under small load. The change in tenor of the ores at moderate depths is suggestive of deposi- tion controlled in part by proximity to the surface. The presence of cinnabar and native sulphur not, it is true, in the ore deposits themselves, but in the same province or region, is, as De Launay a has shown in his study of the Italian metallogenetic provinces, and Villarello6 for the metalliferous regions, of Mexico, in harmony with the view that the ore deposits were formed in a comparatively superficial zone. The presence of abundant antimony, bismuth, and tellurium, and the extraordinary richness of the Goldfield ores have similar significance. Like the deposits at Cripple Creek, those of Goldfield exhibit a mineralogical character that a La inetallogenh' -• *7*A, ..7' i *'* - 1C&?-* ^••vv-j*^'-*^ 2>. PHOTOMICROGRAPHS OF ALUNITIZED ROCKS. U. S. GEOLOGICAL SURVEY PROFESSIONAL PAPER 66 PLATE XXIX B. y*M ^-cm00^W^:' SB PHOTOMICROGRAPHS SHOWING ALTERATION OF DACITE. U. S. GEOLOGICAL SURVEY PROFESSIONAL PAPER 66 PLATE XXX j|K* MJSRrfgRy r* •'. j Ki>'*fei 888*^ t^^M Kjek? 3 ^^^H Hula ' li/ * v^ib mw^i iffiS' Ji ^J^fl $^SySHE ^•'-in ■• s. a PHOTOMICROGRAPHS ILLUSTRATING ALTERATION OF ROCKS. METASOMATIO PROCESSES. 179 The altered rock is light gray, flecked with numerous dull white spots which represent the original feldspar phenocrysts. The few quartz phenocrysts are unchanged, but the ferromag- nesian, or, more briefly, femic, minerals have wholly disappeared. Pyrite, in small, dissemi- nated crystals, is abundant. Under the microscope, it is seen that the only original constituents are the quartz pheno- crysts, even these showing some development of pyrite along irregular microscopic cracks, and an occasional small crystal of zircon. The feldspars are changed to aggregates of minutely crystalline kaolinite and tabular crystals of alunite, some of the latter being arranged in sheaf- like bunches (see PI. XXVIII). The alunite has the form characteristic of it in this district, sections cut at large angles with the basal pinacoid having the shape of narrow laths with irregu- lar ends. The length of these lath-shaped sections rarely exceeds half a millimeter. The alunite, when cursorily examined under a low-power lens, may easily be mistaken for sericite (muccovite), although of course this error is quickly dispelled on closer study, sericite being optically negative and alunite positive. The interference colors, moreover, although bright, particularly in the larger crystals, are of a lower order than those of sericite. Quartz also accompanies the alunite and kaolinite in some of the pseudomorphs after labradorite. Dia- spore, while not present in the rock analyzed, occurs in the alunitized dacite of the Florence mine and elsewhere. (See p. 125.) The former femic constituents can be recognized from the fact that they contain little or no kaolinite, the quartz and alunite being here associated with abundant pyrite. In some cases the pseudomorphous aggregate still preserves a suggestion of the former cleavage of the biotite or of the outlines of hornblende. The groundmass is changed to a fine-grained aggregate of kaolinite, quartz, alunite, and pyrite. The last-named mineral occurs also in irregular microscopic veinlets. As the rock is wholly crystalline and is made up of minerals of approximately constant composition, it is possible to calculate with some precision the actual mineralogical constitu- tion from the chemical analysis. This, in percentages of mass, is as follows: Mineralogical composition of altered dacite. Per cent of mass. Quartz (Si02) 49. 38 Kaolinite (Al2032Si02.2H20) '. 23. 99 Alunite (K20.3A1203.4S03.6H.,0)<< 15. 73 Pyrite (FeS2) 7. 20 Water (11,0) 2. 53 Other constituents 1. 17 100. 00 The various stages and variations in the alteration of the dacite, as seen in thin section under the microscope, are illustrated in Plates XXVIII to XXX, which are accompanied by full descriptive notes. Compared as they stand, the two analyses show close agreement in silica, alumina, titanic oxide, and phosphorous pentoxide. When all the iron in both anahTses is calculated as ferrous oxide, that of the altered rock shows a loss of only 0.7 per cent, so that in this respect also the two analyses are very close together. On the other hand, the analysis of the altered rock shows a loss of practically all the lime and magnesia, most of the soda, and one-half of the potash. It has gained a large quantity of combined water, nearly 6 per cent of sulphuric anhydride, and nearly 4 per cent of sulphur. Such a direct comparison of analyses, however, while indicating in this case the general character of the change that has taken place in the dacite, is really a comparison of equal masses of the two rocks, or, more strictly speaking, of the two powders as prepared and weighed a The molecular proportions of potash and soda as calculated from analysis 2, page 181, are respectively 1 1 and 14. All of the potash and 8 of the soda molecules are needed to satisfy the 75 molecules of S03. Consequently the Goldrield alunite is a soda-bearing variety. In an altered rhyolite from the east slope of Vindicator Mountain, the molecular ratio of soda to potash in the alunite, as determined by Doctor Hillebrand, is as 40 to 45 This rock, however, contains a little sericite, and it is possible that the result obtained for potash may be high inconsequence of some decomposition, of the sericite by the sulphuric acid used to dissolve the alunite. 180 THE GEOLOGY AND ORE DEPOSITS OF GOLDFIELD, NEVADA. for analysis, and as Lindgren0 pointed out some years ago, would accurately portray the character of the alteration only under two conditions, namely: (1) That the specific gravity or density of the rock is unchanged by the metamorphism; and (2) that the alteration has not produced any change of volume in the rock mass as a whole, such a change, for example, as takes place when peridotite alters to serpentine. It is essential in an investigation of tins kind to determine what materials have been added to or subtracted from a unit volume (or unit mass) of fresh rock in order to produce a given alteration product. The changes undergone by a given volume of rock can be determined most simply if the alteration is unaccompanied by swelling or contraction of the whole rock mass. The altered dacite shows no indication of increase of bulk. The field evidence of such swelling would comprise irregular fracturing and squeezing of the rock, the presence of curved slickensided surfaces, and pressure effects in the microscopical texture of the altered dacite. Contraction would probably be more difficult to detect. Any notable degree of shrinkage, however, would be likely to record itself by the development of many irregular open cracks or by some modifi- cation of the original texture of the rock, such as the distortion of phenocrysts. Evidence of either kind being absent, it may be concluded with some confidence that whatever volumetric change has taken place is to be sought in a comparison of the porosity of the two rocks and not in change of total bulk. The porosity of the fresh dacite is exceedingly slight and is not apparent under the micro- scope. An accurate specific gravity determination of the rock powder used for analysis, made by Mr. George Steiger, gave the figures 2.654.fc He also determined the specific gravity of the whole hand specimen as 2.63, the difference between the two results being an approximate measure of the porosit}7. The specific gravity of the altered dacite, which is noticeably porous, as calculated from the mineralogical composition on page 179, assigning to the 1.17 per cent not accounted for the average specific gravity of the other constituents, is 2.769.c Determina- tions by Mr. Steiger gave 2.766 for the powdered rock and 2.49 for the hand specimen. These figures indicate that the substance of the altered rock has gained 4.2 per cent in weight and that, notwithstanding this gain, a given volume of rock, under the supposition of constant volume, has suffered a net loss of 5.3 per cent in weight consequent upon an increase of porosity. Since the volume of a given mass of rock, in cubic centimeters, is, for all practical purposes, equal to its weight in grains divided by its specific gravity, the percentage of pore space in the fresh dacite is obtained from the equation 287.4 287.4 287.4 2.63 ~~ 2.654 ~ 2.63 X' where 287.4 is the weight of a specimen of dacite in air, 2.63 the specific gravity of the rock mass, 2.654 the specific gravity of the poreless mineral constituents, and x the proportion of pore space, which in this case is equal to 0.9 per cent. In the altered rock, the proportion of pore space is 9.9 per cent, showing an increase in porosity of 9 per cent of the initial volume. The chemical changes undergone by the dacite are shown in the accompanying table. Columns lb and 2b are not essential as regards the process illustrated, although they represent a step in the reasoning. They are of value also as showing that specific gravity determinations of rock powders, while useful in calculations of the mineral compositions of rocks, are of minor importance in a comparison of this kind, in which it is necessary to know the specific gravity of the mass as a whole, including its pores. Incidentally, it may be remarked that when the specific gravity of a rock is given in connection with its chemical analysis, the method by which the density was determined should be indicated. a Metasomatic processes in fissure veins: Trans. Am. Inst. Kin. Eng., vol. 30, 1901, pp. 591-595. b The specific gravities of the powders were determined by placing weighed quantities in water in a tared picnometer and boiling them at low temperature under reduced pressure. They were then kept for some hours in a thermostat and quickly weighed at 25° C. The specific gravities of the rock masses were obtained by weighing them in air and quickly in water. The figure 2.49, obtained for the altered dacite, is probably slightly too high in consequence of some absorption by pores open to the surface. c The figures used for the specific gravities of the minerals were: Quartz 2.00, kaolinite 2.01, alunile 2.60, and pyrite 5. METASOMATIC PROCESSES. 181 SiO H,0 BtO- FeO In columns lc and 2c are given the number of grams of each constituent in 100 cubic cen- timeters of each rock, the figures being obtained by multiplying the percentage figures in columns la and 2a by the respective specific gravities of the fresh and altered dacite. The gains and losses of each constituent are given in grams in col- umn 3, and in percentages of total ini- tial mass in column 4. The gains and losses as given in this column are also shown graphically in figure 20." The last column, 5, gives the percentage of loss of each constituent and perhaps most clearly displays the nature of the change. It appears that the rock has lost a little of its silica, more of its alumina, nearly all of its magnesia and lime, three- fourths of its soda, and two-thirds of its potash. On the other hand, the water has greatly increased, a large amount of sulphuric anhydride has been added and the iron has been converted to pyrite. The iron oxides in column lc correspond to 11.08 grams of metallic iron, while the pyrite in column 2c corresponds to 8.4 grams of iron and 9.6 grams of sulphur. The quantity of iron originally in the dacite therefore not only was sufficient suffered a loss of over 27 per cent. CaO Figure 20. — Diagram illustrating gains and losses of each chemical constituent in terms of percentage of mass of original fresh dacite. Radial distance between successive circles corresponds to 1 per cent. Gains are outside, and losses inside, of the heavy circle representing fresh dacite. Areas have no significance. to form all the pyrite in the altered rock but has Chemical alteration of dacite. 1. Chemical analysis of fresh dacite. George Steiger, analyst. Specific gravity of powder analyzed 2.654. Specific gravity of rock mass 2.63. 2. Chemical analysis of altered dacite. George Steiger, analyst. Specific gravity of powder analyzed 2.766. Specific gravity of rock mass 2.49. la. Analysis 1, recalculated to summation of 100, with minor constituents omitted. 2a. Analysis 2, recalculated to summation of 100, with minor constituents omitted. lb. Constituents, in grams, in 160 cubic centimeters of fresh dacite free from pores. Specific gravity 2.654. 2b. Constituents, in grams, in 100 cubic centimeters of altered dacite free from pores. Specific gravity 2.766. lc. Constituents, in grams, in 100 cubic centimeters of fresh dacite with 0.9 per cent pore space Specific gravity 2.63. 2c. Constituents, in grams, in 100 cubic centimeters of altered dacite with 9.9 per cent pore space. Specific gravity 2.49. 3. Gains and loss's in grams of each constituent in the alteration of 100 cubic centimeters of dacite to the same volume of altered product. 4. Gains and losses of each constituent in percentage of mass of the original 100 cubic centimeters of fresh dacite. 5. Gains and losses of each constituent in pi centage of its own original mass in 100 cubic centimeters of fresh dacite. "This simple mode of presentation was adopted before the appearance of Leith and Harder's elegant diagrams in Bull. U. S. Geol. Survey No. 338. It is retained in the belief that a dip ^Tam which is intended to give quantitative expression to all details of a process is likely to be more intricate than illustrative. 182 THE GEOLOGY AND ORE DEPOSITS OF GOLDFIELD, NEVADA. Comparisons of fresh and altered rocks are sometimes made by assuming the constancy of one constituent and recalculating the analysis of the altered rock accordingly. Such a method in the present case would give erroneous results. The metamorphic agent was evidently a strongly acid solution carrying sulphydric and sulphuric acids, and possibly sulphurous acid. Whether the sulphuric acid which was doubtless the direct agent in the formation of the alunite was present in the original solution from the first, or whether it was derived from the hydrogen sulphide, by oxidation at some stage in the movement of the solution toward its point of attack upon the rocks now visible, is a question which will be discussed in Chapter XVI. The absence of sulphates from contact ore deposits indicates, however, that oxygenated sulphur compounds are not given off directly from solidi- fying magmas. The solution was capable of decomposing the silicates in the rocks, carrying part of their constituents away, reacting with the iron of the magnetite and silicates to form pyrite, with the potassium and aluminum to form alunite and with the aluminum to form kaolinite. The large percentage of loss in calcium, potassium, and sodium shows that the active solution was far below its saturation point for these elements, and was therefore, within the range of depth investigated, entirely different in character from the alkaline solutions which deposited the large class of sericitic and calcitic gold-quartz veins exemplified bv those of California. Not all of the dacite is altered to exactly the same product as that just described. Some varieties contain diaspore as a microscopic constituent. Others, which may be classed as ledge matter or ore rather than country rock, contain more quartz and pyrite. On the south slope of Preble Mountain, near the summit, the dacite in some places has been altered to a white fine-granular rock, not unlike quartzite or marble in general appearance. This is a nearly pine aggregate of quartz and alunite, with very little pyrite. The original texture of the rock, except for the presence of an occasional phenocryst of quartz, is entirely obliterated. CHANGES IN OTHER ROCKS. The metasomatic changes effected by the ore-depositing solutions in the latite, andesite, and rhyolite of the district have not been studied in the same detail as that in dacite. Even were conditions for close comparison of fresh and altered rock as favorable as in the case of dacite, such study would not be likely to throw any new light on the general nature of the process. The andesite differs but slightly from the dacite in chemical and mineralogical composition and alters to products not always distinguishable from those derived from the dacite. A similar statement applies to the latite, alunitized modifications of which may be studied on the lower levels of the deeper mines, in various shafts northeast of Goldfield, and in the quarry on the south edge of Columbia, where the original rock has been changed to a soft, white, porous mass which is chiefly alunite. The altered forms of rhyolite differ from those of other rocks mainly in the presence of less pyrite, owing to the fact that the rhyolite originally contained little iron in the form of oxides and silicates. Alunite is very abundant in the altered rhyolite, and, as shown in Plate XXXI, forms comparatively coarsely crystalline aggregates pseudomorphous after orthoclase. Such aggregates may be well seen in the rhyolite capping Columbia Mountain, near the Con- queror mine, and on Vindicator Mountain. METAS0MAT1C PROCESSES. 183 A chemical analysis of altered rhyolite from the eastern shoulder of Vindicator Mountain, one-fourth mile (0.4 kilometer) from the summit, is given below: Chemical analysis of altered rhyolite . Si02 75. 78 A1203 10. 65 Fe203 68 FeO 16 MgO None. CaO 1.67 Na20 22 K20 96 H20 below 110° C 1. 16 H20 above 110° (' 3.54 12 [Oeorge Steiger, analyst.] ZrO, CO, Ti0.2 so,.. 0. 02 76 02 4. 73 F None. MnO None. BaO 02 SrO None. 100. 49 The rock analyzed (G. 333) is nearly white and shows small spots of light-pink alunite. Under the microscope, in ordinary light, it shows embayed quart/ phenocrysts and the outlines of feldspars, in a groundmass which still retains much of the fluidal structure of a glassy rhyolite. Between crossed nicols, however, the whole rock, with the exception of the quartz phenocrysts, is seen to have undergone recrystallization. In the new aggregate, alunite forms the largest crystals. These have grown partly in the groundmass, partly in the original feldspar pheno- crysts. Many of the latter, however, are altered to extremely fine-grained aggregates, in which it is difficult to identify the constituent minerals. Most of the calcite shown by chemical tests and analysis to be present in the rock appears to be in these fine aggregates, as the mineral is very inconspicuous in the thin sections. Some of these aggregates certainly contain sericite and kaolinite. Relatively large plates of alunite inclosed in these fine-grained pseudomorphic aggregates are common. The groundmass is mainly a very fine-grained mixture of quartz, kaolinite, calcite, sericite, and a little iron oxide, probably from pyrite. The secondary min- erals, except the iron oxide, so far as microscopic examination shows, were all formed contem- poraneously. The calculation of the mineralogical composition of this altered rock from its chemical analysis, in terms of microscopically recognized minerals, is not entirely satisfactory. The carbon dioxide of the analysis is too low to combine with all the lime as calcite, while the alkalis do not quite suffice to satisfy the sulphuric anhydride for alunite, and no potassium is left for the sericite known to be present. Consequently, all of the alumina, after that necessary for alunite is taken out, must be calculated as kaolinite, whereas some of it should undoubtedly be combined in the sericite molecule. These conditions, since the chemical analysis may be regarded as trustworthy, suggest the presence of gypsum (CaS04 + 2H20), which, if it occurs in the fine aggregates with kaolinite, can not be satisfactorily identified by microscopical methods. By calculating all of the carbon dioxide as calcite, the balance of the lime as gypsum, the balance of the sulphuric anhydride as alunite, the balance of the potash as sericite, and the residual constituents as quartz, iron oxides, and water, the following is obtained as the approximate mineralogical constitution of the altered rhyolite : Mineralogical composition of altered rhyolite . Per cent of mass. Quartz (Si02) 67. 62 Sericite (2H2O.K20.3Al203.3Si02) " 79 Kaolinite (Al203.2SiO,.2H20) 16. 77 Alunite ((KNa)0.3Al203.4S03.6H20) 9. 93 Gypsum (CaO.S03.2H20) 1. 63 Calcite (CaO.C02) 1. 70 Iron oxides (FeO.Fe203) 84 Water (H20) '. '59 99.87 PLATE XXXI. Photomicrograph of Alunitized Rhyolite. A. Vindicator rhyolite (Gr. 326). West slope of Vindicator Mountain. Shows alunite (a) pseudomorphs after orlhoclase. Quartz phenocrysts (q) are unaltered. Black areas are opaque, white, earthy pseudomorphs after biotite. The groundmass (g), which retains its original flow structure, has been altered from a glass to an aggregate of quartz, kaolinite, and alunite. The rock contains a little diaspore, not shown in this section. Ordinary light. Magnified 40 diameters. B. Same as A. Nicols crossed, showing aggregation of alunite and devitrification of the groundmass. 184 U. S. GEOLOGICAL SURVEY PROFESSIONAL PAPER 66 PLATE XXXI PHOTOMICROGRAPHS OF ALUNITIZED RHYOLITE. METASOMATIC PROCESSES. 185 This result is not entirely convincing, as the quantity of sericite obtained by calculation appears to be a little less than is actually present in the rock, and the occurrence of gypsum is not established beyond question. In the presence together of calcite, alunite, and sericite, this rock is exceptional. Other specimens from the same locality show much quartz, alunite, and kaolinite, with some diaspore, but no calcite or sericite. The rhyolite, as might be expected from its originally siliceous character, tends to become completely silicified in the vicinity of fissures, as is exemplified in the neighborhood of the Sandstorm mine. THE ORE-DEPOSITING SOLUTIONS. The mineralogical character of the Goldfield ores and the alteration of the wall rock show that the solutions or vapors which deposited them carried gold, copper, bismuth, antimony, a little arsenic and tellurium, hydrogen sulphide, and probably sulphurous and sulphuric acids. The solvent action of the solutions upon quartz was comparatively slight, as shown by the fact that the original phenocrysts of the dacite still retain their characteristic embayed outlines when the rest of the rock is altered to quartz, alunite, and kaolinite. The quartz set free by the decomposition of the silicates has for the most part recrystallized as fine-grained aggregates. A small proportion, as we have seen, has been carried away in solution, perhaps in part to be recrystallized in small neighboring fissures, and in part permeating the surrounding less-altered rocks. Large masses of coarsely crystalline vein quartz are absent from this district, and it seems necessary to conclude not only that the ore-bearing solutions were poor in silica but that, in spite of their energetic attack upon the rocks, they were not good solvents for quartz. The apparently intense silicification of the country rock in proximity to fissures appears at first glance to point to a different conclusion. The conversion of a rock containing 60 per cent of silica to a fine-grained pyritic quartz aggregate does not, however, necessarily imply the direct addi- tion of 40 per cent of silica. The result may be attained by the removal of most of the bases, the conversion of the iron to pyrite, and the development of a porous texture such as is favorable for ore deposition and is characteristic of the Goldfield ledges. Moreover, it is probable that some of the silica shown to have been abstracted from the altered dacite may have been con- centrated in the immediate vicinity of the fissures. Certainly, whatever silica was originally in the solutions did not travel far from the fissures through which they rose. Whether the solutions were notably ferruginous is doubtful. As compared with other districts, the pyrite at Goldfield is not abundant, and all of that in the country rock can, as has been shown, be accounted for without any addition of iron. There has, in fact, been an abstrac- tion of iron which may have been sufficient to form the pyrite in the actual ore, upon the supposi- tion that the dissolved iron, like the silica, migrated toward the fissures. In general the heavy metals brought in by the solutions remained within or very close to the multitude of small, irregular fissures that afforded opportunity for the depositional process. The sulphur acids, on the other hand, penetrated the wall rock for considerable distances. It is very probable that the ore-bearing solutions contained carbon dioxide, although the ores and the rock adjacent to them are free from carbonates. Field evidence in this district, as well as in the Coeur d'Alene district" in Idaho, indicates that this constituent, when of volcanic origin, becomes active in the formation of carbonates only at comparatively low temperature, and that it tends to penetrate to greater distances from the source of supply than some of the other constituents. The third, or propylitic type of alteration described on page 176, is thought to be largely due to the extensive permeation of the rocks by solutions containing carbon dioxide. It thus constitutes an outer aureole to the more intense metasomatism associated directly with the ores. oRansome, F. L., and Calkins, F. C, The geology and ore deposits of the Cceur d'Alene district, Idaho: Prof. Paper U. S. Geol. Survey- No. 62. 1908. 186 THE GEOLOGY AND ORE DEPOSITS OF GOLDFIELD, NEVADA. It may be recalled, in this connection, that Sainte-Claire Deville and Leblanc," in their studies of Italian volcanic gases, found that sulphurous and carbonic acids never occurred together, although the association of sulphydric and carbonic acids was frequent. They concluded that, as a rule, the emanation of carbon dioxide marks a later and cooler stage of solfataric activity. The transition from one type to the other, however, can hardly be abrupt. Just what became of the lime and magnesia removed from the altered dacite has not been determined. A part, at least, of the calcium was probably taken into solution as hydrous sulphate and deposited in fissures as gypsum, this mineral being known to occur in the district in places where its formation can scarcely have resulted from the action of surface waters. Still another part and some of the magnesium may have been carried as carbonates into the rocks affected by metamorphism of the third or propylitic type and there deposited metasomat- ically as calcite or dolomite. It has not yet been ascertained, however, whether there has actually been any addition of calcium or magnesium to these carbonatized rocks. aM&noire sur la composition ehimique des gaz rejetes par les events volcaniques de l'ltalie mendionale: Annales cliim. phys., vol. 52, 1858, p. 45. CHAPTER XV. UNDERGROUND WATER AND DEPTH OF OXIDATION. When mining began, the average level of underground water in the district was from 100 to 150 feet (30 to 46 meters) below the general surface. The Combination mine first had water at 130 feet (40 meters), the January at 180 feet (55 meters), the Red Top at 140 feet (43 meters), the Silver Pick shaft, near Columbia, at 100 feet (30 meters), and various shafts near Diamond- field at about the same depth. As is usually the case, water was found at less depth in low ground than on high, the Dixie shaft on Preble Mountain being dry at 300 feet (91 meters), as is also the Lucky Boys shaft, 360 feet (110 meters) deep, on Vindicator Mountain, while some wells near town have furnished water at 40 or 50 feet (12 to 15 meters). At Rabbit and Tognoni springs, and at a spring near the mouth of Pozo Canyon, water comes to the surface. All these are ordinary hillside springs, the water seeping from the higher ground in their vicinity. In none of the mines has the flow of water been so large that it could not be easily kept down by bailing or with ordinary pumps. When the Combination was the deepest mine, the quantity of water hoisted to keep the 280-foot level free was probably not over 3,000 gallons (11,250 liters) in twenty-four hours. The White Rock prospecting shaft in the northern part of the town of Goldfield is one of the wettest in the district. It was 520 feet (158 meters) deep in July, 1908, and goes through 280 feet (85 meters) of Siebert beds and overlying wash into latite. It thus drains a thick mass of porous sediments and at times it has been necessary to hoist 30,000 gallons (112,500 liters) in twenty-four hours to keep down the water. Most of the wells in the district are in the Siebert beds or in the intercalated flow of Mira basalt. The latter is the principal water-bearing horizon for domestic wells of moderate depth (50 to 70 feet, or 15 to 21 meters) in the southern part of town. In 1906 the Goldfield brewery derived its water supply entirely from a 50-foot (15-meter) well in the basalt. The supply from wells in the Siebert beds is uncertain and is not always proportional to depth. In the latter part of 1905 the Goldfield Reduction Company was getting about 4,500 gallons (16,875 liters) in twenty-four hours from a 200-foot (61-meter) well and the New Western Reduction Com- pany 2,000 gallons (7,500 liters) or less from a 250-foot (76-meter) well. The well at the ice works, 100 feet (30 meters) deep, yielded 4,000 gallons (15,000 liters) per diem in June, 1905, but only 2,000 gallons in the following October. A well sunk in 1908, just south of the Gardiner mill, is 180 feet (55 meters) deep, and is said to yield about 10,000 gallons (37,500 liters) in twenty- four hours, most of which comes in at points less than 100 feet (30 meters) deep. This well is rather remarkable in that the water rises to within a few feet of the surface, showing that it is under some artesian head. It undoubtedly taps the same flow that gives rise to Rabbit Spring. The town water supply came originally from wells in Pozo Canyon. The first well yielded about 8,000 gallons (30,000 liters) per diem in August, 1904, at a depth of 25 feet (7.6 meters). This soon diminished, and in November the well was deepened 10 feet (3 meters) and horizontal drifts were run from the bottom. The supply then rose to 15,000 gallons (56,250 liters), but fell •off again when a new well was sunk lower down the canyon. This second well at first gave 20,000 gallons (75,000 liters) per diem, but in September, 1905, was furnishing only 15,000 gal- lons, the well being 90 feet (27 meters) deep, with drifts. Both wells are in the Siebert beds. The Pocahontas well, at the roundhouse of the Las Vegas and Tonopah Railroad, is 840 feet (256 meters) deep. Its yield is about 24,400 gallons (91,500 liters) in 24 hours. Water was first found at 94 feet (28 meters), but the flow was small and no increase was noted until a depth of 450 feet (137 meters) was reached. 187 188 THE GEOLOGY AND OEE DEPOSITS OF GOLDFIELD, NEVADA. The ground water of the district without question represents merely the storage of that small part of the scanty local precipitation which is not evaporated before it can sink into the ground. Extensive pumping soon lowers the water in any one place and the subsequent influx is small. There is a permanent seepage from Malpais Mesa, as shown by springs and by some of the wells, but the quantity of water thus supplied to the sediment-filled basin under Gold- field probably does not average more than 20,000 gallons (75,000 liters) per diem and may be considerably less. The general level of the ground water is being steadily lowered by mining operations, and there is no suggestion whatever of any influx of thermal or abyssal waters at the present time. The character of the underground water varies. That from the wells and springs is fairly good as desert waters go and is not so strongly charged with salts as to give it perceptible taste. The water from many prospect shafts also is potable. But in mines where bodies of ore are in course of oxidation the water, as shown by the analysis of that from the January mine on page 220, is heavily charged with sulphates and probably in many places with free sulphuric acid. The quantity of sulphides in the Goldfield deposits is not great, and in more humid regions their oxidation probably would not give rise to such concentrated solutions. At Gold- field, however, the ground water has little natural circulation, receives only slight accessions of fresh water, and has a correspondingly slow underground run-off. In general, the bottom of the oxidized ore corresponds closely to the original ground-water level. In comparison with most deposits in arid regions, therefore, the vertical range of oxida- tion is short, being only about 150 feet (46 meters). The change from oxidized to sulphide ore is as a rule sharp, and there is no evidence of any large fluctuation in the ground-water level. The character of the oxidized ore has been described on page 170. The question whether oxi- dation has been accompanied by notable enrichment of the sulphides below is so closely connected with the whole problem of ore genesis that its consideration belongs rather to the next chapter. CHAPTER XVI. GENESIS OF THE DEPOSITS. STATEMENT OF THE PROBLEM. Since the preceding chapters contain an ample presentation of the problem now awaiting solution, only a brief recapitulation is needed of some of the most significant facts with which an adequate explanation of ore genesis must harmonize. Beyond all question the intimate association of unusually rich gold ores with the mineral alunite is the most remarkable feature of the deposits and is the one that promises to shed most light on their origin. Alunite is not a common mineral, and although it was recognized in small quantity in the oxidized zone at Cripple Creek it is at Goldfield alone, so far as is at present known, that it is found with sulphides and tellurides as a characteristic mineral of unoxidized gold ores. The presence of this mineral and the kind of alteration undergone by the rocks containing it prove, as shown in Chapter XIV, that the ores were deposited from solutions containing sulphuric acid. Whether this acidity was an original property of the gold-bearing solutions or whether the solutions, primarily of different character, became acidic at the place of precipitation, or during their journey thither, are questions presently to be considered. Other chemical and mineralogical features of the ores to be kept in mind are the occur- rence of telluride and selenide of gold, sulphide of bismuth, and compounds of copper, sulphur, antimony, and arsenic (enargite, famatinite, and goldfieldite) of which the mineral species is not in every case determinable, the cryptocrystalline character of the quartz, and the extraordi- nary concentration of the gold. Due consideration must be given also to the volcanic history of the region, the recent age of the deposits, the slight depth at which they were formed, and, as a corollary of these facts, the brief time and the short vertical distance available for any secondary concentration that may be postulated in connection with erosion. Attention will first be directed to the question of the source of the sulphuric acid, since if it can be satisfactorily answered the other phases of the main problem should crystallize clearly about this nucleus. THE DIRECT VOLCANIC HYPOTHESIS. That some fumaroles emit sulphur dioxide has long been known. As early as 1858 Sainte- Claire Deville and Leblanc a found it in gases from Vesuvius and other Mediterranean volcanoes. From one fumarole in the crater of Vesuvius they collected a gas which proved to contain hydrochloric acid and sulphur dioxide in the ratio of 86.2 parts of the former to 13.8 parts of the latter, together with water vapor and. the constituents of ordinary air. They concluded from their investigations that carbon dioxide and sulphur dioxide never came simultaneously from the same fumarole. This, however, does not accord with the results of some other workers, as is shown by the following table prepared by F. C. Lincoln, b which is of theoretic interest, from the fact that calcite and alunite occur together at one place in the Goldfield district. (See p. 183.) aMemoire sur la composition chimique tics gaz rejetes par les <5vents volcaniques de l'ltalie mendionale: Annates chim. phys., 3d ser., vol. 52, p. 45, 1S58. b Econ. Geology, vol. 2, 1907, p. 802. 189 190 THE GEOLOGY AND ORE DEPOSITS OF GOLDFIELD, NEVADA. Fumarole gases containing both CO, and S02. No. Volcano (or locality). Spot. Tem- pera- ture. COa. so2. HC1. N,. o2. 1 Tuuuerres 3,908 meters elevation °C. 86 93.5 2.44 5.38 4.90 1.42 3.00 3.97 23.40 22.00 59. 62 68.5 98.5 Trace. 1.54 Trace. 3.40 2.61 2.25 1.32 Trace. Trace. Trace. 12.0 0.4 0 0 2.14 3.00 1.98 73.80 66.00 27.19 19.4 1.0 6.5 81.81 79. 16 73.48 76.22 73.71 70.88 2.28 9.00 10.99 o % Hekla Great crater 14 91 3 Vesuvius Cone of 1853-114 218 18 46 4 do Halfway up eruptive crater 18.13 17 61 5 do At eruptive center fi do do 18 04 7 do do 21 85 8 Vuleano Interior of great crater 300 250 150 115 110 0 52 q do do 2 40 in do do 2 20 ii Santorin 200 meters from cone of G iorgios On slope between Giorgios and lava stream n do Authorities: (1) Boussingault, J. B., Annales chim. phys., 2d ser., vol. 52, 1833, p. 21. (2) Bunsen, R. W., Annales chim. phys., 3d ser., vol. 38, 1853, p. 259. (3) Franco, Compt. Rend., vol. 66, 1868, p. 159. (4) Franco, Compt. Rend., vol. 66, 1868, p. 1352. (5-7) Franco, Annales chim. phys., 4th ser., vol. 30, 1873, pp. 98-99. (8-10) Fouque, F., Compt. Rend., vol. 61, 1865, p. 565. (11-12) Gorceix, H., Compt. Rend., vol. 75, 1872, p. 270. Van Hise a states that in the gases emitted from fumaroles and solfataras sulphur dioxide is probably next in abundance to steam. This, however, does not appear to accord with the testimony of published analyses of volcanic gases. F. C. Lincoln,6 on the basis of 50 selected analyses, concludes that, after steam and nitrogen (the latter being difficult to rank owing to the possibility of admixture of air), carbon dioxide is the most important gas, followed b)^ hydrogen sulphide and sulphur dioxide. ' Sulphuric acid or sulphuric anhydride is apparently still less common in volcanic emanations than sulphur dioxide. Geikie c states that "occasionally, also, the production of sulphuric acid is observed at active vents," which probably means merely that the acid is formed superficially by oxidation of sulphur dioxide. In the interesting crater lakes of Taal volcano described by R. F. Bacon d free sulphuric acid is present in large quantities. It is apparently formed, how- ever, by the oxidation of fumarolic sulphur dioxide which bubbles up through the boiling water. On the whole, it appears to be very doubtful whether sulphuric acid or sulphuric anhydride is actually emitted from the deeper part of any volcanic vent. There is a strong suggestion, moreover, that the sulphur dioxide which streams from some fumaroles is not all of deep-seated origin, but may in part be due to an admixture of air with the true telluric gases, particularly with hydrogen sulphide. Here we are confronted, however, with the difficulty of distinguishing sharply between primary and secondary volcanic products. At what depth, for example, must water or oxygen be introduced in order to be classed as a primary volcanic product ? By mag- matic water do we mean only such as has been locked in the earth's interior since the planet took its present form, or may we mean also water that the magmas have subsequently absorbed in some such manner as that advocated by S. Arrhenius ? e May not the water emitted from volcanoes be both magmatic and meteoric as these terms are used by most writers? This is still a vexed question, although the available evidence favors the view that meteoric water does not reach the sources of magmas/ Granted that the water of volcanic eruptions, however introduced or formed, comes mainly from the molten magma, there is no a priori difficulty in postulating the emission of oxygen compounds of sulphur, since Fouque ? has shown that in some cases the constituent gases of water are dissociated and the liberated oxygen might under some circumstances unite with sulphur. As a matter of fact, however, the oxides of sulphur are not nearly so common or abundant, and when they do occur are not so clearly of deep deri- vation, as is hydrogen sulphide. a A treatise on metamorphism : Mon. U. S. Geol. Survey, vol. 47, 1904, p. 491. b Magmatic emanations: Econ. Geology, vol. 2, 1907, pp. 201-264. c Text-book of geology, vol. 1, 1903, p. 268. d Philippine Jour. Sci., vol. 2, 1907, p. 115. 'Zur Physik des Vulkanismus, Geol. Foreningens. Stockholm Forhandl., vol. 22, 1900, pp. 395-419 / For a recent discussion of this problem see Chamberlin, R. T.. The gases in rocks, Carnegie Institution of Washington, Publication No. 106,. 1908, p. 69. g Santorin et ses eruptions, Paris, 1879, p. 230. GENESIS OF THE DEPOSITS. 191 There is evidence also of the deep-seated formation of sulphuric acid in the presence of sulphates, such as barite and celestite," as primary minerals in some veins. Recently, too, Lindgren6 has called attention to the occurrence of anhydrite as a primary mineral with tour- maline and chalcopyrite at the Cactus mine in the Frisco district, Utah. The presence of the minerals haiiynite [(Na2Ca)2(NaS04Al)Al2(Si04)3] and noselite [(Na4(NaS04Al)Al2(Si04)3] in phonolitic rocks proves that under some circumstances sulphur trioxide may be present in molten magmas, and consequently may exist in magmatic solutions. There are, however, no phonolitic rocks known at Goldfield. While these occurrences are to be regarded as favoring the view that sulphuric acid can form at volcanic centers, their testimony, as regards importance in ore deposition, is opposed by the absence of sulphates from contact metamorphic deposits and of sulphuric acid- from most hot springs. Springs carrying sulphuric acid are, it is true, not unknown. The water of a hot acid spring at the so-called geysers of Sonoma County, Cal., according to an analysis by Thomas Price, contains 145 grains of free sulphuric acid per gallon/ Other springs at the same locality contain smaller quantities of the same acid. All these waters, however, are saturated with hydrogen sulphide, and it is possible that the sulphuric acid may have been formed by the oxidation of the sulphydric acid within the zone penetrated by surface waters. Hot sulphuric acid springs occur also in the Coso Range, Inyo County, Cal., accompanied by deposits of sulphur containing hydrogen sulphide. d Similar acid springs carrying hydrogen sulphide issue from sulphur deposits near Maverick Springs, El Paso County, Tex. The water from one of these, according to E. M. Skeats,e contains 136 parts per 100,000 or 79.08 grains per gallon of free sulphuric acid. W. T. Lee has described a similar occurrence at Sulphurdale, Utah/ Analyses of 11 other springs' waters containing less sulphuric acid than those above mentioned are given by F. W. Clarke. ^ The chemical activity of free sulphuric acid in spring water would of course lead to the rapid formation of sulphates during the upward course of the water and to consequent neutralization of the free acid. But there is a limit to such rapid neutralization and in persistent and copious springs it might be expected that some free acid would in most cases be brought to the surface were it commonly generated below. Furthermore, if sulphuric acid were formed in any con- siderable quantity at great depth during volcanic activity we should expect to find alunite a more common constituent of rocks which have been uncovered by erosion than experience indi- cates. Moreover, it is questionable whether waters rich in sulphuric acid would be efficient carriers of gold, sulphides, and tellurides. It is probable that they would precipitate these con- stituents from the alkali sulphide solutions, of which the solvent efficiency has been repeatedly shown by experiment h and by geologic evidence. In view of these considerations, and of others presently to be brought forward, the hypothe- sis, suggested with some favor in a preliminary paper/ that the ore-depositing solutions may have come from below already charged with sulphuric acid, has been abandoned. HYPOTHESIS OF DERIVATION OF THE SULPHURIC ACID FROM THE OXIDA- TION OF PYRITE. The hypothesis that the alunitization of the rocks at Goldfield was effected by cold sul- phate solutions percolating generally downward from masses of oxidizing sulphides, principally pyrite, has some facts in its favor. The small quantity of impure alunite found at Cripple o Lindgren, W., and Ransome, F. L., Geology and gold deposits of the Cripple Creek district, Colorado: Prof. Paper U. S. Geol. Survey No. 54, 1900, pp. 220-221. b Oral communication before the Geological Society of Washington. Abstract in Science, n. s., vol. 28, 1908, p. 933. c Anderson, Winslow, Mineral springs of California, San Francisco, 1892, p. 150. d Anderson, Winslow, op. cit., p. 254. ' Bull. Univ. Texas Min. Survey No. 2, 1902, p. 34. /Water resources of Beaver Valley, Utah: Water-Supply Paper U. S. Geol. Survey No. 217, 190S, pp. 19-20. g Data of geochemistry: Bull. U. S. Geol. Survey No. 330, 1908, pp. 155-157. * As regards tellurides see Lindgren, W., and Ransome, F. L., Geology and ore deposits of the Cripple Creek district, Colorado: Prof. Paper U. S. Geol. Survey No. 54, 1906, pp. 223-224. i The association of alunite with gold in the Goldfield district, Nevada: Econ. Geology, vol. 2, 1907, p. 088. 192 THE GEOLOGY AND ORE DEPOSITS OF GOLDFIELD, NEVADA. Creek was undoubtedly formed in this manner, and observations indicate that a part of the alunite at Goldfield, namely, some of the soft varieties which fill interstices in the partly oxi- dized ore, may have been, if not originated, at least dissolved and redeposited during oxidation. According to De Launay ° the alunite at the classic locality of Tolfa is the product of such solutions acting upon a particularly feldspathic trachyte. The formation of alunite by cold percolating solutions probably requires these to be more strongly acid than is necessary for the production of kaolinite. The intimate association of the alunite with kaolinite at Goldfield has a bearing on the problem. The origin of this mineral has been the subject of much recent discussion, 6 the general trend of which is to emphasize the connection between kaolinization and weathering. Lind- gren c has recently intimated that although he himself formerly referred to the mineral as characteristic of certain classes of veins, kaolinite should not be considered as a gangue mineral of any class of ore deposits except those formed under the influence of oxidation. In a subse- quent paragraph he somewhat modified this statement by the expression of belief that "kaolin is rarely formed by alkaline hot water at any considerable depth below the surface." The preponderant weight of careful observations made during the last few years is unquestionably on the side of the thesis thus moderately stated; and the occurrence of kaolinite at Goldfield, where the intimate association of the mineral with the alunite, gold, sulphides, tellurides, and sulphantimonites, as determined by microscopical work, shows that all were formed at the same time and by one general process, is an additional point against what has been called the direct volcanic hypothesis. Much kaolin originally described by various authors as formed by the solutions which first brought up the ores associated with it has later been proved to have resulted from oxidiz- ing processes, it being one of the most characteristic products of the action of percolating, weakly acid solutions upon aluminous rocks. The kaolin at Cripple Creek is a good example. Much so-called primary or pneumatolytic kaolin, moreover, has been shown to be sericite, and some is perhaps alunite. On the other hand, these facts seem scarcely to warrant the total elimination of kaolinite from the list of gangue minerals found in ore deposits, the connection of which with oxidation is at least not obvious, and which are certainly not affected by ordinary weathering. The mineral occurs as an original constituent of some of the ores of the San Juan Mountains, Colorado,"* and W. H. Weed e has described it as a product of the metasomatic action of the waters of Boulder Hot Springs, Montana, upon granite. Kaolinization has also been noted by Bela von Inkey^ in the dacitic country rock of the Nagyag veins, the material being afterwards investigated by F. Kollbeck,^ whose analysis indicates a mixture of kaolinite and sericite. The principal objections to the view that the alunitization at Goldfield is connected with the oxidation of older pyritic ores are based largely on what appears to be the quantitative insufficiency of the proposed explanation. No such available primary masses of sulphides are known, and study in the district has failed to bring to light any bodies of sulphides that are distinctly older than the ores and that are not accompanied by alunite. There is no evi- dence yet found which indicates the superposition of a distinctly younger phase of deposition characterized by the formation of alunite upon an older phase not associated with that mineral. The mines at Goldfield are still comparatively shallow, but they have penetrated about 500 feet below the bottom of the weathered ores, and if the alunitization were the result of ordinary weathering it is likely that secondary products would somewhere have been found distinctly imposed upon earlier nonalunitic material. It is probable that at a depth greater than that o La m^tallogenie de l'ltalie: Cong. geol. intern., Mexico, 1900, vol. 1, 1907, p. 681. b See especially Zeitschr. prakt. Geologie, 1907 and 1908. c The relation of ore deposition to physical conditions: Econ. Geology, vol. 2, 1907, p. 120. & Ransome, F. L., Economic geology of the Silverton quadrangle, Colorado: Bull. U. S. Geol. Survey No. 182, 1901, p. 73. e Mineral vein formation at Boulder Hot Springs, Montana: Twenty-first Ann. Rept. U. S. Geol. Survey, pt. 2, 1900, p. 253. / Nagyag und seine Erzlagerstiitten, Budapest, 1885, p. 143. g Untersuchungen iiber die Zersetzung des Quarztrachyts neben Goldersgiingen von Nagyag: Oesterr. Zeitschr. f. Berg- und Iluttenwesen, vol. 36, 1888, pp. 25-27. GENESIS OF THE DEPOSITS. 193 now attained alunite will become less abundant, but the change will, it is believed, be gradual, and there is nothing to indicate that it will exhibit such a definite relation to the general ground-water level as might fairly be expected under the hypothesis now under consideration. The alunitization of the rocks, as shown on page 176 and by figure 18, is very extensive and is by no means confined to the immediate vicinity of known ore bodies. Except in the zone of superficial oxidation the alunite is crystallized with pyrite and consequently has not formed under conditions involving the destruction of this sulphide in the zone now accessible. To account for the alunitization by the oxidation of pyrite would require the assumption that the material stripped from the district by erosion was much more heavily pyritized than the rocks at present visible. The thickness of this vanished overburden, as has been shown, can scarcely have exceeded 1,000 feet (305 meters) and probably was very much less. Moreover, the period available for alunitization was geologically very brief, since the process had already taken place when the Pozo formation was laid down. We are thus confronted by the contrast of a process remarkable for the extent and intensity of its action with conditions which, if not markedly unfavorable, were at least not such as would be expected to produce the observed effects under the present hypothesis. The remarkable concentration of the gold and associated minerals in these deposits appears to be out of all proportion to any leaching action possible within the time and distance available. This discrepancy will, it is believed, become more marked when the character and genesis of the metallic minerals of the ores are considered, as they will be in connection with the next hypothesis. HYPOTHESIS OF SIMULTANEOUS SOLFATARISM AND OXIDATION. The third hypothesis to be tested postulates that the ore constituents were brought up in hot solutions charged with hydrogen sulphide, a little carbon dioxide, and probably also with some alkali sulphides; that the hydrogen sulphide was oxidized at and near the surface to sulphuric acid, which percolated down through the warm rocks to mingle with the uprising currents carrying sulphydric acid; and that the precipitation of the richest ores took place in the zone where the two kinds of solutions mingled and as a consequence of such mingling. As Van Hisea has pointed out, the chemical reactions of weathering and of solfataric action are not so different as might be supposed, and this process differs from that of the second hypothesis chiefly in greater intensity of action and in the smaller demands that it makes on time and erosion. The hypothesis differs from the first one considered mainly in that the sulphuric acid acted as the precipitant rather than as the carrier of the ore constituents which came up in sulphide solutions. This latter view has the initial advantage of being in much better accord with all that has been learned of the chemistry of natural sulphide deposition than is the first supposition. Any explanation of the origin of the Goldfield deposits which calls for natural solvents radically different from those which carried the carefully studied ores of Tonopah, the Comstock, Grass Valley, Cripple Creek, and many other districts in this country and abroad is burdened at the outset with presumptive improbability. In accordance with the third hypothesis the hot ascending waters carried abundant hydrogen sulphide, as shown by the extensive change to pyrite of the iron originally present in the dacite and other rocks as a constituent of magnetite and silicates. This change was not confined to the rocks now alunitized, but extended outward to what has been called the propylitic aureole of alteration. The experiments of Becker6 and Doelter,c supported by studies of metaso- matically altered wall rock in various districts, suggest that the sulphur of the original solutions was in part combined with or accompanied by sodium and potassium. The changes in the dacite investigated in Chapter XIV, notwithstanding the development of the potassium- and sodium- bearing mineral alunite, do not show any addition of alkalies to the original rock, but such nega- tive evidence does not prove that no alkali sulphides were present in the primary solutions. o A treatise on metamorphism: Mon. U. S. Geol. Survey, vol. 47, 1904, p. 494. l> Geology of the quicksilver deposits of the Pacific slope: Mon. U. S. Geol. Survey, vol. 13, 1888, chap. 15. "•Einige Versuche uber die Loslichkeit der Mineralien: Tschermak's Min. n. petr. Mitth., vol. 11, 1859, p 319. 79145— No. 66—09 13 194 THE GEOLOGY AND ORE DEPOSITS OF GOLDFIELD, NEVADA. They may have been largely oxidized to sulphates and carried away to accumulate in the playa deposits of the region, just as is happening at the present day at Alkali Spring. (See p. 143.) If so, it is to be expected that at greater depth than is now reached at Goldfield the feldspars of the rocks are extensively sericitized with some addition of alkalies. That the ore-bearing solutions contained carbon dioxide is indicated by the alteration of calcium-bearing silicates to calcite in the propylitic zone. It is not to be supposed that calcite would form abundantly in rocks soaked with sulphuric acid. It does occur, however, with alunite in rhyolite on the east slope of Vindicator Mountain, and this association of minerals is probably the result of local conditions which retained under pressure and fixed in combination the carbon dioxide that otherwise would have escaped in the presence of the acid solutions necessary for the production of alunite. Such local conditions of pressure are more readily conceivable in connection with hot uprising waters than under the circumstances of ordinary weathering. In addition to sulphydric and carbonic acids the solutions carried the following, either as compounds or in ionized condition: Gold, silver, copper, zinc, lead, bismuth, antimony, arsenic, tellurium, and selenium. They probably contained also some iron and silica, although the study of rock alteration recorded in Chapter XIV shows subtraction, not addition, of these constitu- ents to the wall rock. On the. other hand, the actual ledge matter contains more silica and pyrite than was in the original rock. How much of this excess was contributed by the uprising solu- tions directly and how much was merely concentrated from the surrounding country rock is not determinable. There was probably some direct addition, however, from deep-seated sources in the immediate vicinity of the fissures. It has been shown that the Assuring of the district was very complex and irregular, afford- ing innumerable devious channels for the passage of solutions. Thus the hot solutions pre- sumably reached the surface at many places, and this distribution of the outflow must have been far more favorable to oxidation of the hydrogen sulphide to sulphuric acid and to the subsequent activity of the latter than if the uprising waters had flowed from a single vent. There is reason to believe (see p. 107) that the climate at the time the ores were deposited was comparatively arid. It is likely, therefore, that the mineral-bearing solutions, upon reach- ing the surface, were not only oxidized but were concentrated by evaporation as they flowed over the surface or percolated down through the rocks. The sulphuric waters as they pene- trated downward must have exerted a strong leaching action on the superficial rocks similar to that observable at Sulphur Bank, Cal., at the present day, where basalt has been altered to spongy masses of snowy silica by the removal of its basic constituents. At moderate depth the acidic descending solutions met uprising solutions charged with hydrogen sulphide and ore constituents, and mingled with them in a zone characterized by the presence of sulphydric, sulphurous, and sulphuric acids and by the simultaneous development of alunite and sulphides. The vertical range of this zone must have been considerable — probably 1,000 feet (305 meters) or more. The mixing of the solutions may have been effected partly by differences in density between the hot ascending currents charged with gases and the cooler descending waters, partly by convection, partly by diffusion, and perhaps partly by osmotic action. The sulphuric acid solutions would in general have greater power of penetrating the substance of the country rock than would the silica and the in part colloidal bases of the uprising solutions." It is to be remembered also that the rocks at the time of ore deposition were as a whole hard and brittle, had been recently fractured, and Avere much more generally permeable than at present, when much of the country rock, softened by alteration, is incompetent to maintain open fissures. Evidently, with the process once initiated, the waters reaching the surface would no longer represent the original ore-bearing solutions, but would be mixtures of these with sulphate waters and would contain various constituents abstracted from the rocks during alunitization, as shown in Chapter XIV. At no time in their history were the depositing solutions, if we may judge from their work, strong solvents for silica, and the quantity of this constituent transported by them was small. a See Sullivan, E.C., Experiments on the separation of the constituents of a solution by filtration through a mineral filter: Econ. Geology, vol. 3, 1908, pp. 7SO-7S6. GENESIS OF THE DEPOSITS. 195 The ledges, it is true, are siliceous, but most of the quartz was derived from the rock now altered to ledge matter and from the alunitized rock in the vicinity. Some silica doubtless came up with the solutions, but had these been very siliceous it is to be expected that they would have filled all interstices with solid crystalline vein quartz of the usual kind. On the contrary, the quartz at Goldfield is flinty or crypto crystalline, and occurs either as a metasomatic mineral replacing the country rock or as porous vuggy fillings formed by the accumulation of successive thin crusts, the process having rarely gone far enough to produce a solid mass of quartz. In this respect the deposits at Goldfield resemble those of Cripple Creek. It is possible that the crys- tallinity of vein quartz does not depend wholly or chiefly on the supply of silica available but is largely a function of pressure and temperature. At one end of the series may be the coarsely crystalline quartz of the pegmatite dikes or veins; at the other end the cryptocrystalline quartz of deposits formed close to the surface. If so, the character of the quartz at Goldfield is to be added to the other evidence in favor of superficial origin of the deposits. It is believed that the process outlined as the third hypothesis best explains the abundant formation of alunite, with subordinate diaspore, and the intimate association of these minerals with the sulphide ores and especially with the pyrite in the altered rock which surrounds the ores. This explanation of the genesis of the alunite is in accord with the experiments of Sainte- Claire Deville, a who produced the mineral artificially by subjecting, for several months, frag- ments of volcanic rock, suspended in water, to a stream of hydrogen sulphide mixed with air. By providing an efficient precipitant (sulphuric acid) supplied continuously to a definite zone traversed by the uprising metalliferous solutions, the hypothesis appears to account well for the remarkable concentration of the gold and associated constituents in this zone. As already mentioned, it is difficult to harmonize the extent and intensity of the alunitization with the hypothesis of oxidation of lean deposits during erosion. It is still more difficult to explain by such secondary enrichment the unusual concentration of the gold with so much tellurium and bismuth as are present in the Goldfield ores. Many of the important minerals of epigenetic deposits, as is well shown in the useful tables compiled by W. Lindgren6 and W. H. Emmons' can be formed under different conditions and by solutions of diverse origin. The individual minerals that can be accepted with confidence as characteristic of a single bathymetric zone and of a single mode of genesis are certainly very few. Taken altogether, the minerals of the Goldfield ores suggest deposition at moderate or slight depth. They are not, however, as a group characteristic of what is ordinarily understood as secondary enrichment. The tellurides particularly, in view of the recent investigation at Cripple Creek,d are more indicative of deposition from uprising hot solutions than of enrichment by cold descending waters. STAGES OF DEPOSITION. It has been shown in the descriptive portions of this report that some of the richest ore is of later deposition than some of the siliceous ledge matter. , The relation of this fact to the various hypotheses suggested may appropriately be considered at this place. As regards the sulphide ores at least three depositional stages have been recognized. These are (1) deposition of pyrite with famatinite, and probably also with some bismuthinite, gold, quartz, and alunite along zones of Assuring, associated with alunitization and pyritization of the neighboring country rock; (2) deposition of rich nodular ores in zones of shattering in the previously formed ledge matter; (3) deposition of narrow streaks of soft, dark, amorphous ore, often very rich in gold, along fissures in the main ore bodies. These stages are not everywhere recognizable. Moreover, it is doubtful whether they tell the whole story. It is highly probable that fracturing followed by renewed deposition has been repeated many times in the course of the formation of the most a De l'alteration, par voie naturelle et artifieielle, des roches silicatees, au moyen de l'acide sulfhydrique et de la vapeur d'eau: Compt. Rend, vol. 35, 1852, pp. 261-264. b The relations of ore deposition to physical conditions: Econ. Geology, vol. 2, 1907, p. 125. c A genetic classification of minerals: Econ. Geology, vol. 3, 1908, pp. 618-622. d Lindgren, W., and Ransome, F. L., Geology and gold deposits of the Cripple Creek district, Colorado: Prof. Paper U. S. Geol. Survey No. 54, 1906, p. 204, and Chapter XI. 196 THE GEOLOGY AND ORE DEPOSITS OF GOLDFIELD, NEVADA. important masses of ore, introducing a complexity which makes the record undecipherable. To determine whether a given mass of rich ore, with its characteristic concentric crustification, represents one or more periods of mineralization is by no means always easy. The mere fact that the gold, tellurides, and sulphides form shells around masses of dacite or andesite which have been changed to aggregates of quartz, al unite, and pyrite is not proof that the kernels had been altered before the crusts enveloped them. Many of the fragments, in fact, show by their rounded contours and by slight textural and chemical differences in radial directions that the solutions which deposited the ores acted also upon the kernel which they were incrusting. (See Pis. XXIII to XXV) . On the other hand, specimens such as those figured in Plate XXIII, E, prove that crusts of gold and sulphides may be deposited around fragments of rock that have been at least twice fissured and twice subjected to the action of solutions that deposited quartz, alunite, and pyrite. In other ore bodies there is no clear evidence of more than one period of mineralization. The third stage of deposition referred to, that which produced narrow seams of soft, dark, rich ore in some of the ore bodies, is not quantitatively of great importance. These seams may be very rich, but they are generally less than an inch (25 millimeters) in width and are filled wTith a mixture of attrition material and sooty sulphide mixtures of no definite mineralogical character. They are probably due to recent enrichment by the chemical action of the present ground water. This, as has been shown on page 220, is in some places strongly acidic and is probably capable of dissolving and redepositing alunite and some of the sulphides. SUMMARY OF GENESIS. In accordance with the hypothesis of simultaneous solfatarism and oxidation it is believed that after the intruded dacite had solidified, but possibly before it had entirely cooled, the district and part of the surrounding region was subjected to stresses of unknown origin. These found relief in a very complicated system of fissures, which were unaccompanied by any considerable displacement of the rocks. Hot waters carrying abundant hydrogen sulphide with some carbon dioxide and the various metallic constituents of the ores rose in these fissures. The dissolved hydrogen sulphide was oxidized in part to sulphuric acid in the upper parts of the fissure zones and at the surface. The resulting acidic solutions percolated down through the shattered rocks, changing their feldspars to alunite, mingling with the uprising sulphide solu- tions, and precipitating the greater part of their metallic load as ore. The original solutions apparently were not everywhere equally rich in gold, since in many parts of the district ledges were formed which have not proved to be of any value. The most highly mineralized waters rose along a north-south belt about three-quarters of a mile in length and along the line of the Columbia Mountain fault, near Goldfield. Just what significance should be attached to this coincidence of fault and mineralization is not clear. As suggested on page 83, the Assuring along this belt may have been occasioned by a renewal of movement along the predacitic fault line. The presence of the fault fissure may also have favored deep connection with the ore sources. These suggestions, however, are not susceptible of proof and would have more weight did not some good ore occur in other parts of the district. It is believed that during this first stage of deposition most of the ledges were formed, much of the country rock was softened and alunitized, other parts farther from the fissures were propylitically altered, and some masses of good ore were deposited. The ledges at this time were presumably harder than the altered rocks which inclosed them, and it would seem at first thought that any subsequent fissuring would avoid the siliceous masses and pass through the softer material. To some extent it probably did so, the stresses finding relief in gouge-filled, curved, and irregular slips through the country rock. Movements in the soft country rock, however, which is more or less plastic near the ledges, could not fail to exert on these rigid brittle masses stresses which would deform them, like the quartz pebbles in some squeezed and schistose conglomerates, by many small fractures rather than by a few simple fissures. The fractured ledge masses would be pervious to solutions, while the surround- GENESIS OF THE DEPOSITS. 197 ing squeezed country rock would be relatively impervious. Some ledges after fracturing were perhaps cut off from communication with the rising mineralizing solutions and are to-day comparatively barren. Others to which these waters had access, particularly those in which considerable sulphide deposition had previously taken place, were enriched by the revival of the circulation of hot ascending sulphide solutions and cooler descending sulphate solutions mingling in the manner already described. The conditions during this second stage of mineralization would probably be more favorable for the concentration and deposition of very rich ore than during the first stage. The shattered ledges may be likened to great sponges in the pores of which were provided ideal conditions for chemical reactions and precipitation, the sulphides already formed probably aiding directly in withdrawing gold and fresh sulphides from solution." It is not necessary to suppose that all the ledges were subjected simultaneously to this second Assuring or that all were affected by the same number of recurrent depositions. The richest ore bodies probably occur in those ledges which were most often fractured and which at the same time retained most continuously an open connection with the deep source of the hot sulphide waters. Movements in the ledges have continued up to very recent times and may be still in progress. They are no longer followed, however, by any manifestation of thermal action, although they have afforded opportunity for some minor enrichment by waters which have passed downward through the belt of weathering. Objection may be made to the foregoing hypothesis on the ground that, although the sul- phur and cinnabar deposits of Sulphur Bank, California, exhibit a mode of deposition similar to that suggested for the Goldfield ores, no other important gold deposits are known to have formed in this manner. It may be said, in reply, that no gold deposits comparable with those of Goldfield are known, and it is no valid ground for surprise that their unique character leads to an explanation different from that applicable to gold veins such as those of the Mother Lode belt in California. If the explanation here given is correct it follows that the conditions for the formation and preservation from erosion of deposits of the Goldfield type must be rare. Climate alone may exert a controlling influence. If the original sulphide solutions rose in a region of abundant rainfall, deep soil, and luxuriant vegetation, oxidation of the hydrogen sulphide to sulphuric acid would take place less rapidly, and most of the acidic solution, instead of sinking deep into the ground, might flow off in streams. Such part as did seep down and survive the reducing action of organic compounds would mingle with a ground water diluted by copious rains and too rapidly renewed by run-off and additions to be of great chemical activity. In a region of rapid erosion the entire zone of alunitization might be removed in a geo- logically short time and deposits of no unusual character be left. ULTIMATE SOURCE OF THE ORE-BEARING SOLUTIONS. What was the ultimate source of the solutions that brought up the ores? Consideration of this question takes us into a region where facts and hypotheses, inference, and speculation are distinguishable with great difficulty, and where, in consequence, dogmatism finds congenial soil. A genetic connection with volcanicity is strongly suggested by the geologic history of the region and is well-nigh proved by the chemical character of the solutions and by the presumably high temperature at which they issued. This connection is indicated also by some points of similarity, particularly the presence of tellurides, between the Goldfield ores and those of Cripple Creek, for which deposition from hot magmatic solutions appears more nearly demonstrable than for any district yet studied in equal detail. The thesis that the hot uprising solutions at Goldfield emanated directly and solely from some crystallizing magma is, however, still far from proof. The possible share, in much ore deposition, of water that at some time in its history was precipitated from the atmosphere is not to be lightly dismissed. The argument, frequently advanced, that the dryness of most very deep mines precludes the primary concentration of ores by meteoric water is not of great cogency. Its validity depends on the assumption that « See Clarke, F. W., The data of geochemistry: Bull. U. S. Geol. Survey No 330, 1908, p. 558. 198 THE GEOLOGY AND OEE DEPOSITS OF GOLDFIELD, NEVADA. the present conditions of permeability in the rocks are the same as when the ores were deposited. This obviously is not true. If it were, deposition by water from any source would have been impossible. The fracturing which permits the ascent of hot solutions also in most cases favors the descent of surface water. According to Arrheniusa there is no reason why this descending water should not penetrate to, and in the gaseous state be absorbed by, molten magmas. Evidence has already been presented which shows that during the deposition of the ores the rocks at Goldfield were more permeable to descending water than at present, or alunitization would probably never have extended so far and so deep. It is supposed that this downward- moving water wTas for the most part water that had first risen to the surface, but who can say how much rain water mingled with this and how deep the resulting mixture actually penetrated ? The work of Gautier,6 also, shows how volcanic action, by heating masses of solid rock and generating therefrom large quantities of water and of the same gases as are emitted from fumaroles, may play a part in ore deposition which is not dependent on the original water content of the intruding magma. Although not inclined to deny the very important part played by volcanism in ore depo- sition, and while convinced that volcanic emanations have been largely responsible for the formation of the Goldfield ore bodies, I believe that we are not in a position to insist on the all-sufficiency of hypogene waters (that is, juvenile or original magmatic waters) to account for the deposition of most epigenetic deposits. The cooperation of water from different sources is not a negligible possibility and in the complex conditions and delicate adjustments incident to such cooperation is perhaps a suggestion of the reason why ore deposits are exceptional rather than invariable accompaniments of igneous intrusion. The mineralizing capacity of cold artesian solutions is ordinarily slight. Most masses of intrusive rock, on the other hand, are not associated with productive mineral deposits. It is possible, however, that conditions most favorable for ore deposition may result when magmatic and meteoric water, and perhaps water of other kinds than is usually implied by these terms, contribute to the final result PRESENT ABSENCE OF VOLCANIC ACTIVITY. So far as can be determined from existing mine workings volcanic activity, notwithstand- ing its geologic recency, has completely died out at Goldfield. The mines receive no hot or warm Water and no gases such as at Cripple Creek mark the final stage of expiring volcanism. This is rather remarkable, since many of the springs in this part of Nevada are thermal, and Spurr c found that at Tonopah the temperature increases downward at more than the normal rate. The highest rock temperature recorded by him was 78° F. (25.6° C.) at a depth of 766 feet (233 meters) in the Ohio Tonopah shaft. Recently, however, water at a temperature of 86° F. (30° C.) has been encountered at a depth of 1,250 feet (381 meters) in the Mizpah shafts Although no appreciably warm water occurs at Goldfield it is possible that refined tempera- ture observations in the deeper shafts lately available might show a trace of the former heat in a temperature gradient somewhat higher than the normal for nonvolcanic regions. It is to be remembered that the waters of the Comstock lode had a temperature of only 70° F. at the 600-foot level/ It does not appear possible to connect the volcanic contribution to the Goldfield deposits with a magma corresponding definitely to any of the eruptive rocks in the Tertiary sequence. The supposition that the principal metallic constituents (with the exception of the iron) and some at least of the water in which these were carried issued from a body of dacitic magma is an attractive one, but has little real evidence in its favor. It may be remarked in this connection that a chemical analysis of the glassy, extrusive dacite vitrophyre shows 3.35 per cent of water a Zur Physik des Vulkanismus: Geol. Foreningens Stockholm Forhandl., vol. 22, 1900, pp. 395-41U. <> La genese des eaux thcnnales, etc.: Annales des mines, 6th ser., vol. 9, 1906, pp. 316-370. Translated In Econ. Geology, vol. 1, 1906, p. 688. e Geology of the Tonopah mining district: Prof. Paper V. S. Geol. Survey No. 42, 1905, p. 263. d Letter from Mr. W. II. Blackburn, superintendent of the Tonopah Mining Company. <• Becker, G. F., Geology of the Comstock lode: Mon. U. S. Geol. Survey, vol. 3, 1882, p. 252. GENESIS OF THE DEPOSITS. 199 driven off below 110° C. and 4.06 per cent lost above that temperature, a total of 7.41 per cent. The intrusive dacite, on the other hand, contains 2.95 per cent of water, 2 per cent being driven off above 110° C. It is not quite certain that these two rocks had the same magmatic origin, but if so the dacitic magma originally contained a large quantity of water, much of which was expelled during the solidification of the more crystalline facies, as shown by the difference of over 4 per cent between the water of the two analyses. If the ore solutions came from this magma they presumably rose from portions solidifying at such depth as would develop a still higher degree of crystallinity than in the visible dacite and lead to a further expulsion of water and mineralizing constituents. It is quite possible, however, that the ores emanated from a magma differing in composition from any one of the eruptive rocks in the district. GOLDFIELD TYPE OF DEPOSIT. The recognition of alunite as a characteristic constituent of the Goldfield ores and the demonstration of its genetic relation to them establishes a new type — that of alunitic and kaolinitic gold-quartz veins — in the classification of epigenetic deposits based upon the kind of metasomatism effected in the wall rock by the ore-depositing solutions. While the Goldfield deposits are probably too irregular in form to come under the usual definition of vein, yet in all that relates to genesis of the ores there is no essential difference between them and what is usually termed a metasomatic fissure vein. According to Robert T. Hill,™ mineralization very similar to that at Goldfield has affected the rocks in the mining district of Alunite,6 22 miles (35 kilometers) southeast of Las Vegas, Nev. Prospecting is in progress but no ore bodies of importance have yet been found. This chapter may fittingly be closed by recalling to mind how complex is the problem of genesis of most deposits of the precious metals and how uncertain in character are the data available for its solution. These are fragmentary and only in small part consist of definite facts with known quantitative values. A careful sifting of more or less doubtful evidence is all that is possible and the result is usually a matter of judgment rather than of mathematical proof. As regards Goldfield the evidence has been presented without conscious bias and the conclusions are submitted to the reader with full realization that no one of the three hypotheses suggested is certainly impossible. Were the question referred to a geological court its decision might not be unanimous. a Camp Alunite, a new Nevada gold district: Eng. and Min. Jour., vol. 80, 1908, pp. 1203-1206. 6 A new name for a district prospected years ago and formerly known as Railroad Pass. CHAPTER XVII. PRACTICAL CONCLUSIONS. If the genesis of the Goldfield deposits has been correctly inferred it follows that the deposition of rich ore is connected with alunitization. It follows, further, that at some depth not yet determined the alunitic phase of alteration is replaced by metasomatism of a different kind, probably sericitic, accompanied by ores of lower grade. To a depth of 600 feet (183 meters) there is little if any decrease in the abundance of alunite, but there are indications of generally lessening tenor of the ores. There may be individual exceptions to this last state- ment, but few thoroughly familiar with the underground workings in the district and capable of impartial judgment are likely to question its essential truth. Even if the rocks below the depth of 600 or 700 feet (183 or 213 meters) were the same as those above, it is believed that considerable changes in the character of the deposits might be looked for in the next 300 or 400 feet (91 or 122 meters) of vertical development. The rocks, however, are not the same, and this fact renders prediction very uncertain. The latite, which generally underlies the dacite and Milltown andesite, may prove nearly as good an ore bearer as the latter two rocks. This, however, is a little doubtful. Most of the shafts in the principal mineral belt may at any depth below 1,000 feet (305 meters) enter rhyolite, Cam- brian shale, or alaskite, and although no one can with certaint}7 assert the barrenness of these formations their present record in this district is not encouraging. The tendency of the main ledges near Goldfield to flatten out to the east on the lower levels is also rather disconcerting, although the significance of this feature can not be fully understood until the deep levels are further developed. This behavior does not prove that the ledges may not somewhere regain a steeper dip and continue down through the predacitic rocks, but it defers the confirmation of that hopeful supposition, increases the difficulty of exploitation, and introduces greater possibilities of losing pay shoots by faulting.0 Above the 500-foot (152-meter) plane the productive possibilities of the district are still great. In the principal mines there are large reserves of ore which can be milled at a profit, although most of the richest portions have been mined by lessees. In the announcement of the Goldfield Consolidated Mines Company at the end of 1906 the ore reserves of the Mohawk, Jumbo, Red Top, and Laguna mines were estimated at $7,750,000. This was said to be "exclu- sive of low-grade ore," and did not include the Combination and January mines, later acquired. In the same announcement it is estimated that at least $30,000,000 gross may be produced from known ore shoots in the Mohawk mine alone. The quantity of ore available is undeniably large, but in no district are the difficulties in the way of estimation greater, owing to the irregular shape, erratic distribution, and wide range in tenor of the pay shoots. Many new ore bodies are likely to be found in the rich belt near Goldfield, although so thoroughly has this part of the district been explored that it is not probable that any deposit of the importance of the Mohawk ledge has escaped detection. On the other hand, the pro- ductive areas are steadily being enlarged by the discovery of new ore bodies, and in spite of much fruitless prospecting over the district at large the possibility of success in some hitherto unproductive localities is still open. There is, and probably always will be, a large element of chance in the discovery and mining of deposits of the precious metals, and it is vain to expect that geologic stud}', no (i According to the Engineering and Mining Journal of January 2, 1909, the Clermont shaft has cut the Mohawk pay shoot at 850 feet (201 meters), or 241 feet (73 meters) below the bottom of the dacite. The ore is said to assay $22 a ton. This is encouraging as regards the possibilities in the latite. 200 PRACTICAL CONCLUSIONS. 201 matter how conscientiously and ably pursued, can eliminate all of the risks of the search. The obscure conditions that determine the movements of underground solutions and influence the precipitation of their contents can rarely be discovered from the relations of the rocks at the surface. Geology can seldom do more than suggest intelligent trial; and he who undertakes extensive prospecting without a realization of the ratio of success to failure and without being prepared to shoulder the latter, is playing desperately against chance. On the other hand, it must be admitted that were prospecting in general conducted with the same caution and with the same careful scrutiny of probabilities as obtains in ordinary business many deposits which have yielded fortunes to their discoverers would never have been found. There are few gold districts that are not indebted to some man's blind good fortune. This has been well illustrated at Goldfield, and the brief but eventful history of the district teaches that surprises may be in store for one who presumes to say with assurance what ground is ore bearing and what ground is not. Local experience has shown a close connection between rich ore and alunitization. This association is of value as indicating the better chances of a prospect in alunitic material than of one outside of it. On the other hand, the presence of alunite is no proof of the presence of gold, even in this district, as many have learned to their cost, and the hasty generalization that alunitized rocks, wherever found, must be gold-bearing rocks is wholly unwarranted. The occurrence of this mineral means simply that rocks containing some potassic and aluminous silicate have been acted upon by sulphuric acid. A second deduction is that these rocks must have contained pyrite or else have been subjected to solfataric action. In either case mineralizing processes have been active and gold or other metals may have been concentrated. The reason- able conclusion is merely that the locality is worthy of some prospecting. Local experience at Goldfield has shown also that the rich ores are more or less intimately associated with the craggy siliceous outcrops characteristic of the district. This does not mean that all such are auriferous, nor does it mean that no bodies of ore occur under topo- graphic depressions floored with soft rock. It is evident that the dip of a ledge or pay shoot must carry it in places under rock which is soft at the surface. Experience does suggest, how- ever, that exploration near ledge outcrops is more likely to yield results than shafts sunk at a distance on low ground or in areas covered deeply by lacustrine or alluvial deposits, unless such shafts are put down to cut a known ledge on the dip. With reference to the areal distribution of the deposits, no part of the district appears likely to surpass in richness the small elongated area containing the Red Top, Mohawk, Com- bination, Jumbo, and Florence mines. The geologic conditions which have determined the remarkable preeminence of this limited area are not certainly known, although, as suggested on page 83, the relation of the Columbia Mountain fault to the dacite may partly account for the exceptional concentration of gold. As regards general geologic features the belt of conspicuous outcrops stretching from ' the vicinity of Milltown past Preble Mountain appears promising. It has been very persistently prospected, however, with but indifferent or negative results. CHAPTER XVIII. DETAILED DESCRIPTION OF THE MINES OF THE GOLDFIELD CONSOLIDATED MINES COMPANY. INTRODUCTION. The mines to be described in this chapter, in general order from north to south, are the Red Top, Mohawk, Jumbo, Combination, and January. The history of the consolidation of this group has been given in Chapter I, and the relative positions of the mines are described on page 136 and shown in Plate IX. The close connection or proximity of the various under- ground workings, not only of those belonging to this group, but of the workings of other com- panies and of lessees, although it increases the difficulties of systematic treatment, has a com- pensating advantage in that it saves some repetition of descriptive details. Certain features well displayed in one mine will be fully described, while the same characteristics occurring less conspicuously in another member of the group will merely be briefly noted. The space devoted to the description of each mine depends less upon the size or productivity of the property than upon the information its workings supply relative to the geologic occurrence and genesis of the Goldfield ores. RED TOP MINE. HISTORY. The Red Top mine, although older than the Mohawk, was late in development in compari- son with the January, Combination, and Jumbo mines. In April, 1904, some ore was found by lessees, but this apparently was not of great extent, for the mine attracted little further attention until February, 1905, when the main ore shoot was opened by the Red Top Mining Company. By November in the same year the mine had produced ore to the value of $60,000, and in December it became one of the principal mines in the district. Its total gross production up to the consolidation in November, 1906, was $308,515.60. Under its present ownership the mine produced ore of the gross value of $201,025.51 from December 1, 1906, to October 31, 1907. At the time of last visit, in July, 1908, no work was in progress in this property, although mining will undoubtedly be resumed when the company's new mill is in operation. UNDERGROUND WORKINGS. At the time of first visit, late in 1905, the Red Top shaft was 180 feet deep, with levels at 100 and 165 feet. These two levels, which were short, ran generally north-northwest and south- southeast. There had been no stoping at the time the mine was studied, all the ore having been taken from drifts and from a raise above the 100-foot level. At the time of second visit the workings had been developed as shown in Plate XXXII. Unfortunately, the levels above the 165-foot level were not accessible at that time, and some of the long crosscuts to the west on the lower levels, which probably pass from dacite into latite, had caved. The ground in the vicinity of this contact is in most places very soft, constant attention being required to keep it from faffing. Extensive stopes have been opened in the oxidized ore between the 165-foot level and the surface, but practically no attempt has been made as yet to handle the sulphide ores below that level. 202 U S GEOLOGICAL SURVEY PROFESSIONAL PAPER 66 PLATE XXXII 3X O \ ^ O SECTION ON LINE A-A' (largely conjectural) ^r IOO 200 feet Shaft 50-ft. level 100-ft. level o a v -^ — -JL 260-ft. level Gouge $ **&, -^ / " V ^30-ft. level PLAN AND SECTION OF RED TOP MINE MINES OF THE GOLDFIELD CONSOLIDATED MINES COMPANY. 203 GEOLOGIC RELATIONS. The Red Top workings are principally in dacite and dacitic ledge material. The shaft, however, goes into latite between the 260-foot and 330-foot levels, as shown in Plate XXXII. The exact place of the contact in the shaft could not be determined. On the 330-foot level the contact lies 80 feet east of the shaft, and is, locally at least, a fault, accompanied by a seam of tough black gouge about 2 feet in width. It dips east at a low angle. The latite under the gouge is much crushed and is traversed by many smaller seams of gouge. The dacite in the hanging wall of the fissure is alunitized and silicified. This fault lies in the general course of the Columbia Mountain fault and probably represents some of the later movement along that fissure. THE LEDGE. The Red Top ledge as exposed at the surface is unusually wide. It apparently consists of several closely spaced zones of mineralization which trend in a north-northwest direction and altogether attain a width of about 150 feet. The outcrop, however, is short, probably not over 200 feet in length, and the superficial aspect of the ledge is that of a great bunch of rusty silicified dacite. The actual form of the ledge is very unsatisfactorily shown by the under- ground workings. On the 165-foot level the ledge matter varies in width from 100 to 200 feet, and on the 260-foot level is still wider. As a rule, crosscuts show it to be separated from the soft country rock by seams of gouge which in general dip to the east. It is by no means certain, however, that the hanging wall as drawn in Plate XXXII corresponds to a single continuous fissure, and it is still less likely that the fissure which locally forms the hanging or foot wall at any given place on a level is the same as the fissure forming the corresponding wall on the level below. The foot wall particularly appears to be much steeper between the 100-foot and 260-foot levels than the dips of the observed individual fissures would indicate. In a few places ledge matter grades into country rock without any indication of movement between the two. Points of access to the bounding surfaces of the ledge are at present far too few for the con- struction of a reliable cross section. The section shown in Plate XXXII is to be taken, not as a representation of fact, but as a provisional essay at interpretation. Future work will modify it, but for the present it has its use as a graphic summary of what is known and as an attempt to visualize a conception of what may be. On the south the Red Top ledge appears to be separated from the ledges of the Mohawk No. 2 and Wedge claims (see PI. IX) by soft altered dacite, and it is the presence of this soft ground that has enabled erosion to cut the little depression through which the road runs just south of the mine buildings. This ground has not been much explored. It is evidently con- siderably fissured, and the 165-foot level, as shown in Plate XXXII, when pushed southward encountered and followed for some distance a fissure striking about N. 60° E., and dipping 35° S. It was through this gap in the continuity of the ledge matter that the hypothetical cross fault referred to in the preliminary report was supposed to pass. It is no longer neces- sary to assume such a fault, but future underground work may establish a relation between an apparent slight offsetting of the Red Top ledge, with reference to the trend of the Mohawk ledge system (see PI. IX), and a possible zone of displacement running near and approximately parallel to the south end line of the Red Top claim. This is merely a suggestion, as there is no definite evidence as yet that any important faulting has taken place along this line. On the north the Red Top ledge also appears to end rather abruptly. Development from the Harrison shaft (PI. IX), now abandoned, showed great disturbance of the dacite, but no ledge matter nor ore. On the other hand, the Consolidated Red Top shaft a little farther north and on the same line was in ledge and ore in 1908. It is probable that the ending of the Red Top ledge to the north is due primarily to the original irregular character of the mineraliza- tion, and not to any important cross faulting. 204 THE GEOLOGY AND ORE DEPOSITS OF GOLDFIELD, NEVADA. The general material of the ledge is similar to that of other ledges in dacite. Kaolin is abun- dant in the oxidized part, forming irregular seams and bunches in the shattered, altered, rusty dacite. Where pure and waxy the kaolin is rarely gold bearing. Certain gritty varieties, how- ever, in which the kaolinite is mixed with minute quartz grains or crystals and more or less stained with limonite, are highly auriferous. Partial oxidation of the ledge matter extends down to the 165-foot level. The unoxidized material differs in no essential respect from the ledge matter of other mines in dacite. It contains abundant pyrite and alunite. Much of the dacite in the ledge, particularly on the 330-foot level, is divided into thin plates by closely spaced sheeting, the narrow fissures being filled with alunite and quartz. THE PAY SHOOTS. Not enough work had been done at the date of first visit to determine the shape and distri- bution of the pay shoots. They appeared to be irregular and to occur mainly near the hanging wall of the ledge. All the ore taken out in 1905 was oxidized. The only sulphide seen on the 165-foot level was pyrite, and none of the unoxidized ore then visible appeared to be of shipping grade. Two specimens taken as representative of this pyritic material yielded on assay less than $3 per ton. Some of the oxidized ore, on the contrary, was rich, one assay obtained in 1905 giving about $12,500 to the ton. The best of the oxidized ore was a soft, yellow ocherous mixture of kaolinite, quartz, limonite, and native gold. Some of the oxidized ore was very carious, con- sisting of masses of silicified dacite in which cavities, probably at one time partly filled with sulphides, had been etched out by solutions. (See PI. XXIV, B.) These cavities were lined with drusy quartz and partly filled with kaolinite, with possibly some alunite. The sulphide ore exposed in the lower levels of the Red Top in 1908 appeared to be of relatively low grade as a whole, showing little free gold, famatinite, or bismuthinite, such as characterize the rich ores in the Combination and Florence mines. No tellurium mineral has been recog- nized as yet in this mine. Some very good sulphide ore, said to assay from $100 to $200 a ton,' has been opened on the 165-foot level south. This shows specks of famatinite and crystals of pyrite in a quartz alunite gangue. A body of $75 ore also is known on the 260-foot level, west of the shaft. The ore body, as is usual in the Goldfield mines, is of irregular shape. Its total length is about 300 feet. There was no opportunity to study the pay shoots in 1908, and it is doubtful whether enough work has been done to determine the shape and extent of the sulphide ore bodies. MOHAWK MINE. INTRODUCTION. The history of. the Mohawk mine is an essential part of that of the district and has already been related on pages 18-20. The total gross production of the mine up to the end of 1907 amounts to approximately $10,000,000. The following table, compiled from the prospectus and first annual report of the Goldfield Consolidated Mines Company, while not complete and possibly containing a slight overlap or duplication of the production from leased ground in November, 1906, is of some interest as showing the important part played by lessees. Some features of the production of the Mohawk mine. Production by lessees up to November 20, 1906 Production by lessees for year ending October 31, 1907 Mohawk Company shipments for year ending Octol>er 31, 1907. Ore in tons of 2,000 pounds. 34,797.371 15, 213. 540 Gross value. $4,075,919.32 1,230,190.75 a Calculated from royalties at 22{ per cent. Net value. $3,135,426.39 0.3,910,430.00 849, 789. 70 Royalties. $705,469.55 782,056.04 Average gross value per ton. $117.10 80.' 86 MINES OF THE GOLDFIELD CONSOLIDATED MINES COMPANY. 205 The royalties for the second period in the foregoing table were distributed as follows: Royalties, Goldfield Mohawk Mining Company, year ending October 31, 1907. Hayes & Monnette lease $370, 202. 71 T. L. Oddie et al 987. 62 Kalfus lease 1,157.59 Mohawk Leasing and Developing Company (Truett) 17, 179. 99 Frances Mohawk Mining and Leasing Company: 250, 048. 83 Mohawk Lease Company (Van Riper) 3, 757. 48 D. Mackenzie & Co 3, 717. 79 Loftus, Davis & Sweeney lease 33, 744. 09 Mohawk-Combination lease (Kalfus) 58, 557. 31 Curtis Brothers lease 33, 101. 21 Begole lease .'. 5. 35 McNaughton-Mohawk Leasing Company 9, 568. 78 F. E. Haily lease 27. 29 782, 056. 04 During the single month of October, 1906, the Hayes-Monnette lease produced $1,300,000. The richest shipment weighed 47.7 tons and contained 609.6 ounces of gold and 75.4 ounces of silver per ton, the gross value of the shipment being approximately $584,800. UNDERGROUND WORKINGS. In 1905 there were two shafts on the Mohawk No. 2 claim, the Hayes-Monnette No. 1 and the Kalfus shafts. Neither was in ore, and neither so far as could then be seen, was any more promising than dozens of other prospects in the district. The highest assays that had been obtained from these workings did not exceed $4, although the Kalfus shaft was then 200 feet deep and had considerable exploratory work on three levels. After the discovery of rich ore in April, 1906, lessees began a very active exploration of the whole claim through more than 15 shafts. Before the leases expired, the Goldfield Consolidated Mines Company sank what is now the main Mohawk shaft. The plan of the present workings is shown in Plate XXXIII. The Mohawk shaft is 600 feet deep, with levels of 246, 350, 450, and 600 feet below the collar. These main levels, which lie mainly in the southeast part of the claim, connect at various places with the intricate maze of lessees' workings, which are mostly above the 246-foot level. It is possible to go by rather devious routes through these workings from the north end to the south end of the claim. Connections exist also with the lessee work- ings on the Gold Wedge fractional claim and with the levels of the Combination Fraction mine. The 350-foot Mohawk level connects with the 380-foot level of the Combination mine, through which it is possible to pass into the January mine and through the Reilly workings into the Florence mine. With the exception of the Sheets-Ish incline (see PI. XXXIII), and some ground adjacent to it, the lessee workings were for the most part accessible in 1908. The general trend of the Mohawk ledge zone is very nearly north and south and the general dip is at angles ranging from 30° to 45° E. Thus successively deeper levels are farther and farther east, and some of the deepest stoping in the district has been done in the Mohawk- Jumbo lessee workings on the Gold Wedge claim. There are practically continuous stopes down the general dip of the ledge from within 100 feet of the surface at the Hayes-Monnette No. 1 shaft to the 600-foot level of the Mohawk. About 900 feet northeast of the southeast corner of the Mohawk No. 2 claim is the new Jumbo shaft on the Clermont claim. This is expected to cut the Mohawk ledge at a depth of 800 feet. It is at present 612 feet deep, and the company is driving to connect this shaft with the 600-foot level of the Mohawk." « See footnote, p. 260. 206 THE GEOLOGY AND OEE DEPOSITS OF GOLDFIELD, NEVADA. N. n 190 Figure 21.— Geologic plan of the 000-foot level of the Mohawk mine. GEOLOGIC RELATIONS. The principal country rock of the Mohawk mine is dacite. The main shaft, however, goes into latite at the 450-foot level and the crosscut from the bottom of the shaft to the ledge on the 600-foot level is almost wholly in this rock. The contact between the dacite and latite is exposed in very few places and these throw little real light on its character. The relations vis- ible on the 600-foot level at the time of visit are illustrated in figure 21. About 30 feet south of the station the crosscut goes through a strong seam of gouge and beyond this the latite is soft and is traversed by many gouge-filled fissures. Some dacite appears in the east side of the crosscut, but on account of the soft, disturbed character of the rocks its relation to the latite is far from clear. It is perhaps in part faulted against the latter rock, but at one place the contact appears to be of the irregular kind characteristic of intru- sion. The boundary between the soft, altered latite and the siliceous variety constituting ledge matter is sharp, but is not accompanied by gouge and does not appear to be a fault plane. The actual contact between the latite and dacite is within the ledge matter, both rocks being locally changed to ore. This mineralization has obscured the original char- acter of the contact, but the latite at the point where the drift leaves the crosscut clearly dips under the dacite at an angle of approximately 15°. The ob- served relations are sketched in figure 22, and are interpreted as indicating a probable igneous contact between the dacite and the older latite. It is be- lieved that this point in the Mohawk mine is very near the bottom of the thickest part of the dacite sheet, and that further developments to the east will probably show the dacite-latite contact dipping generally to the west. From the structural point of view the work on the 600-foot level at the time of visit was entering into a very interesting and critical stage. On the 450-foot level the dacite-latite contact is exposed at the main shaft. At this place there is no mineralization and the two rocks appear to have been brought together by faulting, as they are separated by a seam of gouge which dips to the east. The distance in a straight line between this exposure, which is partly concealed by the shaft timbering, and the one on the 600-foot level is about 3S0 feet. Does the contact extend approximately as a plane between these two points? Is it rolling? Is it broken and stepped by faults ? The present workings furnish no definite answers to these questions and the distance is obviously too great, considered in con- nection with known irregularity in the contact elsewhere, to be bridged by assumptions. The contact is probably not regular, but the extent to which it departs from a plane and the manner of this departure, whether by faulting or by intrusion, can not be determined. The contact was seen at one other place on the 450-foot level. This is in the crosscut west from the Mohawk shaft under and past the Mackenzie shaft. (See PI. XXXIII.) Most of the crosscut is in the usual soft pyritized latite, but about 25 feet west of the Mackenzie shaft dacite appears. Both rocks at the contact are soft and altered, and it is impossible to determine whether the contact is due to intrusion or faulting. The dacite west of the contact is com- paratively fresh and unmineralized and extends beyond the face of the crosscut. It is supposed to be a large dike cutting up through the latite and connecting with the dacite sheet above as shown in Plate VIII, section C-C. This conclusion, however, is by no means certain. Top of level Dacitic ledge matter Bottom of level 5 j i i i — i 10 FEET _1 Figure 22.— Diagram showing relation of Mohawk ledge to the dacite-latite contact on the 600-foot level. US GEOLOGICAL SURVEY PROFESSIONAL PAPER 66 PLATE XXXIII PLAN OF THE MOHAWK MINE, SHOWING ALSO THE WORKINGS OF LESSEES ON THE GOLD WEDGE CLAIM MINES OF THE UOLDFIELD CONSOLIDATED MINES COMPANY. 207 On none of the levels above the 450-foot does latite appear, so far as known. The scantiness of the data which the Mohawk mine furnishes on this interesting geologic feature is apparent. In an intermediate inclined drift above the 215 stope on the 350-foot level (see fig. 18, p. 162) a mass of soft pyritized latite was noted which appeared to be a block included in the dacite. FORM AND DISTRIBUTION OF THE LEDGES. The ore-bearing ground of the Mohawk is sometimes referred to as if it were a single well- defined lode or ledge with definite walls. The propriety of such usage is questionable, although it is difficult in practice to avoid it altogether. The productive zone as a whole trends about N. 5° E., and extends from the south corner of the Mohawk No. 2 claim to the vicinity of the McNaughton shaft near the north corner, a distance of about 1,200 feet. The general dip of the whole is at an average between 30° and 45° E. The ore nowhere reaches the surface, although it approached within about 50 feet of it in the Sheets-Ish incline. (See PI. XXXIII.) Consequently the surface affords practically no indication of the width or outline of the ore-bearing zone. The cross sections shown in figure 15 indicate a probable width of outcrop of about 200 feet, but this is largely conjectural. These sections show the outline of the ore-bearing ground only in the most general fashion, it being evident from the few workings cut by each section that the available data are far from sufficient to establish the form of so irregular a mass. Moreover, the material represented as ledge matter in the illustration includes much soft dacite which has the usual character of the country rock, and the material represented as country rock includes some bunches of ledge matter. Furthermore, the real outlines of the ledge matter are undoubtedly not the smooth curves shown in the illustration, but are broken and stepped by many minor faults. The difficulty of interpolating with assurance between known points underground is illus- trated by figure 18, which is a plan of the 350-foot level. The so-called hanging wall is probably visible in more places on this level than on any other. Near the upper Curtis shaft this wall, which is a gouge seam dividing ore or ledge matter from soft, altered dacite, has a curved but generally northerly course. Near the Mohawk shaft the hanging wall swings to the east and a similar seam of gouge traverses the ledge matter, passing through the shaft. The two fissures must join or intersect about 100 feet south of the main shaft. Near the Mohawk-Jumbo stope the hanging wall turns northwest. As a whole it is a very sinuous curve. The hanging wall is probably not a single fissure but a series of fissures, each one of which serves as hanging wall for a short distance and then passes either into ledge or country rock. The significance of this is that the hanging wall is probably as erratic in section as it is in plan. Neither in plan nor section can its true course be drawn from a few isolated exposures. Inspection of the general mine map (PI. IX) shows that the Mohawk stopes all end on the south along a nearly east and west line passing about 100 feet north of the Burns shaft on the Combination Fraction claim. This line corresponds in part with the valley followed by the railroad between the Combination and Mohawk mines. The rock under this valley, as shown by workings from the Burns shaft and by the connecting drifts between the Mohawk and Com- bination mines, is generally soft and is much disturbed. It contains, however, more or less ledge matter which forms a link between the Mohawk ledge and the Combination ledge, as will be shown in the description of the latter mine. On the north the Mohawk ledge becomes ill-defined in the vicinity of the Packard No. 1 shaft and shows much disturbance. Whether there is any direct connection between the Mohawk and Red Top ledges is not known. Moreover, where more or less ledge material occurs very erratically distributed through the dacite, as it does in the strongly mineralized area containing these mines, it is often most difficult to decide what does and what does not constitute a connection between one ledge and another. The ledge worked from the Sheets-Ish incline (see PI. XXXIII) has, so far as known, no direct connection with the ledge exploited in the main Mohawk mine. It has the same strike and a similar dip to the east. From the plan of the workings the Sheets-Ish ore bodies appear 20S THE GEOLOGY AND ORE DEPOSITS OF GOLDFIELD, NEVADA. to be in the foot wall of the Hayes-Monnette shoot. A section across this shoot, however, shows that it has an average dip to the east of about 30°, and that if it continued to the surface at this angle it would outcrop from 100 to 200 feet east of the line of strike of the Sheets-Ish shoot. Both, therefore, are probably in the same zone of mineralization, although so far as present workings show they are separated by soft barren dacite. The Sheets-Ish ore is pre- sumably near the foot wall of the zone, while the Hayes-Monnette shoot is in general nearer the hanging wall. Just north of the Kalfus shaft is the theoretical apex of a ledge which has a nearly east and west course near the surface and dips to the south. The strike of this ledge on successively lower levels becomes more nearly north, and the ledge finally appears to merge with the north- south Mohawk ledge. It is a striking example of the irregular spurs or offshoots which are characteristic of the Goldfield ledges and which render it impossible to ascertain the shape and extent of one of them until it has been very thoroughly explored. The material of the Mohawk ledges is chiefly dacite which has undergone the kind of alter- ation described on pages 176 to 186. There are all gradations between dacite which is soft with alunite as the principal secondary mineral, and the flinty quartzose varieties which as a rule constitute the ore. Irregular fracturing or shattering is a less characteristic feature than in the Combination mine and much of the rock on the Hayes-Monnette stopes is closely sheeted. Similar sheeting was noted also in the new diifts on the 600-foot level. Alunite is abundant throughout the ore-bearing ground, both as a megascopic and microscopic constituent of the altered dacite and as the filling of the innumerable small fissures. Although in many places there is a fairly abrupt change from the generally siliceous mate- rial recognized as ledge matter to the generally soft alunitized dacite recognized as country rock, there are many parts of the mine where the change is gradual and where it is impossible to make any sharp distinction between the two. Moreover, the masses regarded as ledge matter nearly everywhere contain ill-defined masses of dacite of the same character as the country rock. Most of the Mohawk workings are below the zone of oxidation, which in general does not extend much more than 100 feet in depth. When the Mohawk mine was examined, practically no stoping was in progress and condi- tions were not the most favorable for a study of the ledge material. Moreover, such study had previously been made in the Combination and other mines, and in the account of these the reader will find additional details which it is unnecessary to repeat in the description of the Mohawk. FORM AND DISTRIBUTION OF THE PAY SHOOTS. The pay shoots of the Mohawk mine, as shown by the stopes in the plan (PL XXXIII) and sections (fig. 15), are irregular bodies of ore distributed through the ledge matter into which they grade. Up to the present time there has been little attempt at working low-grade ore, and the stopes as a rule represent the rich kernels of bodies which will undoubtedly be more extensively worked in the future, and of which the size and shape is as yet very imperfectly known. The great stope between the two Hayes-Monnette shafts, which produced in round figures $5,000,000 from ore averaging $400 a ton, extends from near the 245-foot level to the bottom of the oxidized ground, a vertical distance of nearly 150 feet. This rich shoot, as shown in Plate XXXIII, did not extend straight down the dip of the ledge but pitched to the north. Its stope length was about 75 feet. It was exceedingly irregular in form, however, and its dimensions and plan varied greatly at different levels. The stope as seen in 1908 was a succession of great chambers, suggestive rather of the surprises and ramifications of a natural cavern than of an artificial excavation. The view of the stope shown in Plate XXI, B, was taken at an early stage in its development and illustrates very imperfectly the size and shape which it afterwards attained. As shown by Plate XXXIII, other rich irregular shoots of ore were worked from the Truett, Frances-Mohawk, Upper Curtis, and Loftus and Davis shafts, each shaft, hi the order named, MINES OF THE GOLDFIELD CONSOLIDATED MINES COMPANY. 209 cutting the ore at greater depth. These ore bodies form practically one continuous shoot which connects directly with that worked in the Hayes-Monnette lease and has been explored down to the 600-foot level of the Mohawk. South of the main shaft, on the 350-foot level, there is a chain of stopes on this ore shoot for a distance of about 350 feet. On the 450-foot level ore in the same general shoot has been stoped to a width of 20 feet and for a length of over 100 feet. The ore from this stope was sorted to a shipping grade of $100 a ton, the second-class material being piled in the stope. A winze, shown in Plate XXXIII, had been sunk on this ore for a distance of 170 feet at the time of visit and showed an average value of about $55 a ton. Too little work had been done on the 600-foot level in 1908 to determine the size of the shoot at that depth. Where opened, however, the ore body showed a width of 33 feet of $50 to $60 ore with considerable lower-grade material on each side. Much of the ore now separating these irregular stopes will undoubtedly be mined in the future and the general continuity of the whole shoot thus becomes more apparent. Probably also enlargement of the stope will con- nect this shoot with the one that was stoped from the 350-foot level east of the main shaft and that has been profitably mined through the Mohawk-Jumbo lease shaft on the Gold Wed"-e claim. Above the 350-foot level this stope is in places fully 50 feet wide. The usual width (per- pendicular to the walls, which dip at about 35° E.) is from 6 to 10 feet. As shown in Plate XXXIII, an extensive body of ore was worked by lessees through the Sheets-Ish and Kalfus shafts. This ore came nearly to the surface, and was worked to a vertical depth of about 240 feet. The maximum stope length is about 250 feet. Good ore is known below the lessees stopes, but the relation of this ore shoot to the shoots opened in the main Mohawk workings remains to be discovered. In some parts of the mine the ore ends abruptly against fissures carrying gouge. These appear to be minor faults, and probably in most cases correspond pretty closely to what was originally the boundary of the ore. No persistent faults of large throw have been recognized nor does it appear that any large body of ore has been seriously displaced by faulting. The Mohawk has produced very little oxidized ore, and the sulphide ore differs in character from that known in the district prior to the discovery of the. Hayes-Monnette ore body. Much of the ore from this lease, even when of high grade, consisted of sheeted alunitized dacite, which to the eye showed little evidence of its value. Some of the richest material, however, contained fragments of dacite encrusted with marcasite and a dark-gray homogeneous mineral. These shells, which are up to a quarter of an inch in thickness, contain tellurium and gold, and the dark mineral has commonly been referred to as a telluride. It is chiefly goldfieldite, with some included gold, as is shown on page 116. Visible native gold, bismuthinite, and famatinite have not been found as abundantly in the Mohawk ore as in that of the mines farther south. COMBINATION MINE. HISTORY AND PRODUCTION. Many of the following facts with reference to the early history of the mine are taken from an article by Edgar A. Collins,0 formerly superintendent of the property. The Combination ledge, which outcrops about two-thirds of a mile northeast of the center of Goldfield, was located on May 24, 1903, by A. D. Myers and R. C. Hart, the latter soon selling out to T. D. Murphy. In October of the same year four full claims (Combination Nos. 1, 2, and 3, and Hazel Queen) and three fractional claims on or near the original ledge, with six additional claims (Golconda, Wonder, Mammoth, Goldstone, Red Boy, and Victor) lying a short distance southeast of the main group, comprising in all about 175 acres, were bonded for Boston and Chicago capitalists who organized the Combination Mines Company. The capital stock issued amounted to $320,000 out of a total capitalization of $400,000. The bond was for $75,000, $5,000 being paid in cash, the balance distributed over a period of twelve months. The lessees a The Combination mine: Min. and Sri. Press, vol.95, 1907, p. 397 79145— No. 60—09 14 210 THE GEOLOGY AMD ORE DEPOSITS OF GOLDFIELD, NEVADA. had the privilege of working the property, paying a royalty of 25 per cent of the net value of the ore, with the understanding that such royalty was to apply on the purchase price. These terms show how little suspected at that time was the remarkable richness of the Goldfield bonanzas. The workings when the company took the property consisted of a shallow open cut and a tunnel some 50 feet in length, which crosscut the ledge about 30 feet below its croppings. This exposed about 30 feet of ore, of which 10 feet averaged $150 to the ton and the remainder $20 to the ton. There were also some shallow pits which showed ore ranging up to $10 a ton in value. Shipments began in November, 1903, the first car averaging $160 per ton — the lowest in grade that was ever sent out, according to Mr. Collins. The average gross value of the ore shipped up to May, 1905, when milling began, was $404 per ton. The ore was at first hauled by wagons to Candelaria, 65 miles away, at a cost of $12.50 per ton. With extension of the rail- road to Tonopah in 1904 the wagon haul was shortened to 30 miles. Owing to the excessive freight charges, however, on ore assaying over $300 per ton, the richest ore was sacked and stored, pending the completion of a mill. In May, 1905, the company had completed a 10-stamp mill and had installed a pumping plant and pipe line capable of supplying 75,000 gallons per twenty-four hours. The source is Alkali Spring, 10 miles to the northwest. Upon the completion of the mill some of the rich ore, carrying 48 to 55 ounces of gold to the ton, was milled, about 62 per cent of the gold amalgamated, and the tailings sacked and shipped to the smelter. This process was regarded as safer and more economical than shipping the original ore under the sliding scale of freight charges then in force. By October, 1904, the mine had much more than paid for itself, and the first dividend, $40,000, was declared. By the end of the year, according to the first annual report of the company, 1,166 tons of ore had been shipped, with an average value of $419 per ton, or a total gross value of $489,209. The cost of shipment and treatment averaged $57 per ton, leaving the net value of the ore $362 per ton. The average contents of this ore were 20.22 ounces of gold and 2.68 ounces of silver per ton. By the end of 1905 the mine had produced ore to the gross value of $1,250,000, and had paid about half a million in dividends. In 1905 the mill was enlarged to 20 stamps and electric power substituted for steam. Tube mills were also added early in the following year. By the end of 1904 the Combination mine was about 300 feet deep, with 5 levels. The water was subsequently allowed to rise above the bottom level and attention was confined to the development and extraction of rich ore bodies nearer the surface. In the latter part of 1906 the Combination mine was consolidated with the Red Top, Jumbo, Mohawk, January, and other mines in the Goldfield Consolidated Mines Company. UNDERGROUND WORKINGS. The Combination mine is worked through a vertical shaft with 6 main levels at depths of 80, 130, 180, 230, 280, and 380 feet. The assembled levels are shown in plan in Plate XXXIV, and their vertical distribution is illustrated in Plate XVII. The 130-foot level is the most extensive, connecting on the northwest with the workings of the January mine and on the southeast with those of the Reilly shaft in the No. 1 lease block of the Florence ground. Up to the end of 1905 the Combination was operated through a crooked inclined shaft which fol- lowed the ledge down to the 230-foot level, all hoisting being done with a bucket. A vertical shaft, with a counterbalanced cage operated by electric power, was completed in the early part of 1906 and has since been enlarged to 2 hoisting compartments. The small rectangular areas shown in Plate XXXIV, at the northwest corner of the Florence claim, call for a word of explanation. In 1906 a legal contest was imminent between the Combination and Florence companies over the question of the ownership of certain ore stoped by the Reilly lessees. The dispute was finally compromised by the Florence transferring to the Combination a small block of unstoped ground from the Florence claim while the Combination Mines Company deeded to the Florence-Goldfield Mining Company the block from which most of the ore in dispute had been taken. These blocks are bounded by A'ertical planes. US GEOLOGICAL SURVEY PROFESSIONAL PAPER 66 PLATE XXXIV PLAN OF THE COMBINATION MINE AND THE PRODUCTIVE PART OF THE JANUARY MINE 210 had t1 ore, w show tunne expos the t( c k grade shipp wago road freigl store* plant Alka the t ship] shipi $40,( com] gross the of g( the { Tub. watt to tl Jum of 8t and extt soul to t low. sha) of 1 clai Coi by Coi Mil of 1 MINES OF THE GOLDFIELD CONSOLIDATED MINES COMPANY. 211 GEOLOGIC RELATIONS. The general geology of the mine is simple. The 80-foot and 130-foot levels are entirely in dacite. In the early days of mining the ledge matter produced by the alteration of this rock was often called rhyolite. Latite appears first on the 180-foot level (see PL XVIII), and as the contact dips to the east more and more of this rock is exposed on successively lower levels. The details of this contact are not well known. The dip varies from place to place. On the line of section D-D' (PL XVII) the average dip is probably not over 30° and on the 380-foot level is not over 15°. Farther southeast the dip increases, as shown in the sections of Plate XVII, which, it should be borne in mind, are not at right angles to the general strike of the contact. Where the rocks at the contact are soft some slipping has as a rule taken place. Where, however, an ore body lies at the contact the latter is close and irreg- ular. Although its original character is largely oblit- erated by the mineralization the contact at such places (for example, stope No. 316 on the 280-foot level) suggests igneous intrusion. Some faulting has probably taken place since the ore bodies were formed, but, as in the Mohawk, seams of soft gouge occur at so many places that it is impos- sible, without undertaking special development work for the purpose, to trace any given seam through from level to level. No evidence is vet available that indicates any extensive displacement of the ore bodies. FORM AND DISTRIBUTION OF THE LEDGES. The Combination claims were located on one of the rusty siliceous ledges common in the district, the actual pay shoots or ore bodies, as subsequently found, constituting portions only of the ledge matter. In the following pages the ledges will first be de- scribed and then attention will be directed to their inclosed or associated pay shoots. As exposed at the surface the main ledge appears to have a simple linear character and to trend N. 50° W. It can be traced for a distance of about 1,000 feet, the Combination shaft being nearly in the middle of the line of outcrop. To the northwest the ledge has not been followed beyond its junction with the curved January ledge. To the southeast it be- comes indistinct near the Reilly shaft, although the ledge appears to lie in the same zone of Assuring that is conspicuous in the Florence mine, southeast of the Reilly shaft. The underground workings of the Combination mine show two ledges, between which no direct connection has yet been established. These are best displayed in the plan of the 130- foot level. (See PL XVIII.) On this level the main ledge has been developed from a point about 150 feet northwest of the shaft southeastward into the Reilly workings. When the mine was first studied in 1905 this main ledge was not known to be continuous underground, the 212 THE GEOLOGY AND ORE DEPOSITS OF GOLDFIELD, NEVADA. conditions then obtaining being illustrated in figure 23, taken from the preliminary report. Since that time large stopes have been opened in the ground between what were then known as the Combination shoot and the No. 2 shoot (see fig. 23) and the continuity of the main ledge established, as shown in Plate XVIII. The northwest part of the 130-foot level goes through about 200 feet of generally soft altered dacite into the January ledge, which has not yet proved very productive within the Combination mine. This ledge, as is shown on page 127 and in Plate XXXIV, curves in the January claim so that the southeast end of the January workings is in line with the main Com- bination ledge as developed on the 130-foot level. The intervening ground has not been explored, and it is possible that the Combination and January ledges may yet be found united. If so, the ledge as a whole on the 130-foot level has the remarkable plan shown in figure 24. Below the 130-foot level the Combination workings do not reach the January ledge, nor do they as yet satisfactorily reveal the outlines of the Combination ledge. So far as possible these outlines are approximately shown in Plate XVIII. The Combination ledge as a whole dips to the east, but as may be seen from the sections of Plate XVII the mass is exceedingly irregular. The general dip to a depth of about 250 feet Figure 24.— Diagram showing possible plan of the combined January and Combination ledges. is from 60° to 70°. Below this, near the contact of the dacite with the latite, the dip decreases and the ledge shows a tendency to flatten toward the east. Very little is known of the hanging- wall side of the ledge matter on the lower levels. The boundary between ledge matter and dacite or latite is in some places a gouge seam or fault. The hanging wall of, the ledge on the 130-foot level is in general well defined by a seam of tough leathery gouge up to an inch in thickness.- This seam is particularly distinct in the vicinity of the Reilly workings. In some places it contains well-formed crystals of gypsum which must have crowded aside the tenacious clay to make room for themselves. In many parts of the lower workings there is a gradual change from ledge matter to country rock. An attempt has been made to indicate such a transition in the sections of Plate XVII. As in the Mohawk mine, the shape of the ledge has probably been somewhat modified by faulting, but the data for discriminating such modification from the great initial irregularity of the mass are not available. There is a suggestion that some of the irregularity of the ledge between the 180-foot and 280-foot levels (see PI. XVII, sections E-E', F-F', and G-G') may be due to fault- ing nearly parallel with the contact. MINES OF THE GOLDFIELD CONSOLIDATED MINES COMPANY. 213 MATERIAL OF THE LEDGES. The typical ledge matter of the upper levels is a loose porous mass of rusty angular frag- ments of altered dacite. There are all gradations, from material which is merely traversed in all directions by cracks to loose rubble-like masses with many open interstices between the fragments. The interstices are often partly filled and the fragments coated with yellow or brown ocher, sometimes associated with much kaolinite. The fragments themselves, when broken, prove to be hard masses of gray porous quartz of generally flinty texture, but showing, in spite of intense alteration, the original quartz phenocrysts of the dacite. The pores are in part irregular in shape, but in part they represent spaces left by the removal of the feldspars and of pyrite. They are usually lined with small quartz crystals, and when the rock is broken open are found to contain water, even in dry parts of the mine. The pyrite in these fragments is seldom completely oxidized, small disseminated crystals being abundant in the denser por- tions of the flinty quartz. Small pearly scales of bismite are associated with the ocherous limonite in some parts of the ledges, particularly in the January ledge and in the southeastern part of the Combination ledge. While often associated with rich ore the bismite also occurs in ledge matter of no value. Below the zone of oxidation in the Combination the marked distinction between ledge matter and the alunitized and pyritized dacite vanishes. The contrast in color between the rusty ledge matter and the unoxidized country rock in the upper levels of course disappears in the sulphide zone, but more is involved than mere loss of color distinction. In the lower levels the sulphides are associated with much alunite, and the ore and ledge matter is in many places apparently less siliceous and softer than in the oxidized zone. Whether, however, there is really less silica in a cubic meter of this softer unoxidized material than in the harder but much more porous ledge matter of the upper levels is a nice question and one not to be answered off- hand. In other words, it is doubtful whether or not the unoxidized ledge matter which grades insensibly into the country rock in the deeper levels could be converted by the mere removal of some constituents into a mass as hard and siliceous as the ledge matter of the oxidized zone. The pyritized dacite, even when close to rich ore, carries very little gold, assays of such material seldom giving over 40 to 50 cents to the ton. The disseminated pyrite is clearly very slightly auriferous. FORM AND DISTRIBUTION OF THE PAY SHOOTS. The pay shoots in the Combination mine are such portions of the ledges as contain enough gold and silver to be classed as ore. As a rule, it requires a trained eye to distinguish ore from barren ledge matter, and some ore is recognizable as such only by panning or assaying. There is no real boundary as a rule between ore and mere ledge matter. Under these circumstances it is a difficult matter to describe the form of the ore bodies, inasmuch as this varies from time to time. Originally only the rich streaks of ore were stoped, but afterwards, as improved milling facilities rendered possible the treatment of lower grade material, these stopes were greatly enlarged. Descriptions of ore shoots based upon the stoping down prior to 1906 are not applicable to present conditions. Detailed descriptions of form sug- gested by existing stopes would likewise be of little value a few years hence. In Plate XVIII, showing the plans of the levels, an attempt has been made to illustrate some of the changes made in the apparent shapes and sizes of the pay shoots in the course of development. The illustration shows the streaks of rich shipping ore known in 1905, the approximate outlines of the stopes at the end of that year, and the present stopes. From this plate and the sections of Plate XVII, the reader may gain a better idea of the irregular shapes and distribution of the ore bodies than can be given by words. He should bear in mind the gradation of ore into ledge matter and the probability that in a few years many stopes now separate will coalesce. The original Combination pay shoot came to the surface near the old inclined shaft and according to Mr. Collins had a stope length of 120 feet and a width of from 30 to 50 feet. This 214 THE GEOLOGY AND OEE DEPOSITS OF GOLDFIELD, NEVADA. has been mostly stoped, leaving an open pit or "glory hole'' (PI. XXII, A), which is being steadily enlarged. Probably a large part of the ledge matter exposed on the present 80-foot level will finally go through the mill. On the 130-foot level the best ore near the shaft in 1905 occurred on short, nearly north- south fissure zones which cross the general trend of the ledge. The very richest portions, although irregular, showed a tendency to form vertical pipes or "chimneys." The first pay shoot discovered in the southeast part of the mine in what was known in 1905 as the No. 2 ledge (see fig. 23), was found in the No. 3 shaft, which goes down in the foot- wall side of the ledge. This little shoot was elliptical in plan and was practically confined to the shaft. It pinched at 30 feet in depth. The ore was not particularly rich at the surface, but at a depth of 15 feet ore was found which in places carried 150 ounces of gold to the ton. In all, this small shoot of oxidized ore produced about $65,000. When the ore gave out in this shaft, a crosscut was run to the hanging wall of the No. 2 ledge, and this opened up the main No. 2 pay shoot. This, as worked on the 130-foot level in 1905, was a fairly regular streak of oxidized ore lying within the ledge matter, but close to its hanging wall, which dips at angles ranging from 60° to 75° NE. The ore had a maximum width of about 6 feet, but it passed with no plane of separation into ledge matter, and the width of ore stoped was determined solely by the conditions of economic mining at that time. This pay shoot had been stoped at the time of first visit to a length of about 300 feet. It is not actually continuous with the Reilly shoot, but the two are connected by a distinct zone of Assuring. Since 1905, as shown in Plates XVII and XVIII, stopes have been opened along the foot-wall side of the ledge in this part of the mine and have in places been carried across the full width of the ledge. They have also been carried northwest until they are almost con- tinuous with the stopes north of the shaft, on what was formerly supposed to be a distinct pay shoot. (See fig. 23.) Comparison of Plates XVII and XVIII brings out some interesting features regarding the behavior of the pay shoots with increase in depth. It appears that the ore bodies are fully as erratic in a vertical direction as they are in horizontal directions. The large ore body, for example, on the 130-foot level, cut by sections B-B', D-D', and E-E', does not extend in full strength to the 180-foot level, and on the 230-foot level is unknown. While good ore has been stoped from the 280-foot level, the value of the ledge below this, where it flattens with the dacite-latite contact, has not yet been determined. Although some good ore in latite has been opened on the 380-foot level east of the shaft, the extent of the body had not been ascertained at the time of visit in 1908. CHARACTER OF ORE. The ore of the Combination mine includes oxidized and unoxidized varieties. The typical rich sulphide ore is a rather loose mass in which the fragments consist of altered dacite and are surrounded by thin shells of gold and sulphides. These fragments vary greatly in size and shape. Most of them, however, are probably less than 6 inches in diameter. Many are much smaller, and having been rounded by chemical action give the ore a decided nodular appearance. The dacite of these fragments, some of which show signs of an earlier period of brecciation and cementation, exhibits various stages of alteration. Some of it is changed to a dense flinty quartz with irregular drusy pores. Other fragments, and these are apparently the more numerous, contain much alunite with the quartz, the alunite appearing partly as soft white pseudomorphs after feldspars. Minute crystals of pyrite are nearly everywhere abundantly disseminated through this altered dacite, but they certainly do not carry more than a very small part of the gold in the ore. The outer, highly mineralized crust of these fragments varies from a few millimeters to a centimeter in thickness. The metallic minerals are not everywhere arranged in precisely the same sequence nor developed in the same relative abundance. In what may be regarded as typical rich ore, however, the inner layer of the auriferous envelope is a somewhat indefinite dull MINES OF THE GOLDFIELD CONSOLIDATED MINES COMPANY. 215 yellow band which close examination shows to consist of fine particles of gold embedded in quartz. In the richest specimens this band may be as much as 5 millimeters in width. A section of these bands as seen under the microscope is shown in Plate XXVI, A. As seen in hand specimens of ore, there is no definite boundary between the auriferous band and the kernel of altered dacite. It appears, in fact, as if the gold had penetrated the substance of the rock and crystallized metasomatically at the expense of some of the rock constituents. The microscope shows, however, that there is a distinct surface of. demarcation between the golden envelope and the dacitic kernel. The kernel contains disseminated pyrite, while the auriferous band is usually free from this mineral, the irregular hackly particles of gold being intimately associated with famatinite and bismuthinite. The microscope shows also that the gold and associated metallic minerals are embedded in an exceedingly fine-grained aggregate of quartz with a little kaolinite, the aggregate beuig noticeably finer grained than that resulting from the alteration of the dacite in the kernel. It is also free from quartz phenocrysts, as far as seen. The minute quartz granules of this aggregate exhibit shadowy, wavy extinction, sug- gestive of an extremely fine fibrous or chalcedonic structure. The contact between this aurifer- ous envelope and the material of the kernel, which is still recognizable as altered dacite, while definite, is ragged in detail and is not such as would result from the mere accretion of material upon a smoothly rounded surface. Nevertheless, the form of the fragments shows that some preliminary rounding did take place, this being effected by attrition probably aided by solution. Subsequently the auriferous envelope was deposited, neither by direct accretion nor by partial penetration and metasomatism, but by a narrowly confined process which appears to have involved complete recrystallization of a thin peripheral part of each fragment with the introduc- tion of much gold and probably the removal of some constituents originally present. The extreme fineness of grain of the quartz which constitutes the immediate matrix of the gold indicates that the auriferous solution was a poor solvent for silica. Whether the alteration of the dacite kernel, with the development within it of alunite, took place while the fragments were receiving their initial rounding, or while the gold was being deposited, is in most cases an indeter- minate question. As will presently appear, this alteration may have been taking place during both periods and may have continued to a later stage of ore deposition. Outside of the envelope of native gold there is, on most fragments, a layer of famatinite. This varies much in thickness, and where it is not present its place is taken by pyrite or marca- site. The latter two minerals are not always readily distinguishable, as pyrite frequently occurs in radial crusts such as are characteristic of marcasite. Where the crystal form is not sufficiently well developed to serve as a means of distinction, the tendency of marcasite to dis- integrate after specimens have been kept for a few months may be utilized. Such specimens show an efflorescence of sulphur, and the sulphuric acid formed attacks the paper label or tray upon which the material may be resting. The iron sulphides in some cases coat the famatinite directly; in others they rest upon an intervening crust of drusy quartz. In Plate XXIII, A, is illustrated some very rich ore from the 230-foot level. In this the band of gold is from 2 to 4 millimeters in diameter. The fragment which it incrusts is clearly itself a breccia and must have been cemented into a firm rock again prior to the deposition of the gold. The microscope shows this older breccia to be now an aggregate of fine crystalline quartz, with pyrite and kaolinite. Alunite does not happen to be present in any considerable quantity in this specimen. The interstices between the larger fragments such as have been described are usually filled with smaller, less distinct fragments, similarly incrusted, with bunches of famatinite and with much alunite. Some kaolinite may be mixed with the alunite, and both minerals generally contain embedded crystals of pyrite. Such pyrite crystals often exhibit the common pyrito- hedral habit, but in many specimens they are all octahedral. Films of drusy quartz are not uncommon in the ore, but nowhere in the mine were any quartz crystals seen of sufficient size to permit recognition of their crystal planes without a lens. Solid masses of vein quartz are entirely absent. 216 THE GEOLOGY AND OEE DEPOSITS OF GOLDFIELD, NEVADA. Ore of the kind described has in some places been subjected to later crushing and breccia- tion. Such material often shows dark, soft streaks of obscure sulphides, and some of it is rich in gold. By way of summary, it may be said that the unoxidized ore of the Combination mine shows at least three stages of chemical and physical activity. These are as follows: (1) Breccia- tion of the dacite and cementation by fine crystalline quartz apparently formed by recrystalli- zation of the silica in the rock. How much of the pyritization and alunitization of the rock belongs to this period is difficult to say. (2) Rebrecciation, rounding of fragments by attrition and solution, and deposition of gold, famatinite, and bismuthinite, associated with pyrite, marcasite, alunite, kaolinite, quartz, a little telluride of gold, and some silver. (3) Later crushing along fissure zones and some secondary concentration of the gold, probably by descend- ing waters. There is no evidence that the first stage contributed any valuable constituent to the deposit. The gold, silver, bismuth, copper, tellurium, etc., appear to have been introduced in the second stage of the process. With the exception of the small shoot of oxidized ore found in the No. 3 shaft, the richest ore in the mine has been the first hundred feet of the unoxidized ore in the original No. 1 shoot, near the main shaft. While it was known in 1905 that the unoxidized ore of the Combination contains some tellurium, no mineral recognizable as a telluride had been detected. Since then rich telluride ore, closely resembling that of the Mohawk mine, has been found in stope No. 316, above the 280-foot level, about 150 feet east of the shaft. 'This ore occurs partly in latite. The oxidized ore, as already mentioned, is not readily distinguished from ordinary oxidized ledge matter. The gold is visible at some places, but at more it is masked by yellow ocherous limonite from the decomposition of pyrite or marcasite. Kaolinite is rather abundant in the oxidized ore, while alunite is rare. The hydrous copper carbonates are rarely seen in the thoroughly oxidized ore, although they occur in small quantities in the zone of partial oxida- tion. Alum, gypsum, and melanterite (ferrous sulphate), the latter sometimes mixed with a little chalcanthite, occur usually in seams or as efflorescent coatings in or just below the oxidized zone. The change from oxidized to sulphide ore in the Combination mine takes place at a depth of about 140 feet. UNDERGROUND WATER. Water was reached in the Combination mine at approximately the 130-foot level. In 1905 from 1,500 to 2,000 gallons were hoisted daily to keep the water below the 230-foot level, and when the 280-foot level was open the quantity raised was greater. In 1908 the mine was making practically no water, being drained by deeper adjacent workings. JANUARY MINE. HISTORY. Prior to its absorption by the Goldfield Consolidated Mines Company, the January mine was owned by the Goldfield Mining Company, their holdings comprising, in addition to the January and February claims just west of the Combination ground, 5 claims in other parts of the district. At the beginning of the year 1904, a lease on the January claim was granted for one year to L. L. Patrick and others, who within a month began to make snipments. The lease is reported to have produced 1,000 tons of high-grade ore, yielding $199,489 and $286,000 worth of ore, ranging from $30 to $100 per ton. In January, 1905, the company began to operate the property themselves, with notable success. In 1906 the mine was merged with the Mohawk, Combination, Jumbo, and Red Top. The present owners were not operating the January in 1908 and had abandoned the old shaft. Future work will be from the Combination shaft. MINES OF THE GOLDFIELD CONSOLIDATED MINES COMPANY. 217 UNDERGROUND WORKINGS. The January mine was worked through a vertical shaft about 300 feet deep, connecting with six rather irregularly spaced levels, as shown in Plate XVI. The general plan of these levels is crescentic, with the concave side to the east. The workings are remarkably compact and all the ore thus far mined lies within the space between the outer curve of the crescent and the chord formed by the east side line of the January claim. Some of the ore bodies, however, undoubtedly extend eastward into the Combination claims. Since the mine was studied the 110-foot, 232-foot and 283-foot levels have been extended as shown in Plate XXXrV, but these later workings could not be seen in 1908. The following description relates to the mine as it was when in active operation at the end of 1905: GEOLOGIC RELATIONS. The main workings of the January mine are in the same dacite that forms the country rock of the Combination mine. At the 283-foot level, however, the shaft cuts a fissure filled with soft crushed rock. Owing to the softness of the ground shaft and drift had to be closely lagged, and the fissure was not well exposed at the time of visit. It apparently dips steeply northeast and separates dacite on that side from latite on the southwest. Both rocks, par- ticularly the dacite, show great disturbance in the vicinity of the fissure and are thoroughly altered, containing abundant alunite and disseminated pyrite. FORM OF THE LEDGE. The January ledge is one of the most remarkable that have been exploited in the district. Its peculiar form can best be understood by reference to Plate XVI. In the first three levels the ledge curves from a course of about N. 70° W. to one bearing N. 55° E. It thus turns through an angle of about 125°, the shaft being situated at the elbow. So decided a change in strike suggests that the ledge may be due to the intersection of two distinct zones of Assuring. This, however, is not the case. The outer curve of the ledge is smooth and regular and the distinction between ledge and country rock, particularly on the upper levels, is sharp. That the country rock which bounds the ledge on the northwest, west, and southwest should be entirely free from Assuring is of course not to be expected. Such fractures as occur, however, are small and have rather the character of irregular jointing than of fissure zones which could be taken as the straight continuation of either limb of the crescentic ledge through and beyond the bend at the shaft. In fact the minor Assuring observable in the dacite at the shaft appears in most instances to be tangent to the bold sweep of the ledge, and the smooth outline of the curve as visible in the empty stopes of this part of the mine affords no suggestion of any break in the dacite wall such as would be expected were the turn in the ledge the result of the intersection of two rectilinear fissure zones. As the general map of the workings shows, the part of the ledge northeast of the shaft dips to the northwest, the angle of dip becoming lower as the ledge is followed northeast. The ledge south of the shaft, on the other hand, dips to the northeast. In other words, each succes- sively lower level shows a slight rotation, in a direction contrary to the hands of a watch, about the shaft as a vertical axis. Moreover, below the 109-foot level the whole ledge pitches to the east, as shown by the increasing length of the crosscuts from the shaft in Plate XVI. On the 232-foot and 283-foot levels the ledge is apparently becoming more nearly rectilinear in strike. It thus appears that the January ledge, even when stripped of minor complexities of form, is by no means simple in shape. The minor complexities referred to arise from the variations in width of the ledge and the irregular projections of ledge matter into the country rock on its concave side. These latter are so abundant and so irregular that any section such as that shown in Plate XVI is necessarily diagrammatic, the mine levels, close as they are, being too far apart to reveal every detail of structure. 218 THE GEOLOGY AND ORE DEPOSITS OF GOLDFIELD, NEVADA. In general, the distinction between siliceous ledge matter and the soft alunitized and pyri- tized country rock is fairly sharp in the January mine. In the oxidized zone, especially, the contact is almost a geometric surface. There is very little evidence of movement, however, between ledge matter and country rock, and there is seldom any gouge to mark the plane of division. Small streaks or lenses of ledge matter, apparently not connected with the main ledge, have been found in crosscuts west of the shaft. That on the 283-foot level is a lodelike mass in latite. MATERIAL OF THE LEDGE. The material of the oxidized portion of the ledge is of the same general character as that described in the Combination mine. Below the oxidized zone the ledge matter is perhaps a little more readily distinguished from the ordinary country rock than in the Combination mine, the ledge being, as a rule, harder and apparently more siliceous than the country rock. Miner- alogically, however, there is little difference between the two forms of altered dacite. Both are chiefly quartz and alunite with more or less pyrite. The ledge usually shows more Assuring and brecciation and contains small quartz-lined fissures or cavities. In some places on the bottom level (283-foot) of the January the ledge is a sheeted zone, showing tiny vuggy veinlets of quartz between slabs of dacite in which the feldspars are altered to faint-pink aggregates of alunite. The pyrite in such ledge matter may be no more abundant than in the softer country rock through which it is universally disseminated. Much of the alteration to ledge matter, on the lower levels, has been clearly facilitated by close sheeting of the rock, the fissures being usually less than an eighth of an inch in width. They can in places be seen crossing alunite pseudomorphs after feldspar without perceptibly faulting them. In other places the dacite has been shattered to fragments. The feldspars in these fragments have been changed to alunite and the latter mineral is in places very abundant as an interstitial filling between the fragments. In addition to their internal alteration the fragments in some places show peripheral layers or crusts of quartz, alunite, and sulphides. These are not all mere incrustations. Some frag- ments have been rounded, apparently by chemical action, and have a whitish outer layer which the microscope shows to be a very fine-grained aggregate of quartz and alunite. This differs from the quartz-alunite aggregate of the central part of the fragment in being of finer and more even grain and in retaining no trace of the dacitic texture. It is apparently a secondary crys- tallization of the already altered rock, in the course of which even the quartz phenocrysts are attacked and merged into the fine resulting aggregate. Other fragments, of more or less rounded outline, are encrusted by a thin dark layer of pyrite (with perhaps other sulphides). This is coated with a crust of drusy quartz and this in turn covered by and the whole nodule embedded in soft pulverulent alunite, which in places carries crystals of pyrite. Such material resembles some of the rich ore in the Combination mine, but where studied in the north drift of the 230-foot level of the January mine the material is of little value. As in the Combination mine, there is a noteworthy absence of any quartz crystals large enough to allow the recognition of distinct crystal planes with the naked eye. Whatever processes may have been at work in the formation of the ledge matter, their capacity for dissolving silica and transporting it to places where crystals of some size might develop was exceedingly slight. FORM AND DISTRIBUTION OF THE ORE BODIES. Probably a better idea can be obtained of the distribution and form of the January pay shoots from Plate XVI than from any verbal description. They differ from the rest of the ledge matter in no essential respect save that of richness, and as a rule are without definite boundaries. On the first three levels there is a fairly regular curved pay shoot which conforms to the general curvature of the convex side of the ledge. Except for the curved strike this pay shoot has a lodelike form, and in the part of the mine northeast of the shaft has been stoped to a maximum width of about 15 feet. Just above the 160-foot level this pay shoot dies out. MINES OF THE GOLDFIELD CONSOLIDATED MINES COMPANY. 219 There is a similar shoot of sulphide ore, however, on the 232-foot and 283-foot levels, but it has not yet been opened to as great a length as in the oxidized zone. In addition to these pay shoots which follow the outer curve of the ledge, there are a number of smaller, irregular shoots distributed with little uniformity through the inner or concave part of the ledge. These are irregular bunches of ore which trend in various directions and rarely extend continuously from one level to another. It is noteworthy that the poorest level in the mine, the 160-foot, is the one nearest the original water level. No ore bodies are known on this level. CHARACTER OF THE ORE. The oxidized ore is of the same general type as that described in the Combination mine. The oxide of bismuth, bismite, is rather abundant in the oxidized zone of the January, and usually accompanies ore of high grade. It is present, however, on the barren 160-foot level. The bismite occurs in some places as minute pearly scales in loose limonitic material, but in some varieties of the ore is clearly pseudomorphous after the needles of bismuthinite, from which it has been derived by oxidation. The typical sulphide ore consists of highly siliceous altered dacite containing specks and irregular bunches of reddish-gray famatinite, accompanied by pyrite and needles of bismuth- inite, the latter being usually inclosed in the famatinite. In varieties of the ore pyrite is abundant. In others it is decidedly subordinate to the famatinite and bismuthinite. All three sulphides are so closely intergrown as a rule that it is almost impossible to effect a mechanical separation of them. In some places the sulphides and.minutely crystalline quartz form small veinlets, a section of one of these being figured in Plate XXIII, C. Such material seems to have resulted from the alteration and mineralization of crushed dacite rather than from the filling of an open crevice. The entire process of ore deposition illustrates very feeble capacity for the filling of open spaces, the ore containing many small cavities which have never been filled with either quartz or sul- phides. The altered dacite of the gangue shows original residual phenocrysts of quartz. The feld- spars are partly dissolved or obliterated, partly altered to pinkish-white aggregates of alunite. The material is porous, being full of small irregular vugs lined with quartz druses and in some instances filled with alunite. These pores usually contain water when the rock is freshly broken. Such ore evidently represents the alteration and mineralization of a shattered portion of the dacite. It is in some places traversed by seams of secondary crusliing, which carry streaks of soft dark sulphides of obscure and probably mixed character. Such seams are generally the best part of the ore, and indicate some enrichment subsequent to the deposition of the bulk of the ore. In another form of ore the dacite has been sheeted prior to mineralization, instead of being brecciated. Such ore as a rule contains less sulphides than the other kind and is probably never of so high a grade. The famatinite and bismuthinite particularly occur chiefly where the dacite has been thoroughly shattered, and experience has shown that the gold is associated with these two sulphides. The richest ore in the mine has been found in the oxidized zone. The original water level in the January was at a depth of 160 feet. This may have been lowered somewhat by previous work in the Combination mine. But even if some allowance be made for such artificial depres- sion, the fact remains that the poorest level in the mine is that nearest the old water surface. The best sulphide ore on the 283-foot level at the end of 1905 had a gross value of about $150 a ton, and the highest assays were obtained from soft dark streaks traversing the mass of the ore. 220 THE GEOLOGY AND ORE DEPOSITS OF GOLDFIELD, NEVADA. UNDERGROUND WATER. At the end of 1905 a small pump sufficed to keep the 283-foot level free from water. The only water actually observed flowing into the mine was a small stream at the north face of this level. A sample of mine water was analyzed in December, 1905, in the Dearborn laboratories, Chicago, by Edgar & Carr, chemists, for the purpose of testing its suitability for use in the steam boilers. The analysis is as follows: Analysis of vxiler from January mine. Grains per gallon. Silica 2. 990 Sulphates of iron and aluminum ( principally iron ) 80. 200 Carbonate of lime None Sulphate of lime 58. 455 Carbonate of magnesia None Sulphate of magnesia 22. 971 Sodium and potassium sulphates 72. 194 Sodium and potassium chlorides 11. 880 Loss, etc l. 145 Total soluble solids 249. 835 Suspended matter 41. 580 Free sulphuric acid Trace Total soluble incrusting solids 141 . 645 Total soluble nonincrusting solids 108. 190 Pounds soluble incrusting solids per 1,000 U. S. gallons 20. 23 Pounds soluble nonincrusting solids per 1,000 U. S. gallons 15. 45 The analysts remark that the water — contains a little less than 250 grains of solid matter in solution and a little over 41^ grains in suspension, per United States wine gallon of 231 cubic inches. It also contains a trace of sulphuric acid. Undoubtedly this water in its original condition carried a considerable quantity of free sulphuric acid, but due to the fact that sample was shipped in a can, it has been materially neutralized by the iron of the can itself, producing sulphate of iron, which accounts for the large amount of same above given." The analysis is accordingly very inaccurate and is of value only as affording some indication of the general character of the water. The sample analyzed was probably taken from the pump discharge and represents a mixture of the normal ground water of the district with solutions which have trickled down through the oxidizing ore. Much of the percolating water on the lower levels contains aluminous salts, as shown by its taste and by the deposition of halotrichite in efflorescent form on the walls of drifts. JUMBO MINE. HISTORY. The Jumbo mine lies just north of the Florence, the main Jumbo shaft being half a mile north of the Florence shaft and the same distance east of the Combination shaft. The holdings of the Jumbo Mining Company in 1905 comprised the Jumbo, Lucky Boy, Grizzly Bear, and Clermont claims, all forming a compact group. Practically all the development is on the Jumbo claim, which was located by C. D. Taylor on May 19, 1903. In the following October the property was bonded for $100,000, but crosscuts at a depth of 50 feet having failed to open up ore the bond was relinquished. In March, 1904, the Jumbo Mining Company was organized, and during the following spring leases were let to six or more different sets of lessees. Most of the lease blocks extended for 100 feet along the lode, although the northernmost, or Ridge- Curtis lease, was 300 feet in length. The lessees soon found ore and the ledge became an object of great activity, each block having its own shaft. The daily output from all leases in August, o Report to Goldfleld Mining Company. MINES OF THE GOLDFIELD CONSOLIDATED MINES COMPANY. 221 1904, was estimated at $10,000 a day.a The total gross production from these leases to their expiration early in 1905 was' approximately $1,100,000. The most productive single lease was the Bowes-Kernick, near the middle of the claim, which expired October 31, 1904, after a net production of $258,000. The royalty paid by the lessees to the company was 20 per cent of the gross output. Throughout the greater part of 1905 the Jumbo mine was involved in litigation and no ore was mined. In 1906 it was included in the consolidation with the Combination, January, Red Top, Mohawk, and other mines and is now the property of the Goldfield Consolidated Mines Company. Nothing has been done in the old workings since the consolidation and the shaft has been allowed partly to fill with water. It is the intention of the company to reach the ore body from the Mohawk and new Jumbo (Clermont) shafts. UNDERGROUND WORKINGS. As each lease block was worked through an independent shaft and as the levels were not run at uniform intervals and do not all connect with those of adjoining blocks, the under- ground workings of the Jumbo mine are in a rather chaotic condition. The section of ledge worked by the lessees is about 600 feet in length and their operations extended to a maximum depth of 250 feet. The deepest level in 1905 was the 250-foot level on the Bowes-Kernick lease, near the middle of the productive ledge. This connects with a vertical shaft sunk in the country rock just west of the ledge. After the expiration of the leases the company made this the main shaft, and by the end of 1905 had sunk it to a depth of 450 feet. The ledge, how- ever, had not then been crosscut below the 250-foot level. A general plan of the principal levels is shown in Plate IX. THE LEDGE. The Jumbo ledge, which so far as developed is entirely in dacite, outcrops prominently for a distance of about 700 feet. Its general course is about N. 16° W. Underground develop- ment shows it to be nearly vertical on the upper levels, although the east side is commonly called the hanging wall, and the 300-foot level, not accessible at the times of visit, indicates an eastward deflection of the ledge at that depth. The deposit is more regular and lodelike in form than most of those in the district, much of it being a distinct zone of parallel sheeting in the dacite, resembling some of the typical lode structure of Cripple Creek. The belt of regular sheeting is in most places from 4 to 6 feet wide, but the alteration and mineralization, as shown by stopes, may attain a width of fully 20 feet. Brecciation of the rock, so characteristic a feature of the Combination, January, and Florence ledges, is notably absent from the Jumbo. The sheeting, as at Cripple Creek, has been effected with very little slipping of one sheet of rock past another, and no gouge seams were noted in the workings accessible in 1905. The ledge has no true walls, the sheeted structure and the more intense alteration of the dacite which accompanies it grading into the usual softer country rock, which contains much alunite and disseminated pyrite. Within the ground opened by lessees the sheeting is more regular toward the north, the structure being excellently shown at the north face of the 200-foot level of the Fuller-Macdonald lease (PI. XX, B). In the Vermilyea and Zinn leases, to the south of the Bowes-Kernick lease, the lode divides into at least two branches, the sheeting is less regular, and at the south end of the Zinn workings the ledge becomes rather indistinct. In general, the distinction between ledge matter and country rock is less easily made in this mine than in most of those described, owing to the gradual passage of one into the other. THE PAY SHOOTS. Near the surface the Jumbo ledge proved almost continuously productive for a distance of 500 to 600 feet along the strike. The stopes ranged from 2 or 3 up to 20 feet in width. Too a Goldfield Sun, August 19, 1904. 222 THE GEOLOGY AND ORE DEPOSITS OF GOLDFIELD, NEVADA. little systematic work has yet been done to determine the limits of the pay shoot below the zone of oxidation, which extends to a depth of about 200 feet. A little stoping on sulphide ore has been done near the 250-foot level, but the ore apparently is not there of high grade. At the south end of the ledge the two main branches into which the ledge divides both carry ore. At the north end of the productive zone, in the Ridge-Curtis lease, about $200,000 worth of ore was stoped between the surface and the 50-foot level. Below that level no ore was found, although prospecting was carried to a depth of 200 feet. In the Bowes-Kernick lease, on the other hand, the stopes on the 150-foot level were carried the full length of the block, 100 feet. Below this they shorten and come to a point on the 250-foot level. CHARACTER OF ORE. The oxidation in the upper levels has followed the fissures of the sheeted zone. These, which are rarely more than a small fraction of an inch in width, are filled with rusty material consisting of limonite, kaolinite, gypsum, and probably some alunite. Oxidation has also extended from the fissures for varying distances into the intervening slabs or sheets of dacite, converting the disseminated pyrite into limonite. No gold was seen in the stopes at the time of visit, but it is said to have occurred mainly in the rusty seams of the sheeted zone. Below the zone of oxidation the fissures are lined with films of quartz, the middle part being empty or filled with alunite. Pyrite is apparently not abundant except as finely dissemi- nated crystals in the dacite. On the 200-foot level some of the seams carry famatinite. This, however, did not appear to be associated with much gold, an assay of a sample from the south face affording only 0.26 ounce of gold and 0.25 ounce of silver to the ton. The rock between the fissures is dacite which has been changed to an aggregate of quartz, alunite, and pyrite, the alunite chiefly pseudomorphous after feldspar. The original quartz phenocrysts of the dacite are the only constitutents not affected by this kind of alteration. This ledge rock differs from the general country rock in containing more quartz and consequently in being of superior hardness. Much of the ore shipped by lessees was of very high grade. One lot of 14 tons from the Bowes-Kernick lease netted $36,000, or $2,571 a ton. The smelter settlement on 14 sacks of ore shipped in November, 1904, from the Richard lease, which was immediately south of the Bowes- Kernick lease, was at the rate of $4,960 a ton. As shown on Plate IX, considerable exploration has been carried on by lessees on the 350- foot level of the Jumbo Ledge or Becker shaft, in an attempt to find a continuation of the rich ore formerly worked through the Zinn shaft. In 190S this level was mostly in soft disturbed dacite, containing some large irregular masses of ledge material but no visible ore. MINES AND PROSPECTS OPERATED BY LESSEES. INTRODUCTION. The principal mines operating in 1908 under leases from the Goldfield Consolidated Mines Company were the Five Friends and Hazel-Goldfield on the Laguna and Last Chance claims, the Mushett and Mohawk-Red Top on the Miss Jessie claim, and the Consolidated Red Top on the Red Top claim. All these are situated north of the Mohawk workings, as may be seen from Plate X. Southeast of the Combination mine shafts were being sunk by many groups of lessees. None of these shafts was in ore in 1908, and with the exception of the Rosebud none was con- nected with any extensive lateral development. Among them may be mentioned the Gotwaldt, Moore, Gibraltar, Stein, Mitchell-Fairfield, Rosebud, Black Eagle, Liverpool, Texas-Golconda, and Facer shafts. The positions of these leases are shown in Plate X. The Mushett and Consolidated Red Top leases were shipping ore in 1908. FIVE FRIENDS LEASE. The shaft of the Five Friends lease was 350 feet deep at the time of visit, but, as reported by Mr. H. P. Henderson, it had been deepened to 560 feet at the beginning of December, 1908. A plan of the levels is shown in figure 25. The country rock of the lease is dacite of the usual MINES OF THE GOLDFIELD CONSOLIDATED MINES COMPANY. 223 character. No ore has yet been found, although the north-south drifts on the 275-foot level follow a narrow seam which dips 30° to 40° E. and carries a little crumbling sphalerite and galena. MUSHETT LEASE. At the time of visiting the Mushett lease the principal level connected with the bottom of the 430-foot shaft. A plan of the workings is shown in figure 26. The 429-foot level at 350 -ft. level N. 50 I 100 200 FEET FIGURE 25. — Sketch plan of the workings of the Five Friends lease. the time of visit was wholly in dacite, which, near the ore body, shows the usual alunitic altera- tion. The main drift runs nearly north and south and follows a mineralized streak in the dacite, wluch at one place widens to a pipelike ore body. The narrower part of the mineralized streak is chiefly remarkable as carrying rather abundant sphalerite, a mineral which has hitherto been re- markably rare at Goldfield. A sample of this sphalerite assayed for the Goldfield Consolidated Mines Company gave 1 .8 ounces of gold and 7 ounces of silver per ton, with 55.6 per cent of zinc. The ore body, as shown in figure 26, dips from 25° to 35° E., and pitches north. Its stope length varies from 12 to 20 feet and the width from a few inches to 7 feet. The ore is of high grade, some assays showing a tenor of $8,000 a ton. Mineral- ogically the ore is unique in this district. It con- tains abundant sphalerite, pyrite, bismuthinite in crystals unusually large for this district, famatinite, and some telluride rich in gold. Alunite is abun- dant, both as a constituent of the altered dacite, as the filling of small fissures, and as a soft inter- stitial material in the ore. Further particulars of the Mushett ore are given on pages 165 and 170, and in the chapter on mineralogy under the various minerals mentioned above. Since the date of visit (July, 1908) the contact between the dacite and latite has been cut on the 429-foot level at a point about 160 feet west of the shaft. Both rocks are said to be altered to ledge matter near the contact. On the new 480-foot level the contact, according to a letter from Mr. H. P. Henderson, appears to be about 50 feet east of the shaft, and is in ledge zez-foot level so feet Figure 26.— Plan of the workings of the Mushett lease. 224 THE GEOLOGY AND ORE DEPOSITS OF GOLDFIELD, NEVADA. matter. These observations indicate a dip of about 15° E., and are of interest as showing the tendency of the ledge to flatten out and follow this contact for a way instead of continuing straight down into the latite. MOHAWK-RED TOP LEASE. The Mohawk-Red Top workings at the time of visit consisted of one level at the bottom of the 420-foot shaft. This level, shown in figure 27, is in latite, and the shaft is said to have passed out of dacite at a depth of about 365 feet. The latite shows considerable mineraliza- tion, being partly silicified and containing pyrite and alunite. It is traversed by many approxi- mately parallel fissures which strike generally north and dip at angles of 40° to 50° E. One such fissure followed in the eastward drift contains a little crumbling sphalerite and galena, which, although in a different rock, resembles the material in the Five Friends lease. CONSOLIDATED RED TOP LEASE. The Consolidated Red Top shaft is 300 feet deep, with levels at 200, 225, and 150 feet below the surface. There are also some short, abandoned upper levels driven by earlier lessees. The shaft is in dacite, which, near the bottom, is much crushed, having in part the con- sistency of gouge. This condition is due to movement along the Columbia Mountain fault, for the Cambrian shale appears on the 300-foot level just west of the shaft. The shale itself is greatly disturbed, and the level, which extends westward for about 30 feet, probably does not reach the foot wall of the fault zone. A drift has been run south along the fault and shows black shale and Kendall tuff, both much crushed and disturbed. No ore has been found on this level. On the 150-foot level a strong ledge is exposed. This strikes N. 20° W. and dips 40° to 50° E. It consists of the usual altered dacite, which, near the indefinite hang- ing wall, has a sheeted structure, while near the foot wall this grades into a brecciated rubble-like mass. The whole ledge on this level is about 80 feet wide, but like all similar deposits in Goldfield is irregular. Some traces of ore having been found on this level, the lessees started a new level at 225 feet, and in July, 1908, found a body of good ore about 100 feet east of the shaft. This ore, like that of the Mushett, contains much sphalerite, which forms friable crusts around fragments of silicified and alunitized dacite. Associated with the sphalerite are free gold, pyrite, famati- nite, galena, and probably some tellurium compounds. Some of this ore assayed in the latter part of 1908 gave 42.1 ounces of gold and 34.5 ounces of silver per ton, with 5 per cent of copper and 12.5 per cent of lead. This, it will be seen, is a remarkable ore for this district. HAZEL-GOLDFIELD LEASE. The Hazel-Goldfield lease on the Last Chance claim was not in ore at the time of visit, the shaft being then 415 feet deep. According to Mr. Henderson, the shaft was 740 feet deep on December 6, 1908, and passed into latite at 685 feet. He reports that the contact where cut in the shaft dips about 60° NW. This, as he remarks in his letter, is probably local and may be a minor fault plane. A new level at 718 feet is entirely in latite, much of which is ledge matter. Some good assays (from $200 to $300) have been obtained on this level, and at last report the lessees were shipping some ore. OTHER LEASES. The other leases on the Goldfield Consolidated Mines Company's ground call for no special description. Those which afford information on the geologic structure of the district are referred to in the appropriate places in Chapter VIII. Figure 27 -Sketch plan of the 420-foot level of the Mohawk-Red Top lease. CHAPTER XIX. DETAILED DESCRIPTION OF THE MINES OF THE FLORENCE-GOLDFIELD MINING COMPANY. INTRODUCTION. The principal mine of the Florence-Goldfield Mining Company is the Florence, situated just east of Goldfield on the north side of Florence Hill. The company owns the Florence, Red Iving, Cornishman, Firelight, and Emma claims, forming a compact group, as is shown in Plate XXXV. This ground as a whole has been very productive and is remarkable for the number of highly successful leases which have been taken upon various parts of it. The most notable of these were the Sweeney (in the Florence mine proper), Reilly, Little Florence, Flor- ence Annex, Rogers, and Engineers' leases. (See PI. XXXV.) The approximate gross pro- duction of these leases is as follows: Gross production of Florence leases. Sweeney and other early leasee $650, 000 Reilly 475, 000 Little Florence "1, 500, 000 Florence Annex 169, 000 Rogers 661, 000 Engineers' 1, 100, 000 4, 555, 000 For over a year practically no underground work has been done in the Florence mine. The company has been building a mill, laying a pipe line, and improving its surface equipment. In the meantime lessees have been taking out rich ore up to within 300 feet of the main shaft. FLORENCE MINE. HISTORY. The Florence claim was located on May 19, 1903, by Charles D. Taylor, but shortly after- ward passed into the control of T. G. Lockhart and A. D. Parker. As was the case with all of the important mines except the Combination, the first ore bodies were found and exploited by lessees. The most successful of these early leases was that granted to Sweeney, Nixon, Wing- field, and Hennessy, usually known as the "Sweeney lease." These lessees found little to encourage them and after exploring the ledge at a depth of 50 feet they relinquished the work to Durgan, Elkins, and others, but retained a half interest in the lease. Shortly afterward the 100-foot level opened up the south pay shoot and penetrated the top of what subsequently proved to be one of the largest single ore bodies yet worked in the district. Shipments began in the summer of 1904, and according to Mr. Frank Oliver, superintendent of the Florence mine, the total production from leases prior to January 15, 1905, when the company began to operate the mine, was $650,000. Some of the ore mined by the lessees was very rich, although far surpassed by later slupments from the Mohawk mine. One lot of 75,678 pounds, treated by the Western Ore Purchasing Company in August, 1904, had a value of $40,170.80, correspond- ing to about 53 ounces of gold per ton. Another lot of 1,855 pounds was valued at $7,350.45, equivalent to 396 ounces per ton. a This is merely a rough and conservative estimate from the known net production, which was $1,285,000. 79145— No. 66—09 15 225 226 THE GEOLOGY AND ORE DEPOSITS OF GOLDFIELD, NEVADA. The Florence-Goldfield Mining Company was capitalized at $1,250,000, and the total gross output of the mine up to the end of 1905 amounted to about $1,500,000. UNDERGROUND WORKINGS. At the end of 1905 the Florence mine was developed to a depth of 350 feet. It was worked through a vertical shaft with levels at 50, 100, 150, 200, 250, and 350 feet, and an intermediate level at 300 feet below the collar of the shaft. These levels have a general trend of about N. 15° W., but they are most of them exceedingly tortuous, as may be seen from Plate XXXV. They somewhat resemble the workings of the January mine in showing a sharp elbow-like curve on the upper levels, which becomes less pronounced with increasing depth. At the time of second visit, in 1908, the mine was idle. The 150-foot and 250-foot levels had been driven out to the Reilly shaft, but otherwise the workings were practically the same as in 1905. GEOLOGIC RELATIONS. The chief feature of geologic interest in the Florence mine is the contact between the dacite and the Milltown andesite. Most of the Florence workings are in dacite. On the other hand the Engineers', Little shaft Surface Florence, Rogers, and Rosebud workings are in andesite. At the surface the rather obscure contact appears to be about 250 feet north of the Florence shaft. The 50-foot level (a short one not shown in PI. XXXV) is probably entirely in Milltown an- desite, although the alter- ation of the rock leaves its original character uncer- tain. At the 100-foot level the shaft is still in an- desite. The dacite in the Florence mine, especially near the contact with the andesite, is usually finer grained and less porphyritic than elsewhere, quartz phenocrysts are less abundant and con- spicuous, and the two rocks in their altered condition may be exceedingly difficult to distinguish. For some distance north of the shaft on this level the character of the country rock is in doubt. Dacite certainly occurs on this level at a point 180 feet in a straight line northwest of the shaft. The rock south of this is believed to be mainly andesite, although it may contain some intruded tongues of dacite. On the 150-foot level the contact is just south of the shaft. It could not actually be recognized, but the shaft itself is certainly in dacite, and undoubted andesite occurs in the drift leading south from the station. On the 200-foot level the contact is obscured by mineralization, but appears to be less than 20 feet south of the shaft. On the 250-foot level the workings south of the shaft had caved in 1908, but observations made in 1905 showed that the south drift passes from. dacite across an obscure contact into rock which is certainly andesite. The 350-foot level examined in 1905 is probably nearly all in dacite, although some andesite may appear at the extreme south end. This part of the workings could not be seen in 1908. The facts available from the Florence mine indicate that the dacite ends against the andesite with an igneous contact, and that this contact, below the 150-foot level, as illustrated in Plate VIII, section G-G', and in figure 28, has a steep dip to the south. N.28"W. 100 200 FEET S.28°E. FlGUKE 28.— Diagrammatic section through the Florence mine showing the cross fault and the dacite- andesite contact. Plane of section passes 20 feet southwest of shaft. U S GEOLOGICAL SURVEY PROFESSIONAL PAPER 66 PLATE XXXV PLAN OF FLORENCE MINE, SHOWING ALSO SOME OF THE ADJACENT WORKINGS OF LESSEE COMPANIES MINES OF THE FLOBENCE-GOLDFIELD MINING COMPANY. 227 About 100 feet south of the shaft the 100-foot level passes through a seam of gouge which strikes N. 55° E. and dips southeast. This seam limits the main mass of ledge matter on this level, as shown in figure 13, and apparently fills a fault fissure. Similar seams are found at the southern ends of the 200-foot, 250-foot, and 350-foot levels, as illustrated in Plate XXXV. The strike and dip as observed at these various exposures vary, but when plotted in section, as in figure 28, the points of observation determine a line of slight curvature. This, without much doubt, corresponds to a single fault which in general cuts off the Florence ledge on the south. As may be seen from Plate XXXV the change in strike is progressive from level to level. The observed dips at the various levels agree also with the dips indicated by the curve plotted in figure 28. The fault is in the andesite, and lies as shown in figure 28, southeast of the irregular dacite-andesite contact. As exposed at the south end of the 350-foot level the fault plane has a dip of 40° at the southwest end of the exposure, but gets steeper toward the northeast. The fissure carries a few inches of soft gouge and is accompanied by considerable disturbance of the adjacent ande- site, which in the hanging wall is soft and pyritized, with some narrowly spaced sheeting near the fissure. There is pyrite in these fractures, showing that some mineralization has taken place since the faulting. The direction and amount of displacement along this fault are not determinable from the Florence workings. About 140 feet north of the main fault, on the 350-foot level, an approxi- mately parallel fissure has offset the part of the ledge south of it about 6 feet to the east. This suggests that the effect of the larger fault has been to throw the ledge south of it to the east also. Some additional light on this question is furnished by the workings of the Engineers' lease, which will be described later. FORM OF THE FLORENCE LEDGE. At the surface the Florence ledge appears as a line of rusty siliceous outcrops, which extend from the vicinity of the shaft north-northwest toward the Reilly and Combination mines. The ledge, however, does not actually join that of the Reilly, but ends, superficially at least, just north of the line of contact of dacite with andesite. (See PI. II.) From this ledge some outcropping spurs run off to the east, one of them being indicated on Plate II. The general shape of the Florence ledge, as explored underground, is probably more irreg- ular than that of the January mine, and its boundaries are not so well determined by existing workings. On the 50-foot level (PI. XXXV) the curved northeast-southwest drift is in oxidized ledge matter of unknown width, and apparently follows the line of greatest shattering in the country rock. The crosscut northwest of the shaft is in soft altered andesite containing much kaolinite and probably alunite. The whole level shows much fracturing and disturbance of the rock, and all the material is oxidized. On the 100-foot level the ledge assumes more definite form. It is generally oxidized, while the less pervious pyritized and alunitized country rock shows practically no limonite. Ledge matter and country rock thus contrast sharply in color. The plan of the ledge matter on this level, so far as it can be determined from existing workings, is shown in figure 12. The contact between ledge matter and country rock is almost everywhere sharp. In a few places there is a seam of gouge between the two kinds of material, but as a rule there is no dividing fissure or gouge recognizable. On the south the ledge is cut off by a fault, as already described. On the 150-foot level the ledge is narrower and less defi- nitely bounded, there being insufficient oxidation at this depth to accentuate the difference between the two kinds of material. The general dip of the ledge down to this level is to the west, at an angle of about 75°. Near the 150-foot level the dip flattens, and between the 150-foot and 200-foot levels expands to a maximum widtli of about 18 feet in the part of the mine adjacent to the shaft. (See fig. 17, p. 154.) Here was the large body stoped under the Sweeney lease. This wide part of the ledge continues down to the 200-foot level with a dip of 35° to 40°. It then steep- ens, narrows, and as shown in figure 17, dips east down to the 250-foot level. Near this level it 228 THE GEOLOGY AND ORE DEPOSITS OF GOLDFIELD, NEVADA. again turns and dips west at a high angle. In other parts of the mine the changes in dip from level to level are less well known. The plan of the workings, Plate XXXV, indicates that they are as great as those shown in figure 17, but vary in direction on any given level in different parts of the mine. In the southern part of the workings the general dip is northeast. The long drifts to the Reilly shaft on the 150-foot and 250-foot levels are largely in ledge matter, but this is irregular and is not continuous along the drifts, which here and there cut througli masses of soft altered dacite. The irregular distribution of the ledge matter is in part original, but is in part due to minor faulting. THE PAY SHOOTS. The first pay shoot of any inmortance in the Florence mine barely reaches the 50-foot level, near the end of the south drift, the ledge from this level to the surface being practically barren. This ore body was found to increase in size downward and on the 100-foot level has been stoped for a length of about 40 feet and to a width of 3 feet. This was all oxidized ore. Another pay shoot appears on this level just east of the shaft and is apparently the top of the large body stoped below the 150-foot level. On the latter level the ore shoot south of the shaft has apparently pinched out. Just north of the shaft, however, the 150-foot level enters a pay shoot which, prior to the Mohawk discoveries, was of unusual dimensions for this district. The stope length of this shoot on this level is about 50 feet. The ore pinches above the level and apparently has not been followed through to the small stope on the level above. Below the 150-foot level, however, the ore body flattens in dip and has been stoped to a maximum width of 18 to 20 feet. The width, however, varies greatly and the ore has no walls. (See PL XXI, A.) In parts of this body the rich ore is divided into two layers by a thin sheet or horse of low-grade ore. Near the 200-foot level the ore body steepens with the ledge and becomes nearly vertical. The stope length on this level is 75 or 80 feet and the greatest width about 12 feet. The ore varies much in width, however, and extends irregularly and without definite boundaries into the shattered and altered dacite. This pay shoot appears to end just above the 2.50-foot level. At the time of visit, in 1905, neither of the principal ore bodies known in the upper work- ings appeared to reach the 250-foot level. At the south end of the level, however, a stope about 90 feet in length had been opened on ore up to 7 feet in width. This width probably corresponds only to the ore of shipping grade, much low-grade or milling ore being left in the walls of the stope. This pay shoot evidently does not extend up to the 200-foot level and is probably not directly connected with the ore body stoped south of the shaft, above and for a short distance below the 100-foot level. A winze has been sunk on it and some stoping done from the 300-foot or intermediate level. High-grade ($500-$600) sulphide ore has been taken out from this stope to a width of 6 feet. The deposit here is lodelike, although without definite walls. It dips to the northeast at about 80°. Below the intermediate level the ore decreases in value and it is questionable whether it continues to carry ore of shipping grade down to the 350-foot level. No stoping had been done from this level at the time of visit. The most mineral- ized part of the ledge showed a sheeted structure, the slabs of pyritized, alunitized, and silicified dacite being separated by very, narrow veinlets of quartz. The pay shoot just described lies south of the Sweeney ore shoot, of which no direct down- ward continuation has yet been found on the 250-foot level. It is in line with the Sweeney shoot, however, and it is possible that the ore of the two shoots may prove to be connected. If so, the combined pay shoot pitches very strongly to the southeast between the 200-foot and 250-foot levels. In the development of the workings to the north, some ore was found late in 1905, at the end of the 250-foot level. This ore, while in the general Florence ledge zone, is not directly connected, so far as known, with the ore shoots just described and is probably a separate shoot. Its limits have not yet been determined. In the Florence, as in the other mines described, it is clear that the ore is not coextensive with the ledge, nor does it accompany the ledge to the same extent or with the same regularity MINES OF THE FLORENCE-GOLDFIELD MINING COMPANY. 229 and persistence as do the pay shoots of typical veins their fissures. It forms irregular rich bunches or bonanzas of comparatively short stope length and of no great individual persistency in depth. There were indications in 1905 that in the bottom of the mine the ledge was taking on the character of a metasomatic fissure vein with greater regularity of mineralization, but with a notable decrease in the value of the ore. The study of the Florence pay shoots in 1905 was unsatisfactory on account of the absence of accurate stope maps and even of good plans of the levels. In 1908 better maps were available, but the condition of the mine was not then favorable to examination. CHARACTER OF THE ORE. The oxidized ore of the Florence mine was never very abundant, and was practically con- fined to the south ore shoot, which was stoped between the 50-foot and 100-foot levels. Very little of this ore was visible in 1905. It appears not to have been essentially different from the oxidized ore of the Combination and January mines. The ore of the large stope worked between the 150-foot and 200-foot levels under the Sweeney lease was mainly sulphide material. The low-grade portions of this body, which alone were available for examination in 1905, consist of rock which was probably originally dacite, although it is altered so thoroughly that there is no certain means of distinguishing it from andesite. The material is now a fine-grained aggregate of quartz and alunite, with much dis- seminated pyrite in small crystals. It is minutely fissured, many of the fissures being approxi- mately parallel and giving the deposit a sheeted structure parallel to the greater dimensions of the ore body. There are no definite walls, the ore grading without any break into the country rock. The smaller fissures are filled chiefly with cryptocrystalline quartz, the little veinlets being rarely more than an eighth of an inch in width. Larger fissures and irregular interstices where the fracturing is less regular are fined with drusy quartz and filled with alunite. Pyrite, besides being disseminated through the rock, occurs also in the fissures, where it often forms films which lie next to the walls and are covered by quartz. It also occurs embedded in the quartz and alunite. Minute white crystals, probably barite, are also present in the soft alunite, which in some places is probably mixed with kaolinite. No free gold was seen in this material, although it was presumably visible in some of the rich ore taken from this stope and may have been associated with famatinite. The dependence of mineralization upon Assuring is well illustrated in the low-grade ore left in the stope, pyrite being most abundant in and near the fissures. The ore stoped between the 250-foot and 300-foot levels is nodular, somewhat resembling some of the rich ore in the Combination mine. Fragments of altered dacite, whose contours have clearly been modified to some extent by the chemical action of the depositing solutions, have been incrusted with sulphides. The inner crust is generally pyrite and is usually less than 0.1 inch in thickness. Outside of this is a crust of famatinite up to a quarter of an inch in tlxick- ness. This in turn is enveloped in a layer of cryptocrystalline quartz transfixed by needles of bismuthinite and containing also a little pyrite and famatinite. The outer surface of this siliceous envelope is rough or botryoidal with small quartz crystals and is coated with alunite. Small octahedral crystals of pyrite occur in tins drusy crust and in the alunite. The latter mineral, perhaps in some places mixed with kaolinite, fills the interstices between the nodules. It also occurs in the kernels of the nodules as an alteration product of the original feldspars of the dacite. The appearance of a typical rich nodule is shown in Plate XXIV, A. In the richest specimens much free gold is visible. It occurs chiefly in the quartz and bismuthinite zone, embedded in both these minerals. The succession of minerals, it will be observed, thus differs from that in the rich nodular ore of the Combination mine, in winch the gold is deposited mainly in the siliceous crust next to the dacite kernel. Not all of the ore in this pay shoot shows the nodular character in equal degree. In places where the dacite has been much shattered prior to mineralization and where consequently the solutions have acted upon finely broken material, the pyrite, famatinite, bismuthinite, quartz, 230 THE GEOLOGY AND OEE DEPOSITS OF GOLDFIELD, NEVADA. and gold have crystallized into more irregular aggregates. The nodular structure appears to have been best developed where the fragments acted upon were of moderate size and where the interstices between them were not packed with comminuted material. The nodular structure is not confined to rich ore. Fragments of dacite coated with pyrite that is in turn covered by quartz druses, with a little famatinite, occur on the 250-foot level where the ledge is of low grade. No bismuthinitc, however, was noted in this material. A notable increase in copper has been noted on the 250-foot and 300-foot levels in the Florence mine as compared with the upper levels. The proportion of silver, also, is said to increase with the copper. A shipment of ore from the 250-foot level made late in 1905 carried 100.8 ounces of gold and 3.5 ounces of silver to the ton, with 3.5 per cent of copper. This is the most silver per ton yet found in the ore, according to Mr. Oliver, formerly superintendent, the usual quantity of silver in ores from the higher levels being from 1 to 1.5 ounces per ton. Even 3.5 ounces of silver to 100.8 ounces of gold, however, must be regarded as a very small propor- tion. It is only about one-fifth of the proportion of silver to gold in the rich ore shipped from the Hayes-Monnette lease on the Mohawk mine, for example. None of the ore on the 350-foot level of the Florence mine at the end of 1905 was of shipping grade. The highest assays afforded about $60 a ton, the greater number giving only $25 to $30. Pyrite was the only sulphide seen on this level at the time of visit. UNDERGROUND WATER. Comparatively little water enters the Florence mine, the lowest level in 190S being kept free by hoisting from 30 to 40 buckets of water each day. MINES OPERATED BY LESSEES. REILLY LEASE. The Reilly mine, or "lease," as it more often called, is at the northwest corner of the Flor- ence claim, in what is known as lease block No. 1 of the Florence ground. The workings adjoin those of the Combination and are on the same general ledge. The lessees' stopes were carried into the ground then owned by the Combination Mines Company, and a dispute arose, which was settled by a compromise, as described on page 210. The Reilly mine has not been operated for over two years. The Goldfield Consolidated Mines Company, however, has carried its 280-foot level under the bottom of the old stopes and was taking out some very rich ore in the summer of 1908. The first lease on block No. 1 was taken by F. G. Lockhart, one of the owners of the Florence claim, and George McClelland. They found no ore and relinquished the lease. Later a second group of lessees met with little better success. They opened a small shoot of ore on the 60-foot level, but missed the main ore body. In April, 1905, B. J. Reilly secured a six months' lease of the ground. On June 21 he found some ore, but it was not until August that the extent and richness of the bonanza was realized. Messrs. McKane and Campbell were taken into partner- ship about this time, and their united energies were bent to the task of extracting as much ore as possible before the expiration of the lease on October 19, 1905. The royalties paid by these lessees to the Florence-Goldfield Mining Company correspond to a gross production of $475,000. The estimate that an additional $60,000 worth of rich ore was stolen is probably a conservative one. When visited in 1905, just after the expiration of the lease, the Reilly workings (PL XXXV) comprised a crooked shaft 210 feet deep with four levels, the important drifts being all north of the shaft. On the 60-foot level crosscuts were run northeast and southwest, but revealed noth- ing of value. A drift to the northwest follows what appears to be the northeast wall of the Com- bination ledge. It opened a small body of ore, which apparently was not connected with the main shoot afterwards found. The 110-foot level passed under this small ore body and was then turned to the north until it cut a fissure containing a tough, leathery clay gouge containing MINES OF THE FLORENCE-GOLDFIELD MINING COMPANY. 231 crystals of gypsum. This fissure, followed to the northwest, led into the main ore shoot, which was stoped for about 60 feet on this level and for about 30 feet above it. The 160-foot level was first run as a crosscut to the southwest. It was then turned north- west and at a point about 100 feet a little north of west from the shaft came into an irregular body of ore. A crosscut of 50 feet to the north finally reached the main ore shoot. (See PL XXXV.) The 210-foot level pursues a still more devious course. After first running west, it turns into a north crosscut of 90 feet in length. It then follows a gouge-filled fissure for 35 feet to the northwest and then crosscuts back southwest to the main ore body. The Reilly workings are entirely in dacite and present no geologic features of special interest. The dacite is for the most part soft, with much disseminated pyrite and abundant alunite. It is traversed by numerous fissures, of which the more persistent have a general northwest- southeast course. Some of these fissures carry clay gouge, some are associated with irregular segregations of pyrite. Most of them appear to have no close association with ore bodies. The ledge matter in the Reilly workings is irregularly distributed through the soft altered dacite and is not nearly so well defined a belt as is the ledge on the southeast part of the 130- foot level of the Combination mine. Crosscuts driven across the general line of the ledge in various places have shown only gouge-filled fissures in soft alunitized dacite, with here and there streaks and bunches of harder material such as might be termed ledge matter. The body of ore found on the 60-foot level and the one found nearest the shaft on the 160-foot level are associated with masses of ledge material which apparently are mere irregular bunches in the soft dacite. The ore of the main pay shoot is in most places inclosed in disturbed alunitized dacite with the usual disseminated pyrite. Distinct and persistent zones of characteristic ledge matter, such as the one which accompanies the pay shoot on the 130-foot level in the Combina- tion mine, are absent in the Reilly workings. The main Reilly pay shoot, as shown in Plate XXXV and figure 16, is a curiously warped or twisted sheet of ore, which does not reach the surface and varies much in stope length on different levels. Above the 160-foot level the general dip is northeast, while below that level, at least to the 210-foot level, the dip is reversed and the ore is inclined toward the southwest. As a rule the ore has no definite walls and the maximum width of the stopes in 1905 was about 15 feet. Undoubtedly, under the exigencies of the lease much low-grade ore was left standing. On the northeast side of the ore there is a rolling gouge-filled fissure which on the upper levels appears to serve here and there as a hanging wall. In many places, however, the ore apparently does not extend to this gouge. The smaller ore body shown near the third level is apparently an isolated mass inclosed in soft alunitized dacite. Both oxidized and sulphide ore are found in the Reilly mine, but the conditions for observ- ing either in place were not favorable at the time of first visit. Practically all of the rich ore in sight had been extracted, and development for the opening of new bodies had not begun. Rich sulphide ore was known to exist in a winze below the 210-foot level, but this was filled with water. Some of the sulphide ore from this winze carried over 300 ounces of gold to the ton. In June, 1908, the Goldfield Consolidated Mines Company were stoping under the bottom of this winze on the 280-foot Combination level. This ore lies close to the hanging-wall gouge, which here dips to the west and is thus locall}' the foot wall. The rich ore streak as then exposed came into the drift obliquely from the southwest and wedged out against the gouge. It is a narrow shattered zone in siliceous ledge matter with much interstitial alunite and pyrite, the best ore as a whole being soft and friable. It contains abundant native gold, some of the ore carrying up to 620 ounces to the ton. Much of the rich ore shipped by the lessees was nodular in character, concentrically coated fragments of altered dacite being embedded in so-called "talc," which was probably chiefly alunite. Other specimens show pyrite, famatinite, bismuthinite, and free gold in a porous cryptocrystalline quartz gangue. Such ore appears to have resulted from the alteration of finely crushed dacite. Some of the richest of such masses consist of little else than gold and white quartz, the gold being so abundant and in such fine particles as to give a general 232 THE GEOLOGY AND ORE DEPOSITS OF GOLDFIELD, NEVADA. yellow tint to the quartz. One unfamiliar with Goldfield ores might readily mistake this golden pigment for a superficial ferruginous stain. In some specimens small crystals of barite are embedded in alunite, which encrusts fragments of altered dacite. Other varieties of the ore show a firm interstitial filling or cement of fine-grained porous quartz with pyrite, famati- nite, bismuthinite, and gold. The fine-grained texture and minutely vuggy character of this filling indicates that it has not filled entirely open spaces but has replaced finely comminuted dacite. Marcasite, as well as pyrite, occurs in some parts of the ore body. It is of later origin than at least a part of the pyrite. The ore of the body stoped west of the shaft on the 160-foot level consists of shattered dacite, the interstices between the fragments being partly filled with alunite. The fragments themselves are hard, dense aggregates of quartz, alunite, and pyrite, the original plagioclase phenocrysts being now pseudomorphs of alunite, and the original femic minerals being now chiefly pyrite and quartz. The quartz phenocrysts alone remain unchanged. The surfaces of these fragments are incrusted and partly penetrated by a thin envelope of dark sulphides. A lens shows these to consist of the usual association of pyrite, famatinite, bismuthinite, and free gold. The oxidized ore seen in the Reilly workings presents no characteristics calling for special description. The lower limit of oxidation is irregular, mixed oxide and sulphide ore occurring on the 160-foot level. ENGINEERS' LEASE. The Engineers' lease block, as shown in Plates IX and X, lies in the southeast corner of the Florence claim. The first work in this vicinity was done by the Florence- Annex leasing company, who sank a shaft on the Cornishman claim, crosscut west on the 300-foot level, and stoped ore to the value of about $169,000 from the northeast corner of the Red King claim. One shipment of 40 tons of this ore in November, 1907, averaged $948 a ton. The shaft is 500 feet deep and considerable work has been done on the 400-foot and 500-foot levels. The only ore bodies so far discovered, however, are above the 300-foot level. The Florence-Annex lease expired on February 12, 1908, and early in the following May H. P. Taylor and L. Price began work on the Engineers' lease through the Florence-Annex shaft. On June 15 they broke into a body of ore on the 300-foot level, a short distance north of that stoped by the former lessees. At the time of visit at the beginning of July, 1908, the lease had already produced about $60,000, and at its expiration on November 8, 1908, it had paid over half a million dollars in dividends and was credited with a total gross production of $1,100,000. The country rock of the mines is andesite. This is cut by two fault fissures which limit the ore-bearing ground to the north and south. (See PI. IX.) The northern fault dips south at about 55° and is supposed by Messrs. Taylor and Price to be the same fissure that cuts off the Florence ledge, as described on page 227. This is probably true, although, as shown on Plate IX, there is a considerable difference in strike, probably about 40°, between the fault in the Flor- ence mine and the fissure in the Engineers' lease. Such curvature, however, is by no means unusual in the fissures of the Goldfield district. The 300-foot level, after passing north through the fault gouge, turns east and continues to the end in a soft mass of crushed andesite, which is probably within the fault zone. The fault which cut off the ore at the south end of the 300-foot level has been recognized only at this one place, and its trend is not known. It apparently runs in a nearly east and west direction and has a dip to the south. The Engineers' pay shoot lies just south of the northern fault, although the ore did not extend quite to the fissure. Its stope length was about 50 feet, the average width was about 2 feet, and the height of the stope at the time of visit was 110 feet. The strike of the ore body was about N. 30° W. The clip was 80° NE. It was thus a nearly vertical pipelike mass, of small elliptical cross section, and was one of the richest bodies of its size yet mined in the district. In the drift on the 300-foot level the only suggestion of ore was a mere seam of kaolinite or alunite. A raise was put up on this and soon reached the pay shoot, which continued to improve in value upward. At the time of visit the ore being taken from the top of the stope averaged about $2,000 a ton. MINES OF THE FLORENCE-GOLDFIELD MINING COMPANY. 233 The best ore was much shattered and somewhat slickensided material in which many of the fragments were concentrically coated with gold, bismuthinite, famatinite, and pyrite. The' stope showed very clearly that the rich ore had been deposited after the andesite had already undergone silicification. Specimens of this ore are illustrated in Plate XXV and described on page 165. It is very similar to some of the rich ore of the Florence and Reilly workings. LITTLE FLORENCE LEASE. The Little Florence lease lies immediately south of the Engineers' lease and the main Florence workings, the relative positions of the three mines being shown in Plate IX. The main shaft of the lessees was sunk only a few feet south of the summit of Florence Hill. Work was begun early in 1907, and at the expiration of the lease on April 26, 1908, the total gross production amounted to at least $1,500,000. The main shaft is 555 feet deep, with levels at 213, 268, 316, 442, and 555 feet below the collar. The 268-foot and the 442-foot levels, as shown in Plate IX, connect with an inclined shaft on the east slope of the hill and the 213-foot and 316-foot levels with the Mohawk-Florence shaft on the west slope. These latter shafts were the original workings, and it was while making a connection between them for air that the rich ore was discovered. Subsequently the main shaft was completed by simultaneously sinking and raising. At the time of visit in 1908 no work was in progress and only a brief examination could be made. The country rock of the Little Florence is andesite throughout. The ore body, while far from regular, is more veinlike in form than most of those exploited in the district. The ore was found at a depth of about 250 feet and the pay shoot did not extend quite to the 213- foot level. It was about 5 feet wide where first cut and averaged about $400 a ton. The pay shoot strikes north and south and was stoped in tins lease for a length of about 200 feet. On the south it continues into the Rogers lease. On the north too little work has been done to determine what becomes of the ore in that direction. Until the ground between the Tittle Flor- ence workings and those of the Engineers' lease and Florence mine is thoroughly explored it will be impossible to determine how far irregularity of deposition and how far subsequent faulting are responsible for the lack of continuity between the ore bodies of these three mines. The Little Florence ore body between the 213-foot and 268-foot levels is short and narrow, dipping to the east at 75°. Below the 268-foot level it becomes longer and divides into two rich streaks separated by a horse of siliceous ledge matter about 15 feet wide. The east shoot is the better on the 316-foot level. On an intermediate level 40 feet below the 442-foot level the two streaks of ore come together and form the widest mass of ore in the mine. On the 555-foot level there is abundant ledge matter, but this is bunchy and of low grade. Gouge seams are numerous and in places the ledge matter is cut off by faults. The rich ore stoped from tins lease appears to have been similar to that of the Engineers' and Florence mines. The only place where any of the better grade of ore was visible in 1908 was at the north end of the 316-foot level. This shows the nodular character so common in the rich ore of the Goldfield mines, and contains native gold, bismuthinite, famatinite, pyrite, quartz, and alunite. Some of the bismuthinite from the Little Florence is as coarsely crystalline as that in the Mushett lease. ROGERS SYNDICATE LEASE. The Rogers lease adjoins the Little Florence to the south (PI. IX) and is on the same ledge. Ore was found in October, 1907, on the 409-foot level, and the lease expired on July 11, 1908, after a gross production of about $660,000 from 7,000 tons of ore. The average value per ton was about $95, although some was very much richer. The workings consist of a shaft about 520 feet deep, with levels at 165, 309, 409, and 509 feet, and a sublevel at 559 feet. (See PL IX.) The principal sloping was done from the 409-foot and 509-foot levels and from the sublevel. The general country rock of the Rogers lease is the Milltown andesite, which, where not transformed into ledge matter, is as a rule soft and much altered. The shaft is in this material 234 THE GEOLOGY AND OEE DEPOSITS OF GOLDFIELD, NEVADA. and the principal levels crosscut through it for about 150 feet west-northwest to reach the ledge. This, which is a continuation of the Little Florence ledge, is exceedingly irregular and practically comes to an end in the Rogers lease. In some places it grades into soft andesite, but in others there is a definite seam of gouge between ledge and country rock. These seams vary greatly in dip and strike and are apparently local slips between hard and soft material, not persistent faults traceable from level to level. What may be called the Little Florence pay shoot, although it is not absolutely continuous, but rather a zone of rich bunches of ore, extends into the Rogers lease for about 75 feet, and has been stoped in places above the 409-foot and 309-foot levels. These bunches of shipping ore are small and occur where the ledge matter is cut by intersecting fissures which are clearly later than the primary silicification. The shoot as a whole is nearly vertical, and with its con- taining ledge matter ends irregularly near an east-west vertical plane passing through the shaft. The second and more productive pay shoot is not so obviously a continuation of that known in the Little Florence. It was first cut about 275 feet west of the shaft on the 409-foot level and near the Red King side line. The ore body, as shown by the stope in Plate IX, went very little above the level, but grew longer downward and on the 509-foot level had a stope length of 90 feet. It extends for at least 50 feet below the 509-foot level, but how much farther is not known. The grade is not as good on the sublevel as above. The width of the ore is not uniform, ranging from a few inches up to 4 or 5 feet. The general dip is between 45° and 50° E. Thus although on the 409-foot level this pay shoot appears to be separated from the Little Florence shoot, they must, if both persist, come together below the 509-foot level. There is probably at least some ledge matter joining the two. The same zone of ledge matter that contains the main Rogers pay shoot continues- into the O. K. or Rosebud lease, where it has been explored northeast of the shaft. It appears as the blunt irregular end of a wide zone of sheeted, silicified, and afterwards brecciated andesite in much-disturbed soft rock, originally of the same kind. The best assays of this ledge matter, although the rich ore of the Rogers lease came almost to the dividing line between the two leases, do not give over $20 per ton. OTHER LEASES. There are many other leases on the Florence in the vicinity of the Rogers and Engineers' leases, some of which, as the Pollard-Florence, have deep shafts and considerable lateral work, but no ore. Such geologic information as these workings afford has been referred to in the appropriate places. Description of each prospect in detail is unnecessary. North of the Florence shaft, also, there are a number of leases on the Cornishman claim, of which the workings are not shown in Plate IX. Most of these are on nearly vertical zones of sheeting and silicifi- cation in the dacite, with trends a few degrees west of north. Such for example is the Baby Florence, which has produced some ore from rich bunches in a ledge of this character. Con- siderable work has been done in this mine to a depth of 400 feet, but the ore thus far found is all above the 150-foot level. These ledges appear to occupy not very persistent zones of minor Assuring in the hanging wall of the main Florence ledge. CHAPTER XX. DETAILED DESCRIPTIONS OF THE LESSER MINES AND PROSPECTS OF THE GOLDFIELD GROUP. SANDSTORM MINE. The Sandstorm claim, situated about 2 miles north of Goldfield, was staked on December 2, 1902, by Messrs. Stimler and Marsh, and according to popular tradition was the first mining location in the district. But although claims were probably first laid off in this vicinity there is some doubt whether the distinction of primacy belongs strictly to the Sandstorm. Other claims in the group owned by the Sandstorm Mining Company are the Kruger, Magnolia, ami Stimler fraction. Efforts to find ore were at first unsuccessful, and it was not until December, 1904, that J. R. Davis, J. P. Loftus, and A. H. Mayne, lessees, found rich ore and began shipping. Some of the best ore from these leases (No. 5 and No. 6 blocks) has carried as much as $ 4,600 per ton. The royalty paid was 30 per cent of the net value of the ore extracted. In 1905 the Sandstorm Mining Company began working No. 6 block. The total production from the Sand- storm mine to the end of that year has been locally estimated at about •'5250,000. Very little work was in progress in 1908, and the following account is based mainly on what could be seen at the end of 1905. As is usual in mines worked in small blocks by lessees, the underground workings of the Sandstorm do not accord with any general plan of development. On No. 5 block, which was being worked by Messrs. Loftus, Davis, and Mayne in 1905, there is a shaft 130 feet deep, sunk on the dip of the ledge, which is 68° E. No stoping had been done below the 50-foot level in 1905. At 138 feet a crosscut has been driven through the ledge into the hanging-wall country. This shaft was being sunk to a depth of 250 feet in compliance with the terms of the lease. On the No. 6 block, which lies just south of No. 5, is a vertical shaft which was about 125 feet deep at the end of 1905. All stoping in this block at the time of first visit had been above the 50-foot level. A station had just been cut, however, for an 80-foot level, in which some rich ore was exposed. Above the 50-foot level short drifts and slopes have been run at various grades and levels wherever the ore led. In 1908 the main shaft was about 400 feet deep. Extensive exploration, however, on the 200-foot and 400-foot levels has revealed no ore, and these are for the present abandoned. The upper Sandstorm workings are all in the Sandstorm rhyolite, and this was the only rock visible at the time of first visit. The main shaft, however, is said to go through this at a depth of about 200 feet into Kendall tuff, and a crosscut from this shaft southeast reaches alaskite. The Sandstorm-Kendall ledge, shown in Plate XIII, A, outcrops boldly as a zone of strongly silicified rhyolite, 40 to 50 feet wide. The outcrop is of lodelike character and can be followed without difficulty for at least a quarter of a mile. Its strike is about N. 8° W. Where crosscut on the 138-foot level in the Sandstorm mine its width is from 35 to 40 feet, but the workings are not yet extensive enough to afford much information concerning the size and shape of the ledge underground. The material of the ledge differs from that of the dacitic ledges in containing comparatively little iron oxide; it is not conspicuously rusty. This difference is evidently due to the fact that the rhyolite before its conversion into ledge matter contained few ferromagnesian minerals, and 235 236 THE GEOLOGY AND ORE DEPOSITS OF GOLDFIELD, NEVADA. consequently there was little iron in the rock to be converted into pyrite, such as by subsequent oxidation gives the rusty character of the ledges in dacite and andesite. In the typical Sand- storm ledge matter the rhyolite has been converted into dense cryptocrystalline quartz. This is full of small irregular cavities lined with crusts of tiny quartz crystals. Much of the material, in fact, has a decidedly spongy texture. Within this hard silicified rhyolite are irregular masses of softer kaolinitic and limonitic material, and it is in such softer portions of the ledge that the ore occurs. Alunite is not so abundant in the Sandstorm ledge as in the mines nearer Goldfield. The microscope shows the hard silicified material to consist of finely granular quartz, which in some places contains microscopic disseminated crystals of pyrite. Much alunite, however, occurs in the altered rhyolite near the Sandstorm and Kendall mines, especially in some of the Morena rhyolite, which is cut in the bottom of the Kendall mine. It is not always easy to say whether this alunitic material should be called ledge or country rock. The ore bodies of the Sandstorm consist entirely of oxidized material. The deepest ore found up to the end of 1905 was at 80 feet. This shows a little pyrite under the microscope, although the gold itself is associated with limonite and kaolin. Practically all the stoping had been done at depths of less than 50 feet. The pay shoots are irregularly distributed through the ledge zone and are usually associated with zones of transverse Assuring. The best defined of these fissures runs east and west and on the whole is nearly vertical, although the dip is not uniform. It crosses the Sandstorm lode 30 or 40 feet north of the No. 6 shaft and is apparently of later origin than the metamorphism which produced the ledge. It varies from a few inches to 3 feet in width and is filled with triturated material. Some of the fragments have been rounded to pebbles by movement along the fissure. Some ore occurs in the fissure, but the principal masses extend out from it into the ledge matter. As a rule these bunches are very irregular in form, but most of them appear to rest upon an uneven although generally nearly horizontal floor of hard silicified rhyolite. This floor is apparently barren and exhibits no particular mineralization, although it, like most of the unoxidized ledge matter, contains a little very finely disseminated pyrite. There is apparently no gradation from the rich oxidized ore into this hard underlying material. Some of the pay shoots extend from this floor up to the surface as irregular pipes or chimneys; others rest upon it as flat-lying masses and are overlain by barren or low-grade ledge matter. As already mentioned, all the ore thus far found in the Sandstorm mine is oxidized. It consists usually of a rather soft earthy mixture of kaolinite, quartz, limonite, and free gold, the latter in some of the richest lumps of ore constituting a considerable part of the mass, through which it is disseminated in small particles. Singly these are barely visible with the naked eye, but their abundance in some cases gives a yellow tint to the ore. Crystals of barite are fairly common. They are generally implanted upon the surfaces of the hard silicified rhyolite and project into the softer and richer material of the ore, which fills crevices in the rhyolite or envelops loose fragments of that rock. Some of the ore contains pearly scales of bismite, indicative of the former presence of bismuthinite. Some of the oxidized ore shows slight copper stains, and Mr. C. D. Wilkinson reports that he has seen a little chalcopyrite in the main cross fissure. It is probable that some famatinite, or possibly goldfieldite, accompanied the bismuthinite in the sulphide ore, as in the mines near Goldfield. The best ore shipped from the Sandstorm prior to 1906 is said to have carried about $4,600 (230 ounces) in gold to the ton. It is probable that the Sandstorm ore bodies were originally masses of sulphide ore with very nearly their present shape — that is, they were comparatively small, rich bunches sur- rounded by ledge matter and having no direct downward continuation. The original ore presumably contained pyrite, free gold, bismuthinite, and some cupriferous sulphur-bearing mineral. Oxidation of the known ore bodies has been practically complete, and in the course of that oxidation there has probably been some secondary concentration of the gold. KENDALL MINE. 237 KENDALL MINE. The Kendall claim adjoins the Sandstorm on the north and, with the Argosy and Oregon claims, is the property of the Goldfield Kendall Mining Company. The principal workings are on the Kendall claim and on the same ledge as those of the Sandstorm. The mine was first worked by lessees, but was being operated by the company in 1905. The total production to the end of that year was about $100,000. Little work has been done on the Kendall of late years, and the following description applies to the mine as it was in 1905. The main shaft of the Kendall mine is vertical, and at the end of 1905 was about 200 feet deep, with levels at 60 and 100 feet. Sinking was then in progress. Above the 60-foot level are some small tunnels and some irregular stopes and drifts. All the stoping at the time of visit had been done between the 60-foot level and the surface. The Kendall shaft is sunk in Sandstorm rhyolite, which, as shown in Plate II, here forms a narrow strip between an area of Kendall tuff on the west and the Milltown andesite on the SHAFT ^7.v,vvv.VrN)C/N-^ *.C/' + + + ++ + + + + + + + + i / ^ A - X+ + + + + + + + / /. i > \ \ ^ . \ / / . ■*. / ■ i 0/J/ \ , / - ' ^X0/1" + + + + - N XC .... iX/& + Milltown andesite + + + +•+ + + f f + + '.■>•: Kendall tuff .'4 ^ 7i.\ + >'.\V~73 ' / n| ( ^ i / / — — s. } — I 00 -foot level / \/ \ / V ' . ' I — *• 1 /*•»'».' ,/ > i-,.,X/ -/ / / -. / \ / 0 23 I I I 1 I L_ 75 FEET I / 1 rhyolite, 7 * „ ' V < , Figure 29.— Section through the Kendall mine. east. At a depth of about 135 feet the shaft passed into this tuff and continued in it for about 20 feet. It then passed into rhyolite of the intrusive Morena type, and continued in this rock to the bottom. The exact thickness of the tuff where it is penetrated by the shaft is not meas- urable, as the lagging of the shaft conceals the contacts. The general relation of these rocks is shown in section in figure 29. The tuff, as exposed at the surface, appears to pass beneath the Sandstorm rhyolite on the north, west, and south, but to be cut off on the east by a fault. (See PI. II.) This fault is well exposed on the 60-foot level, about 27 feet west of the shaft. There is not much breccia- tion of either rock, but the plane of movement is marked by a distinct gouge. The fault plane at this place dips about 40° E. It truncates the flow banding of the rhyolite, which dips about 238 THE GEOLOGY AND ORE DEPOSITS OF GOLDFIELD, NEVADA. 25° W. The tuff probably rests upon Morena rhyolite about 150 feet below the surface. This rhyolite is doubtless intrusive into the tuff, but the contact has not been exposed except in the shaft. On the 100-foot level a crosscut has been driven east through the Sandstorm rhyolite into the andesite, as shown in figure 29. The contact lies about 135 feet east of the shaft on this level, and appears to be the result of faulting. The andesite is soft and altered and is either tuffaceous or has been brecciated by movement. The faulting is probably local and is thought to represent minor displacement along a contact which originally was a rhyolitic surface over which the andesite flowed. This same plane of movement, winch dips about 35° E., is exposed in a tunnel just north of the main Kendall shaft. Near the mouth of this tunnel a shaft goes down through about 95 feet of andesite to the same contact. This shaft was not in good condition in 1905, but the dump indicated the presence of soft gougelike material at the base of the andesite and showed considerable pyritization of this rock in its lower part. The Kendall ledge is the same as that of the Sandstorm mine. It is an indefinitely bounded zone of silicification in the effusive rhyolite. It was doubtful at the time of visit whether the ledge could be recognized at all below the point where the shaft enters tuff. The rhyolite in the bottom of the shaft contained much alunite, but this kind of alteration is so widespread in the Morena rhyolite as to be practically useless as a means of distinguishing typical ledge mat- ter from country rock. At the time of visit, near the end of 1905, no ore had been found below the 60-foot level. Considerable rich ore was found by lessees at the surface, pockets of soft auriferous material having been gouged out from the hard, low-grade, siliceous part of the croppings. Subse- quently ore was found, much as in the Sandstorm, in the form of small irregular bunches very erratically distributed through the ledge. The dependence of these rich bunches, however, upon transverse fissures was clearly shown, these fissures, which are neither regular nor per- sistent, having generally northwest-southeast trends. The ore is entirely oxidized and no sulphide ore has yet been discovered beneath it. It is usually a soft mixture of kaolinite, quartz, limonite, and native gold, with abundant barite in crystals up to an inch or more in length. As in the Sandstorm mine, the barite crystals are usually implanted on silicified rhyolite with their free ends embedded in kaolinite or kaolinitic ore. No alunite has been noted in the Kendall ore, although this mineral is abundant in the bottom of the shaft. CONQUEROR MINE. The Conqueror or Tonopah Club mine embraces the Tonopah Club and Bonanza claims, owned by the Conqueror Mining Company. The principal workings lie about half a mile east- northeast of the Kendall mine. Ore to the value of a few thousand dollars was obtained near the surface in 1904 and 1905, but the property has not since been an important producer. No work was in progress in 1908. The principal workings (1905) are an incline about 100 feet in length run on an angle of 20° to 25°, and a vertical shaft about 50 feet in depth, with a crosscut from the bottom. All the stoping has been within 10 or 15 feet of the surface. The geologic relations at the Conqueror mine are more complex than in most of the mines in the district. At the surface is exposed an oval area of Morena rhyolite. This is intrusive into Sandstorm rhyolite, which here has a most deceptive similitude to a gray shale. Just east of the mine openings and dividing -Sandstorm rhyolite on the west from andesite on the east is the line of the Columbia Mountain fault. This fault dips to the east at a low angle (see fig. 3) and is followed by the inclined shaft previously mentioned. A well-marked zone of silicification or ledge, having a course of a few degrees east of north, traverses the oval area of Morena rhyo- lite. The ore has been found, not in this ledge, but between its southern end and the andesite to the east. GOLDFIELD MERGER MINES COMPANY'S MINES. 239 The mine workings show shaly Sandstorm rhyolite irregularly intruded by Morena rhyolite. All the ore thus far found was in the shaly masses of the older effusive rhyolite. The Columbia Mountain fault, as shown by the incline shaft, contains much-crushed shaly rhyolite, much of it reduced to a tough, claylike gouge. This soft material is full of small crystals of pyrite and is said to afford assay values up to $12 per ton*. ADAMS MINE. The Adams mine, which, like the Conqueror mine, has furnished a little ore from surface workings, closely resembles the latter in geologic relations. It is situated rather less than half a mile east of the Sandstorm. The country rock is Sandstorm rhyolite, which is underlain and irregularly intruded by Morena rhyolite, which comes to the surface just south of the mine, as shown in Plate II. The Adams, like the Conqueror, is close to the Columbia Mountain fault, but the workings had not extended to the andesite in 1905. The effusive or Sandstorm rhyolite is much disturbed and altered, but exhibits comparatively little mineralization. None of the irregular workings had attained a depth of 100 feet in 1905. In 1908 the mine was idle and was not again examined. KEWANAS MINE. The Kewanas mine is situated about 1\ miles northeast of the center of Goldfield and three-eighths of a mile south of the Nevada-California Power Company's transformer station. The country rock near the surface is dacite. The workings comprise an inclined shaft" which goes down to the east for a distance of 500 feet at an angle of 45°. There are levels at 100, 200, 400, and 500 feet from the collar. The rock of the mine is generally much altered, partly to ledge matter, but more exten- sively to soft decomposed material which soon caves when a drift is abandoned, and which, as a rule, is difficult to identify petrographically. At the 200-foot level the shaft is in decomposed andesite or andesitic tuff, but the general country rock in the drifts which extend north and south for a total distance of about 250 feet is dacite. The relation between the two rocks is nowhere clearly shown. On the 400-foot level the main country rock is soft altered latite, but here and there in the level, which explores the ground for a distance of about 400 feet from north to south and 300 feet from east to west, are ill-defined masses of fine-grained decomposed andesite, and in a few places some dacite. The 500-foot level is chiefly in latite; which is either silicified to ledge matter carrying some pyrite or else is in a soft, gougelike condition. The conditions for geologic study in this mine render it impossible to determine the structural relations of the much-altered rocks therein exposed. Probably the observed masses of andesite and dacite are in part dikes in the latite. The soft, disturbed character of the ground, moreover, suggests the possibility of considerable faulting, which can not be worked out from present exposures. As noted on page 53, some of the shafts just north of the Kewanas go through dacite into andesite breccia of considerable thickness. Evidently the Milltown andesite underlying the dacite in this vicinity is not uniform in character, and this adds to the difficulty of interpreting what may be seen underground. The Kewanas mine has shipped no ore and is essentially a prospect. GOLDFIELD MERGER MINES COMPANY'S MINES. INTRODUCTION. In June, 1908, the St. Ives, Velvet, Gold Horn, and Potlatch mining companies consoli- dated their buildings under the title of the Goldfield Merger Mines Company, capitalized at $5,000,000. At the time of consolidation the St. Ives and Velvet mines had small productions to their credit, mainly from the workings of lessees. Recently the company has sunk a new shaft from which to explore its ground. « Since the mine was visited this has been abandoned and a new, vertical shaft sunk. 240 THE GEOLOGY AND ORE DEPOSITS OF GOLDFIELD, NEVADA. ST. IVES MINE. The St. Ives mine is situated a little more than a mile east-northeast of Goldfield, and half a mile north of Milltown. The property was worked by lessees in 1904, and the results of their operations are summarized in the following statement, which is of interest as illustrating the conditions under which ore was marketed in the early days of the camp. Operations in St. Ives mine, 1904. Gross weight of ore shipped tons. . Net weight of ore shipped do Gross contents of ore shipped ounces. . Gross value Treatment charges $287. 34 Loss in smelting, 21 per cent 56. 73 Freight 1, 302. 97 Agent's charges 5. 50 Assays 6. 00 Exchange on draft 3. 25 49.34 47.87 535.7 $10, 683. 22 1, 661. 79 Total net value 9; 021. 43 Lessees' share (80 per cent) 7 217. ] 5 Company's share (20 per cent) 1, 804. 28 The gross value of the ore per ton was $223.14 and the net value $150.74. In February, 1905, the first lease expired, and the company began operations on its own account. The ore shipped by lessees was stoped between the 100-foot level and the surface, most of it coming from near the 50-foot level. When visited late in 1905, the workings com- prised a vertical shaft 250 feet deep, with levels at 50, 100, 150, and 250 feet. These are shown in plan in figure 30. No work was in progress in 1908 and the mine was not revisited. The St. Ives ledge, which is in dacite, outcrops boldly, forming the crest of a small north-south ridge, as may be seen from Plate II. It has many branches and is part of a complex chain of ledges extending southeastward past Mill- town to the Gold Bar mine. The main ledge at the St. Ives mine strikes north-northeast, but the shaft is sunk at a point near which branches run out to the east-northeast and to the northwest, as shown on Plate II. Most of the 50-foot level (fig. 30) is in ledge matter, all more or less rusty from oxidation. The general trend of the siliceous zone on this level is northeast. The 70-foot and 100-foot levels are also almost wholly in oxidized ledge matter. The 70-foot shows nearly the same strike as the 50-foot, but on the 100-foot level the trend of the ledge becomes almost due north and south. In other words, the dip of the ledge in the southern part of the workings is about 45°, while in the northern part it is nearly vertical. On the 150-foot level, which is below the limit of oxidation, the ledge is Figure 30.— Plan of the St. Ives mine. GOLDFIELD MERGER MINES COMPANY'S MINES. 241 very obscure. Beginning at a point about 30 feet east of the shaft the dacite for a distance of 50 feet shows irregular bunches and streaks of partially silicified material alternating with soft pyritized and alunitized dacite. In some places the dacite has been shattered and contains considerable pyrite and alunite, such material having the characteristics of unoxidized ledge matter. On the 250-foot level the ledge is still more obscure. A crosscut east from the shaft was about 100 feet in length at the time of visit. This showed soft pyritized alunitized dacite, with slight silicification along some of the fissures. The highest value obtained by assay from any of the material on this level did not exceed $5 a ton. On the whole the St. Ives mine illustrates well the fact of a decrease in silicification with increase in depth. The ore bodies stoped in the St. Ives mine were mainly near the 50-foot level and were oxidized. They were irregular in outline and of small size. The largest body (see fig. 30) was about 50 feet south of the main shaft. It extended about 20 feet, on the dip, above the 50-foot level and for a short distance down the winze to the 70-foot level. CODD LEASE. The Codd lease is on the St. Ives ground and is worked through a shaft 500 feet deep, situ- ated a short distance west of the St. Ives shaft. The upper levels are in dacite, but somewhere between 350 and 400 feet in depth the shaft goes into latite. Oxidized ore of a gross value of about $11,000 was mined in 1907 from small irregular pay shoots in the dacite above the 50-foot level. The ore trends nearly north and south and dips west. The total length of the stopes is about 100 feet. As in the St. Ives proper, the deeper levels have not proved encouraging. VELVET MINE. In 1904 a bunch of oxidized ore found practically at the surface yielded lessees about $10,000. Since then a number of shafts have been sunk near the original discovery, about half a mile northeast of Goldfield. Two of these, the Alta shaft, 418 feet deep, and the Chicago- Velvet shaft, 526 feet deep, were in operation in 1908. The geologic features of these workings are referred to on page 81 . They are not in ore. JUMBO-EXTENSION MINING COMPANY'S GOLD WEDGE CLAIM. The Gold Wedge, as may be seen from Plate IX, is a fractional claim lying on the north- east side of the Mohawk No. 2 claim. On it is a line of lessees' shafts, which from north to south are the Jumbo Annex, Higginson, Mohawk Ledge, Frances-Mohawk, and Mohawk- Jumbo shafts. At the time of second visit to the district, in 1908, these workings were all closed by injunction and were not examined. The dumps showed that all the shafts at that time were wholly in the dacite. Lease blocks in the Goldfield district are bounded by vertical planes, and consequently the lessees on the northern part of the Gold Wedge are confined within narrow limits. In the Mohawk-Jumbo workings, however, at the south end of the claim, large stopes have been opened on the same pay shoots that are stoped at higher levels in the Mohawk mine. (See PI. IX.) This shaft at last report was 685 feet deep, making it one of the deepest in the district. The settlement finally reached between the Goldfield Consolidated Mines Company and the Jumbo Extension Company over the Gold Wedge claim is described on page 23. COMBINATION FRACTION MINES. The Combination Fraction Mining Company owns a nearly square fractional claim between the ends of the Mohawk No. 2 and Florence claims, and northeast of the Combination mine. In it are 5 sets of workings. In the south corner is the company's shaft, with extensive explo- ratory levels down to 431 feet in depth. (See PI. IX.) These workings were closed in 1908 and were not studied. They are probably all in dacite and the ground is said to be generally soft and disturbed. No ore has been found. In the northwest corner of the claim is the Burns 79145— No. 66—09 16 242 THE GEOLOGY AND ORE DEPOSITS OF GOLDEIELD, NEVADA. shaft. The ground here also is soft and the drifts soon close. Northeast of the Burns shaft is the Loftus-Davis lease shaft. From this slopes were opened on the Mohawk ledge in 1906 and 1907. This shaft had been dismantled in 1908, although it was possible to enter the stopes from the Mohawk workings. The 531 -foot level (PI. IX) is reported to follow a nearly vertical fault which is supposed to cut and displace the Mohawk ledge. This level could not be reached in 1908. The displacement is certainly not great, as a short distance north the ledge has been found generally continuous down to the 600-foot level of the Mohawk. East of the Loftus-Davis shaft is the Oddie shaft, originally sunk by lessees, but now being operated by the company. Its depth is 612 feet. It was sunk without any lateral explora- tion above the bottom level, with the expectation that the Mohawk ledge would be cut at a depth of about 600 feet. Subsequent work in the Mohawk mine shows that this expectation was justified, but the lessees failed to find ore. A part only of the 612-foot level was accessible in 1908. It is apparently mostly in latite, the contact, which locally at least seems to be a fault with steep dip to the east, being a few feet west of the shaft. The rock in the vicinity of the contact is soft and decomposed. A part of the latite on this level is distinctly a pyroclastic rock. The 427-foot level shows a north-south dacite ledge with easterly dip. The width of this had not been determined at the time of visit. The principal work in progress in 1908 was on the 285-foot level, where ore in dacite, very similar in character to some of the lower-grade Hayes-Monnette ore, had been opened in two places. Dacite is the only rock on this level. Too little work had been accomplished at the time of visit to reveal the size or shape of the ore body, which is probably an irregular mass in the hanging wall of the main Mohawk ledge. About 250 feet southeast of the Oddie shaft is the shaft of the Little Florence Leasing Company. At the time of visit no ore had been found in these workings, which are in dacite. ATLANTA GROUP. The Atlanta group includes the Atlanta Union, Black Bear, and Bismark claims and lies directly east of the Florence-Goldfield Mining Company's ground. The Atlanta Company has done comparatively little development, but the property has been most persistently explored by lessees, with very little encouragement. Among the shafts on this ground, most of them ranging from 300 to 500 feet in depth, are the Jumbo ledge, Blake, Maloney, Chedd, Lucky Swede, Century, Imperial, Atlanta-Cherokee, and Garrison. The lateral development from most of these shafts is small. GOLD BAR AND VICTOR MINES. The Gold Bar and Victor mines of the C. O. D. Consolidated Mining Company lie south- east of the Atlanta group. (See PI. X.) The main company shaft is the Gold Bar, 300 feet deep. About 400 feet east-southeast of this is the Victor shaft, operated by lessees, and about the same distance in the opposite direction is the C. O. D. shaft, no longer in use. These three shafts are connected by the 200-foot Gold Bar level, as shown in figure 31. The country rock in the upper level is the Milltown andesite, but the 300-foot level and a large part of the 200-foot level east of the shaft are apparently in latite, although the rock is too much altered for satisfactory identification. Dacite appears at several points on the 200- foot level, probably as intrusive tongues in the latite and andesite. In spite of the prevailing alteration this intrusive character of the dacite is well shown at one place on the south side of the main west drift of the 200-foot level. Both rocks are soft and greatly altered, but the original irregular contact does not appear to have been disturbed. A large part of the workings are in ledge matter. While this is largely altered andesite and partly latite, there is a rather close association between ledge matter and dacite. The latter penetrated in ragged protrusions into the older rocks, and the subsequent silicification and mineralization have taken place chiefly in the vicinity of these intruded masses. BLUE BULL MINE. 243 Shipments aggregating about $25,000 in gross value have been made from time to time from a chain of very irregular bunches of ore extending eastward from near the Gold Bar shaft down to the 200-foot (250-foot Victor) level near the Victor shaft, and some ore was produced from a body of oxidized ore near the surface at the C. O. D. shaft. The unoxidized ore is char- acterized by an abundance of a dark-gray brittle mineral, which reseznbles the famatinite of the Florence and other mines near Goldfield. Like that mineral, it contains copper, sulphur, and antimony, and forms crusts around partly rounded fragments of silicified andesite or dacite. It has not the reddish tint of the famatinite, however, and unlike that mineral else- where in the district is not associated with particularly rich ore. It is possibly enargite. As pointed out on page 117, the distinction between enargite and famatinite is impossible with- out quantitative chemical analysis of pure material or the presence of satisfactory crystal form. The Kansas City lease, northwest of the C. O. D. shaft, is not in ore and was not examined. North of the Gold Bar shaft is the shaft of the Gold Bar Leasing Company, 475 feet deep at the time of visit, but not in ore. The country rock is all Milltown andesite. The workings VICTOR SHAFT 250- ft. level Figure 31.— Plan of the Gold Bar and Victor mines. show irregular masses of ledge matter with abundant pyrite, partly disseminated and partly as crumbling stringers. The best assay obtained prior to the time of visit was $1.80. BLUE BULL MINE. The Blue Bull Mining Company owns about 7 claims, lying in a compact group about If miles east of Goldfield. On the Blue Bull claim, which is the northeast member of the group, the company has sunk a shaft 110 feet deep, and has crosscut from the bottom of this for about 400 feet, under some bold ledge outcrops which crown the hill just east of the shaft. The dacite penetrated by this crosscut is cut by two sets of conjugate fissures with a common northeast strike. One set dips northwest at various angles up to 60°; the other dips southeast at rather lower angles. The fissures with northwest dip are generally the stronger, and consid- erable silicification has taken place along them. The great east-west ledge which outcrops on the ridge east of the shaft (see PI. II) had not been satisfactorily exposed in the crosscut at the time of visit. It appears to correspond to a series of east-west fissures, concerning which the mine workings as yet afford very little information. This ledge has been crosscut by a tunnel 244 THE GEOLOGY AND OBE DEPOSITS OF GOLDFIELD, NEVADA. near the crest of the ridge, where it proved to be about 25 feet wide. A small bunch of ore was found in shattered kaolinized dacite, about 50 feet from the surface, on the south side of the siliceous ledge, but the Blue Bull mine has never made any shipments. This shaft had been abandoned in 1908, and a new shaft, which was not visited, had been sunk about 800 feet south of the old one. On the Hat claim, which is at the south end of the Blue Bull group, lessees at the end of 1905 had taken out a little oxidized ore from workings about 50 feet in depth. Additional work has since been done on this lease, but the shaft, like others in the vicinity, was closed at the time of second visit. The country rock here is the Milltown andesite, and the ore as seen iii 1905 occurred in a prominent ledge containing abundant red oxide of iron. The character of the ore is described on page 124. SIMMERONE MINE. The Simmerone is situated about 2 miles east of Goldfield, near the eastern border of the central dacite area. The mine was not producing in 1905, although a small bunch of rich ore had previously been stoped from near the surface, yielding about $5,000 gross. The mine in 1905 had a vertical shaft 50 feet deep and a 44° incline about 110 feet in length. The country rock, which is dacite, is traversed by many fissures, which in general strike north and dip 45° W. These give the rock a pronounced sheeted structure, and along some of them considerable siliciflcation has taken place. The body of ore stoped was found in the incline and extended to a depth of 60 feet. It was an irregular pipe of small horizontal section. The ore is a firm fine-grained material, much of which is pink or light red, irregularly streaked with gray. This material is chiefly alunite, mixed with kaolinite and iron oxide. The gold is distributed unevenly in small hackly particles through the impure alunite. Since the first visit a new shaft has been sunk, which goes through the dacite into the latite. The shaft was not in operation in 1908 and no information regarding it could be obtained. LONE STAR GROUP. The Lone Star mine is about 2 miles east of Goldfield, just north of the ridge on which are the Blue Bull, Simmerone, and Commonwealth workings. The total gross production to the end of 1905 was approximately $10,000, from ore mined by lessees who expended about $15,000 on the property. So far as known there has been no subsequent output. The Lone Star ledge, shown in Plate XIV, B, outcrops boldly, the exposed part consisting of strongly silicified dacite sheeted by closely spaced north-south fissures. This zone of sheeting and siliciflcation is at least 50 feet wide at the surface. The ledge strikes a few degrees east of north and dips 60° E. An inclined shaft has been sunk by lessees on the foot-wall side of the ledge and levels run at 80, 150, and 220 feet below the surface. The principal ore body was followed from the 80-foot level to a point about 20 feet below the 150-foot level. The maximum stope length of the shoot was 20 feet and the greatest width of ore 5 feet. The shoot was accordingly of pipe form. The ore all showed some oxidation and apparent^ consisted of iron-stained alunite, with probably some kaolinite, carrying native gold. A specimen taken from the bottom of a winze below the 150-foot level, at the point where the ore shoot ends, is a rather sandy aggregate in which the constituents are chief!}'' rough, doubly-terminated, microscopic crystals of quartz. The average value of the ore shipped, according to the lessees, was $290 a ton. Alunite is abundant in the Lone Star ledge and in some places forms soft, snow-white or faintly pink masses, with practically no impurities. • The holdings of the Lone Star Mining Company cover an extensive area and embrace about 16 claims. The principal company workings are on the Patrick claim, west of the lessee workings just described. The shaft is only 100 feet deep, but the drifts and crosscuts at this depth arc unusually extensive. They have revealed no ore. The rock is generally much altered and shows considerable disturbance. The bottom of the shaft is just in latite, the PORTLAND MINE. 245 contact with the overlying dacite as seen in the 100-foot station being nearly horizontal. Else- where in the workings dacite appears to cut both latite and andesite, but the information afforded by the exposures is nowhere definite. The general relations of the rocks are similar to those observed in the Kewanas workings, although the thickness of the dacite is much less at the Lone Star shaft. COMMONWEALTH MINE. For the past three or four years lessees have been shipping small lots of ore from superficial workings on the north slope of the ridge east of the Blue Bull and Simmerone mines. This locality, as may be seen from Plate II, is near the eastern edge of the main dacite sheet, and with the exception of the Diamondfield mines is the farthest point east at which any impor- tant quantity of ore has been found in this ditrict. The ore thus far mined is all oxidized and occurs in the usual irregular masses in dacitic ledge matter. Below the tunnels from which the ore has been stoped the Commonwealth shaft has been sunk to a depth of 400 feet. The shaft apparently goes into latite somewhere above the 100-foot level, but the exact depth of the change could not be ascertained, owing to the close lagging of the shaft. The shaft was not in operation in 1908, and the water stood at the 300-foot station. So far as could be ascertained no ore was found in these workings. PORTLAND MINE. The Portland mine is situated about a mile east-southeast of the center of Goldfield and a little less than half a mile south of the Florence mine. It has never shipped any ore. The principal development in 1905 was on the bottom level, 250 feet below the surface. Since then a level has been run at a depth of 400 feet, but none of the lateral work was visible in 1908 owing to the caving of the soft heavy ground. An attempt to put down a diamond- drill hole below this level was abandoned before the bottom of the latite had been reached. The geologic features in this mine are especially interesting. As may be seen in Plate II, the Portland shaft is sunk through a small lobe of the Siebert formation, which apparently rests on andesite. It is not known at what depth the shaft passed out of the Siebert sedi- ments, but it was probably very close to the surface. From the collar of the shaft to the 250- fcot level there was no point at which the rocks could be satisfactorily examined in 1905. From the bottom of the shaft a crosscut has been driven for about 350 feet to the east. From all that was previously known of the structure of this part of the district it was to be expected that the rock in this crosscut would be andesite. It consists, however, of amygdaloidal olivine basalt flows with basaltic tuffs. In general these are soft and much altered and contain much disseminated pyrite. The depth at which these rocks occur appears to rule out any attempt to correlate them with the quartz basalt exposed south of Goldfield or with the later olivine basalt capping Afyers Mountain. The most probable hypothesis is that they represent local basaltic eruptions within or immediately preceding the andesite period. The dump of the mine shows that at some point between the 250-foot and 400-foot levels the shaft went into latite and continued in this rock to the bottom. As a whole the rock of the Portland mine is soft, much of it being little firmer than mud. The Portland was for some years the only deep shaft south of Florence Hill. Recently a number of prospecting shafts, some of which exceed it in depth, have been sunk in its vicinity. These all go through andesite into latite at a depth of about 300 feet. OTHER PROSPECTS. The White Rock, Silver Pick, and numerous other companies owning claims in the vicinity of Goldfield have prospected their ground fully as extensively or even more so than some of those mentioned in the preceding descriptions. To describe in detail all these workings would add to the bulk of this report without increasing its interest or usefulness. Such geological information as is furnished by these various shafts has been incorporated in earlier chapters. CHAPTER XXI. DETAILED DESCRIPTIONS OF MINES OF THE DIAMONDFIELD GROUP. DIAMONDFIELD-BLACK BUTTE CONSOLIDATED MINES. The Quartzite and Black Butte mines, with workings mainly on the north side of Black Butte, were consolidated as the Diamondfield-Black Butte Consolidated Mines in 1905. Prior to that a considerable body of ore had been stoped by lessees, mainly from the original Quartzite ground. A plan of the combined workings is shown in figure 32. The Quartzite shaft is about 200 feet deep, with four levels 50 feet apart. The Black Butte shaft is 150 feet deep, with three levels, which are about 10 feet below the cor- responding Quartzite levels. A tunnel 545 feet in length pene- trates Black Butte from the south and connects through a 25-foot winze with the 50-foot level of the Black Butte work- ings. East of the portal of this tunnel is a chain of nearly horizontal stopes on a flat vein. The general coun- try rock of the mine is andesite, which is cut by a few ill-defined masses of dacite. Both rocks are in most places py- F.0URE32.-Plan of the workings of the Black Butte mine. ^^ ^ ^^ ^ containing much gypsum in gouge seams and in all the joints and crevices. Fissuring in nearly horizontal planes is a notable feature of the country rock and has resulted in the formation of sheets of brecciated and more or less silicified material. The massive ledge which caps Black Butte (see PI. Ill, B) is clearly a remnant of such a sheet, since the tunnel passes directly under it. Similar but smaller silicified sheets are exposed in the tunnel, and, as may be seen from figure 14, these may be very irregular. In some places the horizontal fissuring has produced a sheeted instead of a brecciated structure. Such in the main is the flat vein stoped along the south side of the butte. As a rule, most of these horizontal ledges contain a little ore, but it is very bunchy and erratic in its occurrence. The ledges themselves, moreover, are apparently not very persistent. The ore body stoped by the lessees on the north side of the butte was a very irregular but generally lenticular mass, with north-south trend and a dip to the west, the lens being nearly on edge. Its maximum stope length was about 100 feet and its greatest width about 25 feet. In its widest part the ore was divided longitudinally by a slab of waste or low-grade ore. The extreme vertical range of the ore was about 100 feet, its bottom limit being near the 100-foot level. It became poorer and narrower close to the surface. On the north the ore ended against 246 MINES OF THE DIAMONDFIELD GROUP. 247 a seam of gouge. At the bottom it graded into soft barren andesite. All of the ore appears to have been partly oxidized, the bottom of the pay shoot coinciding roughly with the lower limit of oxidation. The best part of the ore was between the 50-foot and 100-foot levels. The ore, as shown by the little left in the stope, was a much-shattered mass of andesite, in which all the smaller fragments and part of the larger ones had been replaced by cryptocrystal- line quartz carrying pyrite and famatinite. Doubtless native gold and probably a telluride of gold were present in the richer ore prior to the oxidation. The greenish-yellow ferric tellurite, emmonsite or durdenite, is said to have served as an indication of good ore. Alunite is abund- ant, both as a secondary constituent of the altered fragments of andesite and as a filling in crevices and vugs in the sulphide ore. Within the generally silicified material of the pay shoot near the bottom of the ore are some masses of andesite which have been changed to soft, crum- bling aggregates, consisting chiefly of alunite and pyrite. Practically all of the material available for examination in 1905 was sulphide ore, which in this mine has proved of low grade, rarely carrying over $15 a ton. Whether the partly oxidized ore taken out by lessees owed its greater richness to secondary concentration or whether the sulphides from which the extracted ore was derived were originally richer than those remaining, it is impossible to say. The relations are suggestive of secondary enrichment during oxida- tion, but bunches of unusually rich unoxidized ore are in this district so common as to throw the burden of proof upon the enrichment hypothesis. The boundary between the ore and the country rock appears in this deposit to have been unusually definite and in many places is marked by a seam of gouge. Similar seams were some- times found within the ore. All attempts to find a downward continuation of the rich ore shoot have proved futile, although, as shown in figure 32, two levels have been driven directly under the old stope. They show altered pyritized country rock. Exploration in depth has revealed only a few small podlike masses of ore separated by curved seams of gouge from the surrounding soft andesite. Other ore bodies, however, occur in Black Butte, as shown by the discovery of rich ore at the surface, on the south slope, in December, 1905. This was in one of the numerous nearly hori- zontal fissure zones, and at the time of visit, shortly after its discovery, the ore body had been followed into the hill for a distance of 20 to 30 feet. This ore, which was from 18 inches to 2 feet in thickness, showed native gold of unusually rusty appearance, associated with a greenish- yellow ferric tellurite and cryptocrystalline quartz in a nearly white, alunitized rock, which appears to have been originally dacite. (See PI. II.) The gold resembles, more than does most of the native metal in the district, the gold derived from tellurides in the Cripple Creek district, and without much doubt existed in part as a telluride prior to oxidation. Small brighter specks within the dull gold probably represent original inclusions of native metal in the telluride. When visited again in 1908 this ore body had been practically stoped out, although some lessees were still stripping the sides of the stopes. The deposit proved to be nearly horizontal near the surface of the hill, along which it has been stoped for a distance of about 300 feet. The ore was followed into the hill for a maximum distance of nearly 100 feet. The dip in this direction became steeper and the ore gave out. The better part of the body occupied a nearly horizontal zone of sheeting in dacite, the latter rock, as shown in Plate II, extending as an intrusive tongue into the andesite of Black Butte. The width or thickness of the sheeted zone amounts in some places to several feet, but the average thickness of the ore is between 6 and 10 inches. This blanket ledge is cut by a few faults, with throws up to 8 feet. No sulphide ore was found. GOLDFIELD-BELMONT MINE. The Goldfield-Belmont mine lies half a mile northwest of the summit of Black Butte, in ground formerly owned by the Vernal Mining Company. The Vernal workings, from which lessees took some ore in the early days of the district, are about 750 feet north of the present Goldfield-Belmont shaft. Very little ore had been shipped from the new workings up to the end of 1905. At the time of second visit in 1908 all work had been abandoned. 248 THE GEOLOGY AND ORE DEPOSITS OF GOLDFIELD, NEVADA. Open cut A general plan of the development of the mine is shown in figure 33. There is a main ver- tical shaft with levels at 62 and 150 feet below the surface. There are also some shallow shafts and irregular drifts above the 62-foot level. Whether the workings were carried deeper after 1905 is not known. The country rock of the mine is a fine-grained andesite which is considerably altered and is usually soft. The ledge is a broad zone of partly sheeted and partly irregularly fissured and shattered rock of not very prominent outcrop. The strike is approximately north-south and the general dip about 40° W. There are no definite walls to the ledge as a whole, although an approximate hanging wall is defined by a zone in which the andesite is very soft and is in some places sheared to the consistency of gouge. Such ore as has been found was between the 62-foot level and the surface. On that level, on the foot-wall side of the ledge, is a vein of soft, sugary, white quartz carrying small quanti- ties of f amatinite, gold telluride, and pyrite. Within this soft material are fragments of quartz and a silicified rhyolite. Much of the firm quartz in this part of the ledge has a porous texture and appears to be in part pseudomorphous after, or to have incrusted, some mineral which has been carried away in solution. Some of the vein material has a green tint, due to the presence of scales of sericite. On the 150-foot level the ledge, about 40 feet in greatest width, is a zone of irregular white stringers in fine- textured, partly silicified andesite. The gen- eral structure, unlike that of other deposits *? seen in the Goldfield district, might be char- acterized as a stringer lode. The irregular stringers or veinlets fill fissures up to 4 inches in width. The vein material is a fine-grained mixture of quartz and kaolinite, grading in some places from soft kaolinite to nearly pure hard quartz. Pyrite, the only sulphide found on the 150-foot level, occurs in the veinlets and in the altered andesite. Many of the small vugs in the veinlets contain gypsum, F.guke 33-Plan of the workings of the Coldfield-Belmoit mine. gome of which jg intergrown with pyrjte. The ledge material as seen on the 150-foot level shows at least two periods of Assuring and veining, which are distinguishable on structural grounds, although not by the nature of their products. No ore had been found on the 150-foot level to the end of 1905. The chief features of scientific interest in the mine are (1) the occurrence of distinct fissure fillings; (2) the unusual character of the vein material, much of which is a porcelain-like aggregate of quartz and kaolinite; and (3) the occurrence of gypsum with pyrite below the belt of oxidation. The sugar quartz of the upper level was doubtless originally a mass of stringers carrying quartz and kaolinite. With the removal of some of the kaolinite and perhaps other constitu- ents the resulting porous mass was crushed to its present condition. Alunite has not been seen in the few thin sections studied, but is probably not entirely absent from the altered andesitic country rock. DAISY MINE. The Goldfield Daisy Mining Syndicate owns the three Daisy claims along the crest of McMahon Ridge, north of Diamondfield. A general plan and a longitudinal projection of the workings are shown in figure 34. In all, the property had produced about $60,000 gross up to July, 1908. The country rock of the Daisy is the Milltown andesite. Four general ledges are recog- nized, namely, the North, Middle, South, and Fault "veins." The general courses of these are shown in figure 34. They are not continuous, at least in outcrop, but are marked by bunches of ledge matter along zones of fissuring. The so-called Fault vein strikes northeast and dips 55° N"W. It is probably the same as the Belmont ledge. Most of the ore hitherto shipped from 200 FEET I MINES OF THE MAMONDFIELD GROUP. 249 ^ toplitz shaft a d m i II DETCH 8 BREWER, Sf U A/0./ SH^ET £ - DETCH Q BREWER. "=1 N0.2 SHAET DAtsr SHAFT CAMP SHAFT C c o H c a z > 3) H o > XI O (_ rn o H O z GRAHAM SHAFT BEESLEV SHAFT 250 THE GEOLOGY AND ORE DEPOSITS OF GOLDFIELD, NEVADA. the Daisy has been oxidized material from this "Fault vein." According to Mr. C. W. Geddes, the superintendent, the ore from this pay shoot averaged about 5 ounces of gold and 3 ounces of silver to the ton. No work was in progress on this ledge in 1908, and the old Daisy shaft was not in a condition to give safe access to the levels. West of the old shaft the main work on the Daisy No. 1 claim has been on the Middle ledge, which is fairly distinct at the surface up to the highest point on the ridge. Here all the andesite between the courses of the two ledges is intensely silicified and at the surface forms a single broad mass of ledge matter. The main Daisy shaft (originally the Truett lease shaft) was 400 feet deep at the time of visit, in July, 1908, with crosscuts running south to the Middle ledge on the 300-foot and 400-foot levels. This lies about 80 feet south of the shaft on the 300-foot level and dips about 65° S. It is a broad soft zone of crushed andesite, showing much less silicification than the typical ledges in the dacite near Goldfield. The material apparently is not heavily mineralized, pyrite being the only sulphide seen. According to Mr. Geddes the average value of this shoot for a width of 5 feet is $50 per ton. The pay shoot on the 400-foot level is of the same general character. On both levels the soft ore-bearing zone is apparently on the foot-wall side of the main ledge, or zone of most intense silicification. A crosscut was being run at the time of visit to cut the North ledge on the 400-foot level. The country rock of the 300-foot and 400-foot levels is an andesitic breccia, part of the Milltown andesite volcanic complex. West of the company workings, on the Daisy No. 1 claim, the Morrison and Toplitz leases were being worked in 1908. The Morrison shaft at that time was 370 feet deep, with a crosscut from the bottom 225 feet to the south. The rock exposed in this crosscut is altered and pyritized andesite and andesitic breccia, containing streaks and bunches of oxidized ledge matter but no ore. The Toplitz shaft, about 700 feet west of the Morrison, was down 250 feet. A streak of good oxidized ore up to a foot in width was being stoped near the 200-foot level. This was a mere streak in a great oxidized siliceous ledge fully 100 feet wide. The ore showed free gold, cerargyrite, and specks of an undecomposed gray telluride. JUMBO EXTENSION (GOLD COIN) MINE. The Gold Coin claim of the Jumbo Extension Mining Company's ground, on the south slope of McMahon Ridge, and south of the Daisy mine, was being worked by lessees in 1905. At the time of visit, in November, the shaft was 150 feet deep with 3 levels. It is sunk on a lodelike, nearly east-west ledge from 2 to 3 feet in width, which is probably the "South vein" of the Daisy. Down to the 100-foot level the ledge dips 75° N; but south of that level the dip is apparently in the other direction, although too little work had been done on the 150-foot level to establish the position of the ledge. The country rock is andesite. Most of the ore shipped prior to 1906 was partly or wholly oxidized and came from small stopes above the 100-foot level. It consists of cryptocrystalline quartz, formed by replacement of andesite, associated with limonite. Within the quartz are specks of a dark-gray telluride of gold, associated with native gold and microscopic crystals of alunite. In the limonitic part of the ore are native gold and cerargyrite associated with a yellow-green ferric tellurite. Some of the ore contains an unusually large proportion of silver, assay certificates in the possession of the lessees showing in one case 48.2 ounces of gold and 88.1 ounces of silver per ton; in another case 814.65 ounces of gold and 579.85 ounces of silver. Presumably, therefore, the dark telluride is argentiferous as well as auriferous, for most of the unoxidized ore contains no other mineral likely to yield much silver, although a few specks of what appeared to be famatinite were noted above the 100-foot level. The 150-foot level, as developed at the end of 1905, showed practically no ledge matter and no ore. No work was in progress in 1908. MINES OF THE DIAMONDFIELD GEOUP. 251 TRIANGLE MINE. The Triangle workings are immediately northwest of the Gold Coin, and appear to be on the same ledge. The shaft at the end of 1905 was 100 feet deep with 3 levels. The strike of the ledge in the Triangle workings is N. 50° W. The dip is northeast and, although variable, approximates to 75°. The country rock is andesite. The ledge is a well-defined plate of silicified andesite generally from 1 to 2 feet in width or thickness. A little oxidized ore has been shipped from the 40-foot and 70-foot levels, but the ledge as exposed on the 100-foot level in 1905 contained only low-grade pyritic material, none of which, in all probability, was worth more than $30 a ton. No work was in progress in 1908. GREAT BEND MINE. On the Great Bend claim, which adjoins the Daisy No. 1 on the west, the principal work in progress in 1908 was on the Loftus & Davis lease, on the westward continuation of the Daisy ledge zone. An inclined shaft had been sunk 300 feet on the ledge at a 65° angle, and some good ore has been stoped from very soft pay shoots resembling that of the Daisy. The ore consists of tiny stringers and bunches of quartz in alunitized andesite, the whole being as a rule soft enough to pick. Most of the ore has come from the hanging-wall side of the ledge, but some bunches have been found next to the foot wall. The best ore shows small crystals of pyrite and sphaler- ite, with specks of a telluride in a nearly white, shattered, alunitic matrix which can be crumbled between the fingers. Firm masses of flinty ledge matter, such as are common in the mines near Goldfield, do not occur, apparently, in the Daisy and Great Bend ores, which are prevailingly soft structureless masses and have evidently undergone comparatively recent crushing. A new vertical shaft was being sunk just south of the incline in the summer of 1908. INDEX. A. Page. Acknowledgments to those aiding 13-14 Adams mine, description of 239 Alaskite, age of 35 character and distribution of 33. 87 geology of 34 intrusion of 27. 37 petrography of 33-34 vie w of 34. 40 Albite, occurrence and character of 108 Alkali Springs, water from 143 water from, analysis of 143 Alteration. See Metamorphism. Alum, occurrence and character of 108 Alunite, association of, with kaolinite 192 association of, with ores 132-133, 189, 199. 201 formation of 30. 38, 132. 191-192, 195 occurrence and character of 108, 129-133, 107 Alunite, Nev., rocks at 199 Alunitic veins, type of 199 Alunitized rocks, area of 193 area of, figure showing 177 photomicrographs of 178, 184 production of 170 Amphibole, occurrence and character of 108 Andesine, occurrence of 108 Andesite, age of 104 alteration of 182 photomicrograph of 178 breccia of 05 correlation of 102-104 dikes of 65 ledges in 151*150 ores in 31, 103 veins in, photomicrographs showing 150 See also Milltown andesite; Chispa andesite. Anorthite, occurrence of 120 Apatite, occurrence of 108 Arnett, W. D., & Co., analyses by Ki7 Atlanta group, mines of 242 Augite, occurrence and character of ION Azurite, occurrence and character of 108 B. Bacon, R. F., on fumarole gases 190 Ball, S. H., correlation by 92-93 on erosion of region 87, 88 on Funeral Mountains 98-99 on pre-Oambrian rocks 86 on Siebert Lake beds 98-99 Banner Mountain, rocks of and near 27, 28, 33, 38-39, 43, 44, 76-77, 88, 152, 163 rocks on, view of 152 Barite, occurrence and character of 108, 127-128 Basalt, alteration of 194 character and distribution of 54 Beaman, W. M., work of 13 Becker, G. F., on Nevada rocks 102 Bibliography of region 24-26 Biotite, occurrence and character of 108 Bishop Creek, Cal., power from 142 Bismite, analysis of 122 occurrence and character of 108, 121-123 crystals of, figure showing 123 Tage. Bismuthinite, occurrence and character of 108, 111-112 synthesis of 112 Black Butte, ores at 31 rocks of and near 16, 33, 43, 45, 48, 56, 60, 70-71 , 73, 151-152 photomicrograph of 62 view of 138 Black Butte mine, description of 246-247 ledge in 246 section of, figure showing 152 plan of, figure showing 246 Blackcap Mountain, rocks of and near 30,47,53,61,71,72,73,74,151 rocks on, view of 152 Blue Bull mine, description of 243-244 ores of 172,244 silver in 172 Bonanzas, occurrence of 159-160 Bosqui, F. L., combination mill devised by 143 Butler, J. L., gold discoveries by 16 Bytownite. occurrence of 108 C. Calcite, occurrence and character of 108, 126 California, sulphuric acid in springs in 191 Cambrian shale, character and distribution of 32-33 geologic relations of 32, 34 views of 34, 46 Campbell, M. R., on lake sediments 100 Capitalization, inflation in 19 Cerargyrite, occurrence and character of 108, 119-120 Chalcantliite. occurrence and character of 108,129,171 Chalcopyrite, occurrence and character of 10S,113,166 Chispa andesite, character and distribution of 28-29,64 petrography of 04-65 Chispa Hills, rocks of 01,04 Chlorite, occurrence of 108 Cinnabar, occurrence of 108,113 Climate, Tertiary, description of 100-107 Codd lease, description of 241 Collins, E. A., on Combination mine 167,171 on occurrence of chalcopyrite 113,106 Columbia, rocks near 38,39,41,42,43,44,55,58,151 water of 143 Columbia Mountain, gold on 17 rocks of 27-34, 38, 41-49, 53,55, 58,70-77,88, 152,183 views of 34,46 view from 137 description of 137 view of 34 Columbia Mountain fault, figure showing 82 location and character of 82-83 relation of, to deposits 201 Columnar sections, figures showing 90,91 Combination Fraction mine, description of 241-242 Combination mill, ore treatment in 143-145 Combination mine, geology of 211 glory hole in 160 . vie w of : 160 history of 209-210 location of 17 mining costs at 141 ledges of 211-213 figures showing 211,212 253 254 INDEX. Page. Combination mine, ores of 31, 170, 171, 172-173, 214-2] 6 ores of, photomicrographs of 104, 16S treatment of 143-145 pay shoots in 159,213-214 plates showing 154 production of 210 rocks in 58-59 section of, plate showing 154 water supply of 143 water in -. 187,216 workings of 18,22,210 plate showing 154,210 Commonwealth mine, description of 245 Comstock lode, production from 16 Conqueror mine, description of 238-239 section at, figure showing 82 Consolidated Red Top lease, description of 224 Constabulary, organization of 21 Copper, occurrence of 108, 111 Correlation, discussion of 91-101 methods of 91-92 Country rock, effect of, on pay shoots 103 Cretaceous time, events in 87 Cuprite, sulphur near 109-110, 175 I). Dacile, alteration of 176-177 alteration of, photomicrograph showing 178 results of, analyses of 179, 181 description of 176-182 diagram showing 181 analyses of 55, 56, 64, 94, 179, 181 assays of 114 character and distribution of 54-55, 79-81 correlation of 94-95 distribution of, map showing 80 geology of 58-61 inclusions in 55,207 intrusion of 88-89 ledges in 151, 155-156 ores in 31, 158, 163 analyses of 167 petrography of 55 relations of 63-64, 79-81 veins in, photomicrographs showing 156 views of 150, 156 Dacite vitrophyre, analyses of 61. 64, 94 character and distribution of 61, 81-82 correlation of 94-95 eruption of 88-89 ledges in 151 petrography of 61-63 photomicrographs of 62 relations of 63-64, 84 Daisy mine, description of : 248-250 discovery of 22 rocks in 53 workings of 137, 248 figure showing 249 Dall, W. H., fossils determined by 102 Datums, description of 92 Deposition, stages of i 195-190 See also Ores. Depth, relation of, to ores 173-174, 200 Depth, original, of ore deposits 174-175. 193 Deville, St. Clair, experiments of 195 Deville and Leblanc, on volcanic gases 180. 189 Diamondfield, rocks at and near 43, 45, 47, 48, 53, 56, 78, 152 view of 138 Diamondfield group, mines of 135 mines of, descriptions of 2 16-251 ores of 173 silver in 166,171 Diamond Peak, altitude of 15 rocks of 57. 00 Diaspore, occurrence and character of 108, 124-125 Page. Dikes, andesites, character and distribution of 65 Domical , use of word 27 Durdenite, occurrence and character of 108, 17S E. Edgar & Carr, analysis by 220 Eldorado limestone, occurrence and character of 86-87 Electric power, use and cost of 142 Emmons, W. II., on Mira Mountain 75 work of 13 Emmonsite, occurrence and character of 108, 171 Enargite, analyses of 118, 119 occurrence and character of 108, 117-118 Engineers' lease, description of 232-233 ores in 22, 165, 170, 232-233 Enstatite, occurrence and character of 108 Epidote, occurrence and character of 108,126-127 Erosion, amount of 174-175 differences in 16 results of 27, 79, 87 Eruptive sequence , description of 105-106 Esmeralda formation , age of 102 character and distribution of 97 Espina breccia , character and distribution of 2S, 30, 69 correlation of 69 ledges in 151 Espina Hill , rocks on 58 F. Famatinite, analyses of 118-119 occurrence and character of 108, 118 Faulting, effects of 101-162 occurrence and character of 83-85, 161-162 relation of, to ores 196, 201 Field work, nature of 13 Fissuring, nature of 157, 194, 196 relation of . to pay shoots 160-161 Five Friends lease , description of 222-223 workings of, figures showing 223 Florence-Goldfield Mining Co. , mines of , description of 225-234 Florence Hill , view from 136 view from , description of 136-137 view of 136 description of 135-136 Florence mine, faulting in 162,227 geology of 226-227 figure showing 226 history of 225-226 ledge in 227-228 section of. figure showing 152 view of 160 mill of 145 ores of 31, 166, 170, 225, 229-230 photomicrographs of 104, 108 pay shoots in 159, 228-229 section of, figure showing 154 rocks of 59 stope in, view of 160 water in : 230 workings of 226 plate showing 226 Formations, sequence of 27-30 Fossils, lack of 91-92, 101-102 Frances lease, production of 20 Freight, rates for 18, 147, 148 Fumaroles. sulphuric acid in 1S9 G. Galena, occurrence and character of 108, 112, 166 Garrey, G. II.. work of 13, 113 Geikie, A., on fumarole gases 190 Geographic names, application of 20 Geologic history, outline of 86-91 Geologic maps of district 32, Pocket. Geologic names, derivation of 26 INDEX. 255 rage. Gold, occurrence and character of 108, 110-111 production of 23-24, 145 Gold Bar mine, description of 242-243 ores of 173, 243 plan of, figure showing 243 rocks of - - - 59 Gold Bar Fraction mine, shaft sinking at. cost of 142 Gold Coin mine, description of 250 Goldfield, history of 16-23 location of I5 location of, map showing 15 view of 46 description of 135 Goldfleld-Belmont mine, description of 247-248 ores of 171-172,248 plan of, figure showing 248 veins in 248 photomicrographs showing 156 Goldfield CI Mill Co., mill of 146 Goldfield Consolidated Mine Co., mines of, descriptions of 202-224 ore treatment plan of 14" organization of 20 plant of 146 report of 200 Goldfield dome, formation of 70, 84-85 structure of 76-85 Goldfield group, mines of 135 Goldfield Hills, rocks of 72, 151 Goldfieklite, analyses of 116-117 occurrence and character of 108. 116-117 Goldfield Merger Mines Co., mines of, descriptions of 239-241 organization of 22. 239 Gold Sovereign Mine, rocks of 42 Gold Wedge claim, description of 241 workings of, plates showing 206 Gouge, formation of 156 Granite. See Alaskite. Great Bend mine, description of 251 Greenawalt, J. E., mill designed by 146 Gypsum, occurrence and character of 108, 128, 167 U. Hague, Arnold, on lake sediments 96 Hague, Arnold, and Iddings, J. P., on Nevada rocks 102 Halotrichite, occurrence and character of 108, 129, 171 Hayes-Monnette lease, ores of 172 production of 18, 20, 205 stope in 1 59 vie w of 160 Hazcl-Goldfield lease, description of 224 Hematite, figure showing 124 occurrence and character of 108, 123-124 Henderson, H. P., on ore in latite lt>3 on sphalerite 112 Highgrading, prevalence of 19 Hill, R. T., on alunite rocks 199 Hillebrand, W. F., work of 63, 110, 115, 133-134, 165 Historical geology, outline of 86-91 Hornblende, occurrence and character of 108 Hornblende-biotite andesite, analyses of 52 petrography of 52-53 Hornblende-pyroxene andesite, analyses of 50-51 petrography of 48-51 Humboldt group, correlation of 104-105 Hypersthene, occurrence and character of 108 Iddings, J. P., on plagioclase 48 Iddings, J. P., and Hague, Arnold, on Nevada rocks 102 Igneous rocks, classification of 36 See also Prelacustrine rocks. Indian Springs, water from 143 J. January mine, geology of 217 history of 216 ledge of - 217-218 Page. January mine, ores of 31, 219 ores of, photomicrographs of 164, 168 pay shoots in 218-219 rocks of 58 section of, plate showing 152 water in 220 analysis of 220 workings of 142, 217 plate showing 152, 210 Jarosite, occurrence and character of 108, 133, 171 Jasperoid, description of 32 Jumbo Extension Mining Co.'s mines, descriptions of 241, 250 Jumbo mine, history of 220-221 ledge in 221 ores of 222 pay shoots of 159, 221-222 production of 18, 221 veins in, photomicrographs showing 156 workings of 20441, 221 K. Kalinite, occurrence and character of 108 Kaolinite, association of, with alunite 192 occurrence and character of 108, 127, 167 Kendall mines, description of 237-238 ores of 170, 171 , 238 rocks in 41-42, 46, 237 view of 138 workings of 237 figure showing 237 Kendall Mountain, rocks near 43,44,47,53,151 Kendall tuff, character and distribution of 28-29, 41-43, 78 eruption of 88 relations of 83-84 Kewanas mine, description of 239 King, Clarence, on age of Nevada ranges 35 on Great Basin rocks 87 on lavas 102-103 on Pahute lake sediments 95-96, 100, 101 on Tertiary climate 106 King, L. M., analysis by 167 Knowlton, F. II., fossils determined by 102 L. Labor, troubles with 18, 19, 20-22 Labradorite, occurrence and character of 109 Lacustrine sediments, age of 104 character and distribution of 36, 66-69, 100-101 correlation of 95-101 Lahontan, Lake, climate of 107 correlation of 105 Lake beds, datum marked by 92 deposition of 89 Laguna mine, development of 18, 20 Lake, Tertiary, character of 89 Latite, alteration of 182 anal ysis of 40 character and distribution of 38-39, 78 correlation of 92 eruption of 88 ores in 163, 200 petrography of 39^1 relation of ledges to 155 relations of 83 view of 152 Lavas, succession of 105-106 succession of, figure showing 106 Lease blocks, map showing '. 136 Leasing, practice of 17 Leblancand Deville, on volcanic gases 186,189 Ledges, composition of 155-157 definition of. 150 dip of 152-153, 200 distribution 150-152, 201 plate showing 151. pocket. pay shoots in 150, 158. 200 persistency of 200 resemblance of, to fissure veins 150 256 INDEX. Page. Ledges, shape of 153-155 shape of, figures showing 152-154 strike of ". . 152 structure of 155-157 photomicrographs showing 156 type of 199 Lida, waterfrom 142-143 Limonite, occurrence and character of 109. 1 25-12(1 Lincoln, F. C, on fumarole gases 1S9-190 Lindgren, W., on lake sediments 9(i. 101 on occurrence of anhydrite 191 Literature, review of 24-26 Lithology , correlation by 92 Litigation, avoidance of 23 Little Florence lease, description of 233 ores of. 170, 233 pay shoots of. 159, 233 production of 22, 233 workings of 142,233 Location of district 14 map showing 15 Lone Star group, description of 244-245 Louderback, G. D., on erosion 88 on lake sediments 96 M. McMahon Ridge, rocks of 84 Magma, water in 198-199 Magmatic water, nature of 190 Magnetite, occurrence and character of 109 Malachite, occurrence and character of 109 Malpais basalt, analyses of 72. 73 character and distribution of 28.30, 72 correlation of 105 extension of 90 petrography of 72-74 Malpais Mesa, rocks of 71 . 72 rocks of. photomicrograph of 62 seepage from 188 view of 136 description of 135 Manhattan district, boom in 18 Map of district Pocket. Map, geologic, of district 32, pocket. Marcasite, occurrence and character of 109. 114-115 Marsh, William, gold discovered by 17 Massicot, occurrence and character of 109, 123 Mauzelius, Robert, work of 63 Meda Pass, rocks in and near 65.67.70,175 Meda rhyolite, character and distribution of 28-29, 65 intrusion of 89 petrography of 65 Melanterite, occurrence and character of 109, 128-129. 171 Metamorphism, cause of 27 knobs due to '. 1 6. 1 50 view of 150 processes of 176, 186 results of 27 photomicrographs showing 178 types of 176 Mills, construction of 145 ore treatment in 1 44 Milltown, rocks near ■. 151 Milltown andesite, character and distribution of 28-29. 47, 79 correlation of 93-94 eruption of 88 ores in 31 . 152, 163 petrography of 47-53 view of 150 See also Andesite. Mineralogy of district 108-134 Minerals, paragenesis of 169 Mines, detailed descriptions of 202-251 distribution of 135-144 shafts of. depths of 141-142 list of 138-141 water in 187-188 character of 188 Page. Mines, workings of, plate showing 136 Mining, costs of 141-142 hisl ory of '. 16-23 power for 142 Mira basalt, character and distribution of 28-29,66,69 petrography of 69 Mira Mountain, rocks of 69, 75, 175 Mohawk mine, development of 18,20,22 faulting in 161 figure showing 162 geology of 206-207 latite under, relation of ledges to 155 leases on, production of 20 ledges of 207-208 sections of, figures showing 153,206 mining costs in 141 ores of 18, 167, 169, 172 174,200,208-209 analyses of 167 pay shoots in 208-209 plan of, figures showing 206 production of 204. 205 rocks of 55, 58-59 workings of 200,205 Mohawk - Red Top lease, description of 224 plan of. figure showing 224 Montezuma, location of 14 Montezuma Peak, rocks of 68, 98 Morena rhyolite. character and distribution of 28-29,46,78 correlation of 93 intrusion of 88 petrography of 46 view of 46 Morena Ridge, rocks of 29,46 view from 138 description of 137 Morris, II. ('., on occurrence of sulphur 109 Muscovite, occurrence and character of 109, 127 Mushett lease, description of 223-224 ores of 165, 170, 173,223 plan of, figure showing 223 Myers Mountain, rocks of and near 30,53,61,65,66.67,72,73,84 N. National Museum, Goldfield rocks in 14 Nevada, bibliography of 24-25 columnar section of, figure showing 91 correlation of 93 mining in 16 Nevada Goldfields Reduction Co.. mill of 145 Nomenclature, determination of 26 O. Oligoclase, occurrence of 109 Olivine, occurrence and character of 109 Open shop, maintenance of 22 Ore deposition, solutions in 185-186 Ores, age of 175 alunite and, association of 30, 132-133, 189, 199, 201 areal variations in 172-173, 201 character of 30-31 climate and, relations of . 197 deposition of 31, 195-196 deposits of, genesis of 189-200 depth and, relation of 173-174,200 minerals in 30-31 original depth of 174-175 paragenesis of 169-170, 195-196 photomicrographs of 168 relation of. to country rock 163 shipment of 143, 146 structures of. plates showing 1(54, 166 tenor of 17, 171-172 treatment of 143-149 costs of 143 figure showing 144 See also Pay shoots; Sulphide ores; Oxidized ores. INDEX. 257 Page. Orthoclase, occurrence and character of 109, 126 Oxidation, depth of 188 solfatarism and, results of 193-195 Oxidized ores, character of 31, 170-171 minerals in 31 See also Ores. P. Pahute Lake, age of 101 datum marked by 92, 101 situation and extent of 95, 100-101 Paleontologic evidence, scantiness of 91-92, 101-102 Paleozoic time, events in 80-88 Palmer, Chase, on goldfieldite 116-117 work of 14 Paragenesis, discussion of 169-170, 195-196 Patrick claim, workings on 244-245 Patrick lease, production of 17 Pay shoots, distribution of 158 relation of, to country rock 163 to depth 173-174 to Assuring 160-161 to ledges 150, 158 shape of 158-160 plate showing 152, 154 similarity of, to barren matter 158 See also Ores. Petzite, occurrence and character of 109 Pocahontas well, flow of 187 Polybasite, occurrence of 109, 116 Population, data on 14, 18, 19, 23 Portland mine, description of 245 rocks of 54 Postlacustrine rocks, character and distribution of 70-74 Postlacustrine time, events in 89-91 Power, kinds and costs of 142 Pozo Canyon, rocks in 29,66,70,85 water from 142, 187 Pozo formation, age of 175 character and distribution of 28, 70 correlation of 71 deposition of 90 Preble Mountain, altitude of 15 rocks of and near 29, 30, 47, 50, 58, 60, 63, 151-152 photomicrograph of 62 Prelacustrine rocks, correlation of 92-95 description of 36-74 Prelacustrine time, events in 88-89 sequence of 36 Pre-Tertiary rocks, description of 32-35 Production, data on 23-24, 145 Propylitic rocks, character of 176 Prospect Mountain limestone, occurrence and character of 86-87 Proustite, occurrence of 109, 116 Pyrite, assay of 114 occurrence and character of 109, 113-114 oxidation of, sulphuric acid from 191-193 Pyroxene, occurrence and character of 109 Pyroxene andesite, derivation of 48 petrography of 52 Q- Quartz, alteration of rocks to 176 occurrence and character of 109, 120-121, 166-167 phenocrysts of, figure showing 121 Quartzite mine, ores of 171 Quaternary deposits, character and distribution of 75 R. Kabbit Spring, rocks at 71 water from 143 Rabbit Spring formation, character and distribution of 28, 30, 71 correlation of 105 deposition of 90 Railways, access by 14, 18, 22 Red King claim, discovery on 22 Red Top mine, development of 20 Page. Red Top mine, discovery of 18 geology of 203 history of 202 ledge in 203-204 mining costs in 141 pay shoots in 204 plan and section of, plate showing 202 ores of 170 photomicrograph of 164 workings of 202 Reilly lease, description of 230-232 ores of 171, 172,231-232 pay shoot of 159, 231 section of, figure showing 154 production of 17, 230 Retinite, analysis of 64 Rhyolite, alteration of 182-185 ledges in 156-157 ores in 163 See also Meda rhyolite; Sandstone rhyolite; Morena rhyolite; Spearhead rhyolite; Vindicator rhyolite. Rhyolite, altered, analyses of 183 photomicrograph showing 184 Rickard, T. A., on mills 143-146 on highgrading 19 Rocks, sequence of 27-30 Rogers Syndicate lease, description of 233-234 ores of 170, 173, 233. 234 production of 22 rocks of 59, 233-234 Rutile, occurrence and character of 109, 124 S. St. Ives mine, description of 240-241 plan of, figure showing 240 production of 22, 240 Sampling, cost of 149 Sandstorm mine, description of 235-236 ores of 18, 170, 236 rocks of 44 view of 138 workings of 137,235 Sandstorm rhyolite, character and distribution of 28, 43-44, 77-78 correlation of 93 eruption of 88 petrography of 44-46 Sanidine, occurrence and character of 126 Scapolite, occurrence and character of 109 Schajier, W. T., on bismite 122-123 work of 14, 111, 115, 131, 133 Secondary enrichment, inadequacy of 191-193, 195 Sections, geologic, plate showing 76 Sericite, occurrence and character of 127, 167 Serpentine, occurrence and character of 109 Sharwood, W. J., on minerals 110,116 Sheeted structure, occurrence of J 56 plate showing 156 Shoshone Lake, existence of 104-105 Siebert formation, character and distribution of. . 28,66,68,84,89.97,175 Siebert tuff, correlation of 36, 68, 94,98 deposition of 68 lithology of 66-68 relations of 84 water in 187 Silver, occurrence of 31, 166, 171-172 production of 23 Simmerone mine, description of 244 Sinclair, W. J., fossils determined by 96,101 Smelting, costs of 148-149 Smith. D. T. , on lake sediments 96 Solfatarism. oxidation and, results of 193-195 Solutions, ore-depositing, character of 185-186, 191-197 source of 197-198 Spearhead Point, rocks of 67, 70 Spearhead rhyolite, character and distribution of 28, 30, 71 correlation of 105 79145— No. 66—09- -17 258 INDEX. Page. Spearhead rhyolite, extension of 90 use of, for building 71 Sphalerite, occurrence and character of 109,112-113,166 Springs, sulphuric acid in . . 191 Spurr, J. E., correlation by 92,94.105 on beds at Furnace Creek i 99-100 on Goldfield ores 171 on lake sediments 96-97, 102, 105 on lava sequence 105-106 on Nevada rocks 92-95, 97, 102, 103 on pre-Cambrian rocks 86 on Siebert tuff 97 on Tonopah rocks 103 on Tonopah underground temperature 198 work of 17 Stealing, prevalence of 18-19 Steiger, George, analyses by 50, 52, 56, 61 , 63, 73 work of 14, 130 Stimler, Harry, gold discovered by 17 Stokes, H. N., on mar^asi.te 115 Stratigraphy , columnar sections showing 90,91 outline of 27-30 Structure, description of 27,76-85 Sullivan, E. C, analysis by 41 Sulphide ores, character of 30-31,165-169 minerals in . . .>* 30 See also Ores. Sulphur, occurrence and character of 109 Sulphuric acid, source of 189-195 Sweeney lease, production of 17 T. Talc, so-called , nature of 167 Tellurides, occurrence and character of 109,110,115-116,166 Tellurite, occurrence and character of 109,123,171 Tennantite, composition of 118 Tertiary rocks, sequence of 27-30 subdivision of 36 Tertiary time, climate in 106-107 events in 88-91 Tetrahedrite, composition of 118 Texas, sulphuric acid in springs in 191 Titani te, occurrence and character of 109 Tognoni Springs, rocks near 45,53,54,55,57,58,60,65,81,152 sulphur near 109 Tonopah, dacitefrom, analyses of 94 discoveries at 16 rocks at 103 Topography, description of 14-16, 150 Page. Triangle mine, description of 251 Truckee group, character and distribution of 95-90 correlation of loi Tuff, petrography of , 53 Turner, H. YV.. on Esmeralda formation 97 Unconformity, datum marked by 92 United States Government, investigation by 21 V. Van Hise, C. R., on fumarole gases 190 on solfatarism 193 Velvet mine, description of 241 production of 22,241 Victor mine, description of 242-243 ore of 173,243 plan of, figure showing 243 Vindicator Mountain, faults near 84 rocks of 27-34, 38-39, 43-18, 72, 74, 76-77, 88, 152, 176, 182 Vindicator rhyolite, alunitization of, photomicrograph showing. 178, 184 character and distribution of 28, 37-38, 76-77 correlation of 92 eruption of 88 petrography of 38 Vogt, J. H. L., on alunite 132-133 Volcanic ash, quarry in 63 Volcanic rocks, photomicrographs of 62 Volcanism, disappearance of 198-199 relation of, to mineralizing solutions 197 Volcanoes, prevalence of, in lacustrine epoch 89 Von Schulz & Low, analyses by 169 W. Wages, scale of 18-19, 21 Washington, H. S., on derivation of pyroxene andesites 48 Water, supply of 142-143 Water, magmatic, nature of 190 Water, meteoric, relation of, to mineral solutions 197-198 Water, underground, character of 188 depth of. 187 White Rock shaft, water in 187 Yellow Tiger mine, rocks of 39, 64, 79 Z. Zircon, occurrence of 109 Zoisite, occurrence of 109 u DEPARTMENT OF THE INTERIOR UNITED STATES GEOLOGICAL SURVEY GEORGE OTIS SMITH, DIRECTOR Professional Paper 67 LANDSLIDES IX THE SAN JUAN MOUNTAINS, COLORADO IXCLUDIXG A CONSIDERATION OF THEIR CAUSES AND THEIR CLASSIFICATION BY ERNEST HOWE WASHINGTON GOVERNMENT PRINTING OFFICE 1909 DEPARTMENT OF THE INTERIOR UNITED STATES GEOLOGICAL SURVEY GEORGE OTIS SMITH, DIRECTOR Profp:ssional Paper 67 LANDSLIDES IV THE SAN JUAN MOUNTAINS, COLORADO INCLUDING A CONSIDERATION OF THEIR CAUSES AND THEIR CLASSIFICATION BY ERNEST HOWE WASHINGTON GOVERNMENT PRINTING OFFICE 1909 CONTENTS. Page. Introduction 7 Geographic features 7 Location and limits 7 Topography 8 Relief 8 Drainage 8 Culture 8 Outline of geology 8 Sedimentary rocks 9 Volcanic rocks 10 Structure : 10 Physiography 10 Topographic expression 11 Description of landslides 12 Recent landslides 13 Cimarron landslide 13 Position of region 13 General description of the scene 14 Character of movement 14 Cause of slide 14 Movement of soil on C. H. C. Hill, Rico 15 Landslip of Ute Creek 1G Older landslides 10 Telluride landslide area east of Lake Fork of San Miguel River 17 Silver Mountain landslide 17 Yellow Mountain landslide 19 Sheep Mountain slide 20 Discussion of Telluride landslides 20 Rico landslides 21 North side of Horse Gulch 21 South side of Horse Gulch 22 Ridge between Burnett and Sulphur creeks 23 Landslip Mountain 24 C. H. C. Hill 24 Comments on Rico landslides 24 Silverton landslides 25 Red Mountain landslide district 25 Ironton Park area 25 Red Mountain area 26 Landslide area south of Sheep Mountain 27 Landslides of Canyon Creek, Needle Mountains 28 Landslides of Hermosa Creek 29 Landslides in vicinity of Ouray 29 Landslide of the Amphitheater, Portland Creek 30 Canyon Creek slides 30 Pleistocene landslides 30 Rock streams 31 Rock stream of Pierson Basin 32 Character of material composing the stream 32 Form in which the material lies 32 Source of material 32 3 CONTENTS. Rock streams — Continued . Page. Silver Basin rock streams 33 Rock Stream in Imogene Basin 34 Rock Stream of American Basin 35 Cleveland Gulch 3(i Engineer Mountain rock streams 37 Graysill Mountain 38 Sliderock Ridge 39 Conditions favorable to landslides of trachytic rock in Engineer Mountain quadrangle 40 Slumgullion mud flow 40 Classification of landslides and their causes 41 Heim's observations in the Alps 41 Penck's views 43 Nature and causes of San Juan landslides 44 Physical condition of rocks affected by landslides 44 Sedimentary rocks 44 Volcanic rocks 45 Structural conditions 45 Topographic conditions 46 External causes 46 Summary 49 Nature and causes of rock streams 49 Important features of rock streams 49 Elm landslide 50 Frank landslide 51 Description of the slide 51 Character of the movement 52 Cause of the slide 52 Origin and nature of the San Juan rock streams 52 Classification of San Juan landslides 54 Index 57 ILLUSTRATIONS. Page. Plate I. Cliffs of San Juan tuff-agglomerate 12 II. South Lookout Peak, Telluride quadrangle 12 III. Cimarron landslide 14 IV. Tree split by landslide movement, C. H. C. Hill 16 V. Southern part of Silver Mountain landslide area 18 VI. A, Ridge southeast of Expectation Mountain; B, South face of Landslip Mountain 24 VII. A, Trench between landslide blocks near head of Mineral Creek; B, Landslides below Red Mountain No. 2 26 VIII. A, Red Mountain landslide district; B, Landslides southeast of Corkscrew Gulch 28 IX. A, Landslide on south side of Dexter Creek; B, Northwest end of Sneffels Range 30 X. Rock streams in Pierson Basin 32 XI. Rock stream in Pierson Basin 32 XII. Rock streams at head of Silver Basin 34 XIII. A, Rock stream in lower portion of Silver Basin; B, Rock stream at head of Silver Basin 34 XIV. A, Rock stream in lower portion of Silver Basin; B, Rock stream in I mogene Basin 34 XV. A, Talus and rock stream at head of American Basin; B, Rock stream in American Basin 36 XVI. A, Rock stream north of Greenhalgh Mountain; B, Rock streams in Hurricane Basin 36 XVII. Landslide in Cleveland Gulch 36 XVIII. A, Engineer Mountain from the north; B, Engineer Mountain from the east 38 XIX. A, Engineer Mountain from the west; B, Sliderock Ridge 38 XX. A, Rock stream at head of Bear Creek, Silverton quadrangle; B, Slumgullion mud flow 50 Figure 1. Map of Silver Mountain landslide district 17 2. Map of Silver and Pierson basins 33 3. Diagram illustrating influence of snow banks in formation of talus accumulations 36 4. Diagram illustrating theoretical conditions controlling landslide action 43 5 LANDSLIDES IN THE SAN JUAN MOUNTAINS, COLORADO, INCLUDING A CON- SIDERATION OF THEIR CAUSES AND THEIR CLASSIFICATION. By Ernest Howe. INTRODUCTION. In a region whose last cycle of erosion has not yet passed beyond its youth or very early maturity, wasting of the land proceeds with the utmost activity ; the corrasive power of streams is great and the topography reaches a maximum of boldness. Probably none of the well- recognized processes of degradation is more active at this stage than that commonly known as the "landslide" or "landslip," by which greater or less masses of soil or rock are detached from steep hillsides or cliffs and slip or plunge to the valley bottoms, there to be attacked and in time removed piecemeal by the vigorous streams. Although the magnitude and fre- quency of landslides are probably greatest during youth or early maturity, sliding may continue throughout maturity in regions where the physical conditions are favorable. Such conditions appear to have persisted till recent time, if indeed they do not still exist, in the San Juan Moun- tains, where the abundance and variety of landslides represented by the fallen material are note- worthy. Many of the slides have been described in the published reports of the Survey, but the space possible to devote to them has been necessarily limited. The purpose of the pres- ent paper is to assemble all of the information at present available in regard to the landslides and their causes. Closely related to the more common landslides first observed are the remarkable rock streams that occupy so many of the cirques and high valleys; these are described in consid- erable detail, since they appear to have been heretofore unrecognized in the Rocky Mountains. After the landslides and rock streams have been described their origin and causes are dis- cussed, this discussion being preceded by a brief summary of the various views entertained concerning the subject of landslides in general. The study of the landslides described in this paper has been carried on for more than ten years in connection with the survey of the various quadrangles situated in the San Juan region. The work was under the direct charge of Mr. Whitman Cross, who, soon after its inception, recognized the important part played by landslides in the Quaternary history. The descrip- tions of most of the landslides of the Telluride and Rico districts are largely in Mr. Cross's own words. The San Juan landslides were first described in the Telluride folio, while a longer discussion of the causes and the general character of the slides appeared in the special report on the Rico Mountains in part 2 of the Twenty-first Annual Report of the Survey. To this last paper numerous references are made in the following pages. The slides in other locali- ties, as well as the rock streams, came under the writer's personal observation. GEOGRAPHIC FEATURES. LOCATION AND LIMITS. The San Juan Mountains lie in the southwestern part of Colorado. On the northwest, west, and south they are sharply bounded by the plateaus of Utah and New Mexico; the east- ern limit of the group is the broad San Luis Valley, while an indefinite line separates them from 7 8 LANDSLIDES IN THE SAN JUAN MOUNTAINS. the mountains on the north. As a matter of fact, the term San Juan is usually applied to the western portion of the group, where there are a number of important mining centers, and it is with this restricted area, roughly bounded north and east by Gunnison, Lake Fork, and San Juan rivers, that this paper deals. In addition to the central mountainous region a number of outlying groups are included in the San Juan district, such as the Mount Wilson group and the Rico (or Bear River Moun- tains, as they were named on the Hayden map), which are of especial interest on account of their numerous landslides. The La Plata Mountains, the southwestern outlyers of the San Juan, need hardly be mentioned, since no landslides of any importance have been observed among them. TOPOGRAPHY. Relief. — The topography is of almost infinite variety in different parts of the San Juan region. In the central portions the mountains are high and rugged and the valleys corre- spondingly deep and narrow, many of the streams flowing for parts of their courses through bare, rocky canyons a thousand feet or more in depth. A very large part of the central area is above timber line. To the south and southwest the mountains decrease gradually in elevation and assume gentler outlines, and no sharp line can be drawn between them and the plateaus of very moderate relief. To the northwest, on the contrary, the high mountains end abruptly and face the plateaus in a well-defined wall. Partly detached from this wall is the Mount Wilson group, a number of whose summits rival in elevation and rugged grandeur the highest peaks of the central region. The Rico Mountains are of more moderate relief , and occupy a position intermediate between the slowly descending foothills of the southwest and the abrupt mountain face of the northwest. Drainage. — Five principal streams control the drainage system of the mountains — the Gunnison, San Juan, Rio Grande, San Miguel, and Dolores. The Gunnison, San Miguel, and Dolores join Grand River, and the San Juan enters the Colorado near the head of the Grand Canyon. The Rio Grande, on the Atlantic slope of the Continental Divide, controls but a very small part of the drainage of the western San Juan Mountains. Animas River, the prin- cipal tributary of San Juan River, has a length of about 100 miles, more than one-half of which lies within the region of higher mountains, and, with its various branches, drains a large part of the area in which the landslides occur. The Uncompahgre, on the north, attains an almost equal length before it joins the Gunnison. These two streams, which rise in the elevated region between the towns of Ouray and Silverton, known as the "Red Mountain district," and flow, respectively, south and north, sharply separate the mountains to the west from the main San Juan group. It is in these western mountains, with a few notable exceptions, that nearly all the landslides described in these pages occur. The western face of these mountains is drained by Dolores River and its principal tributary, the San Miguel, near the headwaters of which are many characteristic landslides. CULTURE. The presence of a number of old mining centers, such as Silverton, Ouray, Telluride, and Rico, has had much to do with the opening of the country, so that to-day hardly any part can be considered inaccessible, notwithstanding the extremely rugged nature of the mountains. In few localities in the United States are there included in so small and easily explored an area so many features of interest to the student of geology. Railways penetrate the very heart of the mountains and wagon roads or trails lead to the most remote valleys or basins. OUTLINE OF GEOLOGY. It is unnecessary to present here an extended discussion of the geology of the San Juan region, since detailed descriptions may be found in the folios and other published reports of OUTLINE OF GEOLOGY. 9 the United States Geological Survey concerning special areas. a The following account merely summarizes the present knowledge of the region, and is intended to supply only such information as is necessary in a consideration of the landslide phenomena. Broadly considered, the mountains consist of Tertiary volcanic rocks which rest upon a truncated quaquaversal of Paleozoic and later sediments, which, in turn, he unconformably upon pre-Cambrian formations. The oldest rocks are the gneisses and schists of the Needle Mountains, which, with sediments of Algonkian age, represent part of the exposed core of the quaquaversal. The Algonkian is also exposed in the canyon of Uncompahgre River and at Rico. SEDIMENTARY ROCKS. The first rocks of Paleozoic age of which there are any records in the San Juan Mountains are quartzites of the upper Cambrian — the Ignacio quartzite — which rest unconformably upon older rocks, and in turn are followed by a stratigraphic break, above which occur shales and thin limestones and sandstones of Devonian age, known as the Elbert formation. The Ouray limestone follows this directly, and is characterized by thin-bedded limestones, calcareous shales, and sandstones near the base, and by a heavy massive limestone near the top. Fossil evidence shows that the Ouray limestone is of Devonian age in its lower part, and that an indefinite upper portion of the massive limestone layer is of Mississippian (lower Carboniferous) age. In the succeeding Molas formation, which is itself of variable thickness and apparently not always present, Pennsylvanian fossils have been found. These early Paleozoic formations have a maximum thickness of about 500 "feet, but are extremely variable, and in a few instances may lack the lowest member, the Ignacio. They are characteristically thin bedded with the exception of the uppermost cliff-forming limestone of the Ouray, and in the lower portions are of gray or buff colors, the Molas being a deep purplish red, often shown only by rounded, bare banks of crumbling shale. The Hermosa formation, which follows the Molas, marks the beginning of a long period of sedimentation in which a great series of shale, sandstone, and limestone was deposited. The Hermosa itself has a thickness of more than 2,000 feet in the Animas Valley, and there consists very largely of great massive limestones near the top and shales and sandstones in the lower portions. It is richly fossiliferous, and the fauna is characteristic of the Pennsylvanian series. On the northern side of the mountains, in the vicinity of Ouray, the formation is less thick and is generally arenaceous instead of calcareous, although thin limestones not infrequently occur. Above the Hermosa strata appears a series of reddish conglomerates, sandstones, marls, and thin limestones, separated by an unconformity from similar overlying beds in which Triassic fossils occur. These rocks occupy a much larger area than the Hermosa in the zone adjacent to the mountains, and are conspicuous in the Animas, Dolores, San Miguel, and Uncompahgre valleys. In the Rico Mountains a fauna that is related to the " Permo-Carboniferous " of the Mississippi Valley has been found in the lower portion of the reddish series, and this fossiliferous zone is called the Rico formation. It has also been identified in the Animas drainage basin, but its presence has not been recognized in the Uncompahgre Valley. The nonfossiliferous portion of the reddish beds, which rests upon the Rico formation and is limited above by unconformable Triassic strata, has been called the Cutler formation. The name Dolores has been given to the Triassic portion, which is distinguished from underlying beds not only by fossil evidence but also by an unconformity. Above the red Triassic beds come other formations that are correlated in general with the fresh-water Jurassic of other parts of Colorado, and above these comes the upper Cretaceous, from the Dakota to the uppermost and coal-bearing member of the Laramie. Below Durango the post-Laramie formation, made up of eruptive-rock debris and known as the Animas, rests upon the Laramie, and is in turn overlain by the Puerco and higher Eocene deposits. The a The followingpublicationson ttie geology of the San Juan Mountain region have been issued by the United States Geological Survey: Folios No. 57, Telluride, No. 60. La Plata; No. 120, Silverton; No. 130, Rico; No. 131, Needle Mountains; No. 153, Ouray. Geology of Rico Mountains, by Whitman Cross and A. C Spencer: Twenty-first Ann. Rept. U. S. Geol. Survey, pt. 2, 1900, pp. 7-165. 10 LANDSLIDES IN THE SAN JUAN MOUNTAINS. older Jurassic formation is the La Plata sandstone, which overlies the Dolores formation conformably. The younger Jurassic formation, the McElmo, and the succeeding Cretaceous beds are of peculiar interest because of the close relation between their physical character and the occurrence of landslides, a subject which is considered in greater detail in a later paragraph. The McElmo formation consists of thin-bedded shales and sandstones, and above the next following formation, the Dakota, is a great thickness of very fine, soft shales known as the Mancos shale. Following the Mancos is a series of friable sandstones and shales, the Mesaverde formation, and this is succeeded by the Lewis shale. At the close of Cretaceous sedimentation uplift and erosion occurred, and on the surface thus prepared the Telluride conglomerate was laid down, which is supposed to be of Eocene age. It is of variable thickness, reaching 500 feet as a maximum, coarsely conglomeratic, and of a dull reddish or pinkish color. VOLCANIC ROCKS. Resting upon either the Telluride conglomerate or the base-leveled floor below it is a very great thickness of volcanic rocks. In the central part of the mountains they completely cover the earlier sedimentary formations and have an aggregate thickness of many thousands of feet. The oldest member of the volcanic complex is the San Juan tuff, which at Ouray has a thickness of more than 3,000 feet, but elsewhere may be but a few hundred feet thick. It consists of coarse and fine-grained tuffs and agglomerates, and has a characteristic bluish color. It is usually well indurated, and in places may form bold cliffs. Succeeding the San Juan epoch came a time in which rhyolitic and andesitic magmas, together with others of intermediate composition, alternated and built up the Silverton volcanic series of flows and tuffs to an aggregate thickness of 4,000 feet or more. Above them comes the Potosi volcanic series, consisting predominantly of rhyolitic material and observed to have a thickness of more than 1,000 feet. During and after the Silverton epoch there were intervals of great erosion. The three series of lavas mentioned make up the greater part of the western San Juan Mountains. East of the Silverton quadrangle they greatly diminish in thickness and disappear under other lavas of various kinds not yet fully investigated, but known to include rhyolite, andesite, and basalt. STRUCTURE. Structurally, the most striking feature in the present attitude of the sedimentary forma- tions described, from the base of the Paleozoic upward, is their general southerly, westerly, or northerly dip away from a point in the west-central part of the San Juan Mountains. This structure is mainly the result of dynamic forces which were intensely active during three great epochs of Tertiary time, and the present elevation of the region above sea level is to be regarded as the result of numerous oscillatory movements of uplift or subsidence which have taken place since the close of the Cretaceous. In the Silverton and Rico districts, and to a minor degree elsewhere in the San Juan, extensive faulting exists. PHYSIOGRAPHY. From the preceding outline of the geology of the San Juan it will be seen that the region has had an extremely varied history, some of which, if not actually recorded in the present physiography, at least has played a part in determining the character of the topography. Broadly considered, the San Juan region is a volcanic plateau, which has been so deeply dissected that in many places the foundation rocks have been exposed, and from whose borders an unknown but probably vast amount of material has been removed. In order to understand the meaning of the present forms, it is necessary to consider briefly the late geologic history of the region beginning with the orogenic movements at the end of the Cretaceous. These movements resulted in a general doming of the 12,000 feet of Paleozoic and Mesozoic sediments about a center which was near the site of the present Needle Mountains. The erosion which followed OUTLINE OF GEOLOGY. 11 removed the entire cover from the center of the dome, exposing the hard pre-Paleozoic rocks, which resisted the continuing degredation and were preserved in a group of mountains which had a considerable boldness. The softer sediments yielded more readily and were reduced to base-level. It was upon this peneplain, now to be observed at only a few places, that the Telluride conglomerate was deposited, and later partly removed before the volcanic outbursts occurred which resulted in the burial of the central region under many thousands of feet of tuffs and lava flows. One of the features of the Tertiary volcanic eruptions was the more or less continuous erosion which took place throughout the period. There is reason to believe that in a few places this Tertiary erosion influenced to some degree that which followed the uplifting and slight tilting of the whole region at the close of volcanic activity and resulted in the development of the broader features of the present topography. Modification due to the glaciation of the region, as described later (p. 46), appears to have been comparatively slight. The western border of the plateau was attacked and practically removed, and the interior plateau was thoroughly dis- sected and given a topography bolder than that which it presents to-day. It has been shown recently a that more than one period of glaciation occurred during the glacial epoch in the San Juan Mountains. The first stage is believed to have been of somewhat greater magnitude than the second, and although the effect has been almost completely obliterated, at a few places dis- tinct evidence has been found of the modification of the preglacial topography by the first stage of glaciation. Between the first and last stages there was an interval during which considerable erosion took place. Whether or not this erosion was associated with an intermediate period of glaciation is not known ; at least no evidence has been found to indicate that glaciation occurred at that time. As a result of this vigorous revival of the streams, deep, narrow trenches were cut in the older valley floors and a more or less youthful topography was developed, the bolder outlines of which were somewhat softened by the last stage of glaciation, which has left behind the familiar U-shaped valleys and typical glacial cirques at the head of most of the streams. Except in the cirques and near the valley heads, very little actual erosion appears to have been accomplished during this last stage of glaciation. Furthermore, since the final retreat of the ice and the close of the glacial epoch, only a moderate amount of erosion has been effected by the streams; but general wasting of the land has proceeded at a more or less rapid rate in certain favored localities. Briefly summarized, the topography of the San Juan Mountains is that of a dissected and glaciated plateau of more or less horizontally bedded volcanic rocks resting upon a foundation of sedimentary rocks whose structure is complex. Near the central part of the region the vol- canic rocks only are exposed. Around the border of the mountains the inclined sedimentary rocks appear, and the conditions are those of a warped and dissected peneplain whose drainage is independent of the rock structures except in a few minor localities. The Needle Mountains, in the south-central part of the San Juan region, represent the exposed and deeply dissected core of the San Juan dome ; at a number of places on their flanks are remnants of the old, pre- Paleozoic peneplain upon which the earlier sediments were deposited. The region as a whole is still in the early stage of its maturity, certain parts having advanced farther in the cycle than others on account of the character of the rocks of which they are composed. TOPOGRAPHIC EXPRESSION. Nearly all the formations have a characteristic topographic expression due to their physical peculiarities. Certain strata are usually cliff makers; others, from their more friable nature, are seldom exposed, and where not covered by more resistant beds cause the topography to have a smooth, rolling surface. As cliff-forming rocks the upper parts of the Ouray limestone and Hermosa formation in the Animas Valley section are notable; the lower portions of the same formations, being com- posed of rather thin-bedded limestones, shales, and sandstones, occur as slopes. The 2,000 feet a Howe, Ernest, and Cross, Whitman, Glacial phenomena of the San Juan Mountains, Colorado: Bull. Geol. Soc. America, vol. 17, 1906, pp. 251-274. 12 LANDSLIDES IN THE SAN JUAN MOUNTAINS. or more of sandstones and shales represented by the Rico, Cutler, and Dolores formations may cause rough, steep slopes, or sometimes, as in the vicinity of Ouray, abrupt cliffs, while elsewhere smooth slopes may be the rule, with occasional outcropping ledges of harder rocks, the differences being due to changes in the physical character of the beds, a feature common to the Rico and the Cutler. With the exception of a few horizons of thick, massive conglomerate, these forma- tions are not strictly cliffmakers. The Elbert and Molas formations underlie, respectively, the Ouray and Hermosa, and are essentially slope-forming, the Molas especially so, as it is very seldom actually exposed and is recognized largely through the reddish color of the soil which results from its rapid weathering. Of the later formations, the La Plata and the Dakota form cliffs, but this is not as invariably true of the La Plata as it is of the Dakota, the former being sometimes extremely soft and weath- ering in smooth slopes. The Mesaverde, the youngest of the Mesozoic formations to be con- sidered, possesses a number of resistant sandstone layers, and may in places form steep cliffs. In strong contrast to the Dakota is the overlying Mancos shale, which is extremely uniform in texture and very soft and friable, forming typical rounded hills or rolling lowlands. The McElmo formation, underlying the Dakota, being composed of alternating sandstones and shales, gives less smooth slopes. As is shown later in describing the landslides, the soft, yielding nature of the clay of the Mancos is largely responsible for many of the slides of greatest magnitude. In the volcanic rocks similar conditions and contrasts exist, though in all cases to a less marked degree. Thus the tuffs correspond more or less closely to the shales of the sedimen- tary formations, and the flows to the massive cliff -forming sandstones or limestones; but the physical character of the different volcanic formations is extremely variable from place to place. The San Juan tuff may be well indurated and form such bold cliffs as occur on both sides of Canyon Creek in the neighborhood of Ouray; more frequently, however, it crumbles readily at the surface and is characterized by more or less even, smooth slopes on which there are few outcrops. Both of these features are shown in Plate I. The composite nature of the Silverton volcanic series, which succeeds the San Juan, is largely responsible for its lack of distinctive topographic expression other than steep, half- graded slopes, on many of which are found outcrops and irregular cliffs. An exception is seen in the flows of pyroxene andesite near the upper part of the Silverton volcanic series, cap- ping some of the mountain summits which form abrupt cliffs, shown in Plate II; the same is true of the flows of the Potosi volcanic series. A physical feature of most of the volcanic rocks which has influenced their topographic expression and which has an important bearing on the occurrence of landslides is their jointing, which causes otherwise massive formations to weather more readily in some places than in others; that is, a flow of massive andesite exposed in a steep-faced cliff at one locality may, a few hundred yards away, be recognized only through its debris covering an even slope. DESCRIPTION OF LANDSLIDES. So far as is known, a landslide in the act of falling has never been observed in the San Juan Mountains. One on the east side of Cimarron Creek was studied by Cross a few days after its occurrence, in 1886; incipient slides have been observed near Rico, and examples may be found at many places of accumulations of landslide debris of all ages, from the most recent to those so ancient as to be hardly recognizable. It would be well-nigh impossible to describe all the landslides that have occurred in the San Juan, and such an enumeration would probably fail to emphasize many of the important features and the differences that exist between certain slides. No one slide can be taken as typical of all; as a rule each possesses a few features peculiar to itself and many in common with others. Probably one of the most recent landslides in the region is that, already mentioned, which occurred on the eastern side of Cimarron Creek. It was, as far as is known, the first in the San Juan region to be specifically described, although references were made in the reports of U. S. GEOLOGICAL SURVEY PROFESSIONAL PAPER 67 PLATE I CLIFFS OF SAN JUAN TUFF-AGGLOMERATE. East side of Hayden Mountain near Full Moon Gulch, overlooking Ironton Park, Silverton quadrangle. U. S. GEOLOGICAL SURVEY PROFESSIONAL PAPER 67 PLATE II SOUTH LOOKOUT PEAK, TELLURIDE QUADRANGLE. The characteristic topography of an area composed of rocks of the Silverton volcanic CIMARRON LANDSLIDE. 13 the Hayden Survey to various localities "in the volcanic section where large masses of rock have fallen down, at times for several thousand feet, and are now lying immediately below the perpendicular cliff that their falling produced."0 As an introduction to the landslide phenomena of the San Juan, no better example can be found than the Cimarron slide. Its age is definitely known, and it was examined and de- scribed within a very short time after its occurrence and before any serious modification of the form of the fallen material could have taken place. The character of the local topography which existed prior to the slip is known and the direct cause of the slipping is clearly under- stood. The following account is taken, largely without change, from the contemporaneous report of Cross. RECENT LANDSLIDES. CIMARRON LANDSLIDE.6 Late in July, 1886, there appeared in the Denver papers a report that an earthquake had occurred in Cimarron Creek valley. The locality was visited shortly afterward by Professor Farnham, of the Nebraska State Normal School, and he confirmed the earlier reports in so far as they referred to the convulsion, which had affected a considerable area, but he offered no explanation of the cause of the disturbance. A few days later Whitman Cross, of the United States Geological Survey, accompanied by W. H. Jackson, a photographer of Denver, visited the scene. POSITION OF REGION. The landslide occurred on the west fork of the valley of Cimarron Creek, a tributary of Gunnison River, heading under Uncompahgre Peak. The country south of the Gunnison canyon is a well-dissected plateau, drained by the Cimarron and other north-flowing streams, between which remnants of the plateau still exist in the form of long mesas or narrow, flat- topped ridges. The capping of these mesas is a flow of massive andesite resting upon andesite tuffs, which in turn lie on the Upper Cretaceous clays and shales of the Mancos (Pierre and Fox Hills formations). The edges of the eruptive sheets are either cliffs or precipitous slopes, while from these down to the creek bottoms the shales produce more gentle but uneven, wavy descents. Parts of both shale and eruptive rocks are covered by a heavy growth of timber, but a scanty covering of sagebrush is the more general. The scene of the so-called "earthquake" was on the eastern slope of Big Cimarron Creek, near the northern end of the western arm of Trident Mesa of the Hayden map, on the shaly slopes below the eruptive sheets. The exact day on which the slide occurred is not known, but it was between the 18th and 25th of July. No one witnessed the event. The news that there had been an earthquake was first brought by a ranchman who had had cattle ranging in the disturbed region. He had gone out to round them up on the 25th, and had found some of his stock hemmed in by fallen timber — trees thrown down in all directions — and deep fissures in the ground; ridges had been thrown up, ponds filled, and the whole region showed signs of very great disturbance. The locality was described by Cross as follows: In going to the earthquake ground we followed a trail which led diagonally up the slope toward the end of the western fork of Trident Mesa. The valley is here G to 8 miles wide and the eruptive sheets of the mesa are about 1,200 feet above the stream bed, some 3 to 4 miles to the west. The surface of the long slope was undulating, with many smooth-banked drains which were crossed obliquely. Sagebrush grew thickly on the lower slopes. The banks of drains frequently exhibited outcrops of Fort Pierre shales, and the clayey soil everywhere indicated that the formation from which it was derived could not be far below the surface; indeed, slight digging in several spots brought shale or clay strata to view. A feature of this soil, derived so immediately from the Fort Pierre clays and shales, is the tendency to the formation of drought cracks during the long dry summer. These cracks are irregular in course, lacking the sharpness and curved form of ordinary mud cracks, but opening sometimes an inch or two in width, with a visible depth of nearly a foot. Their walls are crumbling. a Ann. Rept. U. S. Geol. and Geog. Survey Terr, for 1874, p. 194. b Cross, Whitman, The Cimarron landslide, July, 1886: Proc. Colorado Sci. Soc, 1886, pp. 116-126. 14 LANDSLIDES IN THE SAN JUAN MOUNTAINS. After rising some 400 to 500 feet above the creek the surface became more uneven, resembling many morainal districts, in the hillocks, with deep depressions or sinks between them. Ponds of water are common at this elevation. Such rough surfaces seem to be characteristic of the upper slopes of this region. In general, the chief topographical features of the long slopes are rounded ridges which run out from the mesa arms nearly at right angles. On reaching the crest of one of these minor ridges which runs out from about the northern point of the western arm of Trident Mesa, we found ourselves overlooking the entire area disturbed. [See PI. III.] GENERAL DESCRIPTION OP THE SCENE. From the ridge mentioned one looks into a rudely basin-shaped area, bounded by this ridge on the north, the steep mesa slopes on the east, and another ridge 2 miles to the south, while the lower or western side is open. The greater part of the basin is quite densely covered by spruce timber, with aspens here and there. The detailed topography is difficult to make out, but in general the central part is higher than the northern border along which runs one of the drainage channels. A prominent shoulder projects a short distance from the mesa, near the center of the upper basin rim. The slopes of this shoulder are very steep, but it is covered with trees. Looking into the timbered area of this basin, evidence of such disturbances as had been described was everywhere visible. In some parts nearly all trees were overturned, and in others where many stood erect, the various angles of inclination assumed by a few showed that these areas had also been affected in some degree. The nearest ground disturbed was seen to be almost at the base of the northern ridge, along a line that could be traced upward to the union with the mesa. At the head of the basin the limit of confusion seemed to follow along slightly above the foot of the mesa slope. To the south, beyond the central wooded parts of the basin, were seen bare slopes, fissured and presenting a steplike structure, as if from the dropping down of successive sections. Down- ward, i. e., to the westward, the limit of visible disturbance was reached in densely wooded tracts where the trees were all erect. Thus at a glance one saw the area affected to embrace the basin-shaped depression, while the limits were the bounding higher grounds. This area is estimated to be not less than 3 square miles in extent. CHARACTER OF MOVEMENT. The close examination showed the area disturbed to be limited, in fact, on almost the very lines seen from the first point of view. The movement was a downward sliding of the whole surface, unequal in different places, apparently greatest in the upper part, and dying out gradually as distance from the upper line increased. The upper limit of movement runs along the steep mesa slope at a present elevation of 50 to 125 feet above the basin floor. A steep surface of freshly exposed earth and shaly rock marks the line. Above are undisturbed trees, turf, or debris. At the foot of this surface is a tangle of overturned trees and bushes, half buried in loose soil and rocks. Upon the slide surface lie a few uprooted trees, or a small patch of earth which has caught halfway down. Along the upper edge are partly detached sections, with their trees inclined at various angles. The shoulder mentioned as projecting from the mesa out into the upper part of the basin has suffered on all its steep sides, as did the above slope; and the entire mass is divided into sections by fissures, so that it seems strange that all did not slip, piece by piece, to the basin below. Along the northern side, near the base of the bounding ridge, runs a more or less continuous line, which is nothing less than an anticlinal fold or plication of the surface soil or turf, caused by the lateral pressure of the downward-mov- ing mass. On the outer or northern side of this fold the bushes and trees, where such exist, are simply tipped from the vertical position, corresponding to the sharpness of the plication. They are not uprooted, and in many places this side of the little ridge is unbroken, while on the basin side the downward movement has torn away nearly all of that half. A mile below the head of the slide this lateral movement is manifested very plainly by the cracking of a grassy surface, the turf from the basin side being simply shoved sideways a foot or more over the undisturbed part on the ridge side. CAUSE OP SLIDE. Whatever the standpoint from which the scene was viewed, the uniform impression produced was to the effect that a sliding or almost a, flowing movement had taken place in which the whole area had been involved. The move- ment was clearly confined to the basin area, and had taken place upon a plane very near the surface in order to produce the complete overturning of the large trees upon such gentle slopes as were for the most part concerned. The agent through whose influence the forces of gravity were enabled to produce these results was water. Only through complete saturation of the ground by water can the degree of plasticity, evidently possessed by this moving mass, be adequately accounted for. Direct evidences of the abundant presence of water were not so plentiful as one might expect, yet they were by no means wanting. Mud streams were here and there found in which tree trunks and rocks were embedded. In some places seen by Professor Farnham there were columns and mounds of moist earth or mud pressed up through cracks by movements of some parts of the mass. As expressed by him: " In places the pressure from below has thrust up great columns of black, moist earth, the perpendicular sides of which are smooth as if turned up with a huge plow- share." (Tribune-Republican.) The upheaving force invoked by Professor Farnham to account for these columns is not needed under the explanation here adopted. As to the source from which the water needed for this saturation came, it may be said that, according to the ranch- men of the neighborhood, there were several small ponds or pools and one little " lake " in the wooded parts of the basin. >> >^ J3 JD Tl ~o 0) (/I crt rt o u 1_ to u en o c_ CIMARRON LANDSLIDE. 15 At the present time there is no free drainage channel, and ponds which will soon become swamps, and little pools, are forming on every hand; for a considerable volume of water comes into the basin from the mesa slope above. Where the shoulder which has been spoken of as projecting into the basin joins on to the mesa there is a small level spot occupied even now by a swamp. It has not been affected by this disturbance, although some of the fissures that rend the projecting point visibly approach to within a few yards. The water from this swamp drains into the basin on the north, partly by a surface rivulet, and partly issues in a strong spring now bursting out of a freshly exposed clay slope of the shoulder adjoining. The swamp lies at the level of the line of fracture on the mesa slope and 100 feet above the tangled mass of trees in the basin below. While these constant sources of water can be mentioned, it is highly probable that the thorough saturation neces- sary for such a movement of a large mass could not have been effected by the amount of water thus supplied. But according to the testimony of the ranchmen living in the Cimarron Valley, a few miles distant, nearly the whole week, July 18-25, preceding the discovery of the disturbance was characterized by very heavy thunderstorms in the valley above, and although little rain fell at the ranches it was thought at the time that much must have fallen on the mesa and adjoining valley slopes. The clouds hung especially heavy and low and persistently over the region of this slide. It seems quite probable, then, that the abundant rainfall of these days rendered highly plastic the soil already thor- oughly moistened from local sources. A small slip may have started the movement and, by removing the resistance which held another mass in place, have paved the way to a successive slipping of section after section until the higher bounding grounds were reached." Such a theory would allow a slight movement in the lower portions to lead to much greater displacements on the upper limit, and such seems to be in fact the case. That the slipping did occur in sections is shown by the appearance of ridges here and there in the midst of the area, which were plainly formed as was the one on the northern limit, described above. Again, the degree of disturbance is very different in different places. Certain areas seem to have moved but little. They are fissured, and some trees are partially overturned, while on all sides are courses within which no tree stands erect. In such a case one can readily conceive that the less disturbed mass was less plastic, per- haps situated on slightly elevated ground, and was only affected through the pressure from the moving masses on either side. All observed disturbances seem to be well explained thus. Cross's account of the Cimarron landslide has been quoted in such detail because of the light which it is able to throw upon most of the other landslides in the San Juan region, concerning which little more than the characteristic topography of the fallen material can be taken as evidence that actual landslides have occurred. Certain features of the Cimarron landslide are of especial interest. The comparatively gentle slope upon which slipping occurred, although not without precedence in regions of clay soils, is yet noteworthy. Although involving an area of no small size, the materials concerned in the slip appear to have been clearly of a surface nature; it was a soil slip rather than a land- slide, strictly speaking. Furthermore, no massive rock appears to have been involved in the slip; that is, the capping formation of andesite on the mesa was not affected. MOVEMENT OF SOIL ON C. H. C. HILL, RICO. Somewhat analogous slipping of purely surface material has been observed at a few widely separated localities in the San Juan region. Such conditions have been found on C. II. C. Hill near the town of Rico, where timbering in prospect tunnels and shafts has been twisted or crushed. Evidence of the character of this movement is well shown in a crevice which is gradu- ally opening at the upper end of C. H. C. Hill. Where most distinct this fissure occurs on a northerly slope which is rather thickly wooded, and it would scarcely be noticed except that several trees on its line have been split from the roots up to 2 or 3 feet above the ground, as shown in Plate IV. A stump of one tree cut off about 2 feet above the ground has been split open since the tree was felled, and the severed portions are now seen about 5 feet apart. The tree was known to have been cut about 1894, while the observations were made four years later. Earth has filled in between the halves of this stump and to some extent under the split trees, indicating that the movement has been gradual; it probably began, however, before the felling of the tree the stump of which has been split, for the two parts show that the tree was once cracked on the line of subsequent splitting and that this crack had been partly healed by growth. The crevice may be followed for 200 or 300 feet below the split trees by a crack in the soil, seldom open for more than 2 or 3 inches in depth, although a horse's hoof will sink a foot or more. a It is not unlikely that the drought cracks, mentioned by Cross on page 120, may have permitted surface waters to descend to lower portions of the otherwise impervious clays, thus saturating certain layers and causing them to become naturally lubricated slipping planes. — E. H. 79146—09 2 16 LANDSLIDES IN THE SAN JUAN MOUNTAINS. It is not improbable that very similar conditions may have existed in the vicinity of the Cimarron landslide for a long time previous to the actual slipping; in fact, actual fissures have been reported by ranchmen as occurring a few miles south of the site of the Cimarron landslide LANDSLIP OF UTE CREEK. During a reconnaissance trip made by Cross and the writer in 1903 in the western part of the San Cristobal quadrangle evidence was found in Ute Creek, a tributary of the Rio Grande, that a landslide intermediate in character between the Cimarron slide and that at Rico had occurred in comparatively recent times. The movement appeared to have been confined strictly to the surface material, which is that of deep soil on a steep hillside covered thickly with timber. The actual area involved was estimated at about one-fourth of a square mile, and was restricted to the upper part of the hillside near the crest of the ridge which separated Ute Creek from the stream immediately to the east. Although no trees appeared to have been actually thrown down as a result of the slip, most of them had evidently been disturbed and stood at considerable angles from the vertical; the trunks of many were buried for several feet by fine, sandy soil which stood in steep slopes in an extremely unstable condition, and although this material was dry, the horses sank into it so deeply that they were extricated with no little difficulty. The general condition of the locality suggested that a series of heavy rains might so saturate the soil as to cause a renewal of the movement with a violence comparable to that which characterized the Cimarron landslide. These slides, of which the Cimarron is the most typical example, are evidently the youngest that have been observed in the San Juan region, and their superficial nature is noteworthy when compared with the enormous quantity of material involved in many of the older landslides. In the case of the Cimarron slide it appears that little more than the surface soil took part in the movement, but notwithstanding this marked changes in the topography were brought about. These changes consisted in the complete obliteration of the older ground surface beneath a confused mingling of waste, the forms of which were unlike those produced by any other natural process. Ridges were thrown up, depressions formed, and peculiar rounded hummocks and mounds, many of which suggested morainal deposits, covered an area that had previously presented the smooth, even surface of a region far advanced in maturity. The scene of the Cimarron landslide was observed from the opposite side of the valley in the summer of 1905, nineteen years after the actual slipping, and apparently no changes had taken place in the character of the topography. It is important to note that all of the evidence obtained by Cross in his first examination seemed to show that the debris that covered the floor of the basin had not reached its position as the result of a single slip, but rather through a succession of minor slides of unknown but probably large number. OLDER LANDSLIDES. In considering slides of greater age and magnitude in other parts of the San Juan, the time of their occurrence is largely a matter of inference, as is also the character of the topography which existed before slides took place. It is probable that only slides of greater magnitude, but not necessarily covering greater area, than the Cimarron are preserved at the present time, largely because the superficial character of lesser slides could hardly produce changes that would be observable for any great length of time. Because many of the older slides were of great size and involved enormous masses of solid rock the topographic and geologic evidence of their origin is well preserved. The topographic evidence is perhaps the most striking and easily recognized, and consists of two elements — the disordered heaps of fallen material and, in most cases, the scar on the mountain side from which the material has fallen, and which for long periods remains uncovered by vegetation and is not softened by any of the processes of erosion. A third element, the path of the slide, may sometimes be recognized. In not a few cases the topographic evidence may be misleading. With greater age certain masses of land- slide debris might easily be mistaken for morainal deposits, and it is also true that vast accumu- lations of drift may, at first sight, appear to be of landslide origin. In such cases of doubt SILVER MOUNTAIN LANDSLIDE. 17 recourse must be had to strictly geologic evidence — that is, the condition and character of the material and its relations to rock in place. Fortunately in such instances the landslides, if such they be, are of considerable age and have yielded to the repeated attack of torrential streams, which have exposed to view the composition of problematical mounds and heaps of debris. In most of these the differences between the material of glacial origin and that due to landslide can be readily recognized. These differences will be brought out in later pages. TELLURIDE LANDSLIDE AREA EAST OF LAKE FORK OF SAN MIGUEL RIVER. SILVER MOUNTAIN LANDSLIDE. The largest and perhaps the best example of an area covered by old landslide material is in the Telluride quadrangle between the Lake Fork of the San Miguel and Silver Mountain. While evidence has been found, especially at Rico, of slides of much more recent occurrence, in none is there presented a more complete line of evidence pointing toward the landslide origin of the debris, while the topographic form of the fallen material seems to be especially characteristic of a large number of landslide areas. The cause of the slide and the topog- raphy that existed previous to the sliding are probably better under- stood than in many instances of younger slides. The area covered by the debris of this landslide, which may, for con- venience, be referred to as the Silver Mountain slide, is about 10 square miles. It almost covers the broad bench that lies between the bases of Silver Mountain, Bald Mountain, and Gold Hill, on the east, and the canyon of the Lake or South Fork of San Miguel River, on the west ; it reaches within 1 mile of the Tel- luride Fork of the San Miguel on the north and within nearly the same distance of Howard Fork on the south. The topographic as well 3 E& Landslide Pleistocene Eocene Cretaceous Jurassic Itfneous rocKs iGlactalhnH/rferJConqlomeratcUShalesantt', (Sandstones) \ deposit /\ •> /' sanastones v Contour interval 500 feet Figure 1. — Map of Silver Mountain landslide district, Telluride quadrangle, showing the landslide and its topographic and geologic relations. as the geologic relations of the landslide area are shown on the map forming figure 1 . The following account is taken from the detailed description which appeared in the Telluride folio:" The topography within this area is that most naturally characteristic of a surface made up of landslide blocks. In fig. 10 [PI. V] is illustrated the configuration of the southern part of the landslide mass as seen from the western side of Lake Fork, looking toward Silver Mountain. There are a great number of knolls, longitudinal ridges, or benches, the majority of which have steep outer slopes, with trenches, or depressions, often containing a stagnant pool, back of them, on the mountain side, and the drainage is extremely irregular. While this area is large it exhibits relatively few exposures in which the attitude of the bedded formations there present can be clearly seen. On the upper limit, north of Ophir Needles, a small slide block of San Juan tuff, etc., a Telluride folio (No. 57), Geol. Atlas U. S., U. S. Geol. Survey, 1899, p. 11. 18 LANDSLIDES IN THE SAN JUAN MOUNTAINS. interrupts the ledge of the San Miguel [Telluride] formation between the levels 10,500 and 11,000 feet.' In this block the tuffs strike somewhat west of north and dip 21° E. This seems to have been a recent slide of the lower few hundred feet of the San Juan formation. The trail from the Gold King road to Ophir Loop passes at the base of this slide block, over a bench on which there is a small lake. At about this level to the north is a much more extensive bench with two ponds, which are shown upon the map. These benches are typical of many in this slide area, having a steep outer slope in which the crushed San Juan tuff does not form a distinct ledge outcrop, though its presence is plain. From the south branch of Turkey Creek around Bald Mountain to Prospect Creek the slide line is not sharply indi- cated, except that above it are seen nearly continuous outcrops of the San Juan tuff in normal position and below it the confused landslide topography begins. On the west slope of Gold Hill, however, lateral ridges, with a trench back of them, are found in several places near the cliffs of the San Juan. In some of these ridges the outcrops show the San Juan tuff dipping at various decided angles toward Gold Hill. One of these is below the point where the normal cliff of the San Miguel [Telluride] formation reappears. Rhyolite debris is scattered over the upper part of the slide area, but was not found in mass, as east of Trout Lake. San Juan tuff and agglomerate forms most of the knolls and benches down to a level somewhat below 10,500 feet. In several outcrops below the Gold King road dips of as much as 60°, generally somewhat north of east, were observed. The most regular element in the composition of this area seems to be the presence of the San Miguel [Telluride] formation in a broad band extending from Prospect Creek to Turkey Creek. The lower line of the slide and the line between the San Miguel [Telluride] and San Juan formations can be pretty clearly made out within this space. South of the south branch of Turkey Creek no regular relation between San Juan and San Miguel [Telluride] outcrops can be made out. Above the Currency mine is a knoll of San Miguel [Telluride] conglomerate with irregular eastward dip, the reddish western face being visible miles away. This is the oval mass represented upon the map. All around it is debris of the San Juan tuff. The Currency mine, a little below this exposure, has a shaft 200 feet deep sunk through San Juan and San Miguel [Telluride] formations to the Mancos shales. It lies within the landslide area, immediately below the knoll of the San Miguel [Telluride] conglomerate. This shaft was sunk on an ore-bearing vein which was traced down to the Mancos shale, though much fractured and dislocated. Drifts from the shaft and various surface workings have shown the broken-up character of the San Juan formation about this point and have furnished evidence of slipping still in progress. Thus, tunnels running nearly parallel to the general slope of the country in the vicinity exhibit a crushing of the timbers, especially on the upper or mountain side. The Currency shaft could not be kept vertical, the bottom moving down the slope and with a twist indicating some undulation in the shale surface upon which the sliding mass rests. A short dis- tance from the Currency shaft a prospect tunnel in broken-up San Juan material was run into an older tunnel whose timbers were all crushed together, the entrance to this old working having been entirely obliterated by recent eliding. Mancos shale was also found here, much nearer the surface than in the Currency shaft. The attempts to find a continuous ore body in the Currency mine resulted in the discovery of sufficient ore in small stringers and disconnected masses to induce the erection of a steam hoisting plant and other mine machinery, but the total irregularity in dislocation and the cumulative evidence that the whole mass was slide material caused the abandonment of further exploration. There are some indications of secondary deposition of ore on the shale contact, but the thoroughly crushed condition of vein and rock matter and the likelihood of some ore being dragged into the zones of movement make positive statements on this point unwarrantable. Material representing the San Miguel [Telluride] conglomerate, much broken up, occupied some 15 feet above the shale in the Currency shaft. In some levels and tunnels a greater thickness was found, but in both this and the San Juan tuffs, etc., the normal bedded structure could seldom be made out, and the innumerable fracture planes running in all directions plainly showed the cause of the existing conditions. It seems probable that the Currency mine is in a slide block which may have originally been much more solid than at present, and that secondary sliding has increased the dislocation upon the fractures produced in the fall, and perhaps created new ones. . Below the Currency mine the confused mingling of San Juan, Telluride, and Mancos shale extends down to Lake Fork. At one point the wagon road close by the stream passes over the loose black shale 500 feet below the Dakota ledge, over which it has been pushed by the sliding mass of the other formations. This shale and that of other exposures higher on the slope is thought to belong to the great furrow of this soft material which must have been thrown up by the plowing force of the original slide. There is much landslide material in disconnected masses on the slope west of Ophir Needles, and the southern border for the landslide mass, as shown on the map, is thus a necessary generalization. From the extent and observed structure of this, the largest landslide of the Telluride quadrangle, it is supposed to be the product of several slides from the mountain face, which were perhaps contemporaneous or nearly so, and that ever since the primary slide there has been continual slipping of minor masses within the area. The disinte- gration of the whole mass is going on under the active operation of a geological agent of no mean importance in such a region . It now seems probable that the Silver Mountain landslide and other large ones of the region antedate in part the recent glaciation, and ma}' owe their origin to the conditions prevailing at the close of an earlier and more extensive ice occupation of the San Juan Mountains. Evidence of such earlier glaciation has been found on the north and south slopes of the mountains, and it YELLOW MOUNTAIN LANDSLIDE. 19 must have been general.0 Whatever the time of the initial fall may have been it is clear that practically continuous movement of the older slide material has been in progress and glacial gravels have been involved in these recent movements. An arm of the landslide area cuts across the trend of the moraine on the east side of the Lake Fork, below the Currency mine, and here slipping is manifestly in progress. YELLOW MOUNTAIN LANDSLIDE. Another landslide, covering an area of about 3 square miles, took place on the southwest face of Yellow Mountain, just east of Trout Lake. It is believed that the lake owes its origin to a dam of slide material at its lower end now almost completely eroded away. This landslide, whose general characteristics are essentially the same as those of the Silver Mountain slip, presents to-day abundant evidence of its origin. As in the case of the Silver Mountain slide, the bedded volcanics rested on Mancos shale, which gave way under their superincumbent load, permitting a large block of the volcanics to slip about 1,000 feet vertically below their former position. A noteworthy feature of this landslide is that a very large part, if not all, of the fallen mate- rial slipped at one time, and the present accumulation is not the result of component slips; the mass was naturally much fractured, but was not broken up into many small blocks. There appear to be two fairly distinct parts to this landslide area. The upper part is made up entirely of the Potosi volcanic series, and in all the distinct outcrops the lamination dips toward the east or northeast at various angles, in many places exceeding 30°. The apex of this somewhat pyramidal rhyolite mass is very near the crest of the main ridge from which the slide has occurred, and which is made up of tuff-like flow breccias at the very base of the Potosi volcanic series. This apparently rests on the San Juan tuff, the members of the Silverton vol- canic series being absent at this point, so that there is now no lamellar rhyolite, such as that of the shoulder described, on the ridge above it. The base of the rhyolite in the landslide mass is seen at 1,000 feet below the apex of the mass, and under it comes San Juan tuff, etc., as in the normal section. These variations are in general accompanied by changes in the dip and strike of the rhyolite bands, but not always. Fracture planes, marking lines of dislocation, traverse the mass in several directions. Below the line of rhyolite is a broken, wooded country with numerous knobs or huge blocks of San Juan tuff and other formations, and occasionally one of rhyolite. The structure in these exposures is very variable, in no two being quite alike, and the conclusion is that they are not outcrops of rock in normal relation to the rhyolite above. The second part of the landslide extends from the rhyolite down to Trout Lake. Its topography is very irregular. There are numerous hillocks and short ridges covered by aspens, with sink holes on the upper side of many of them, and the drainage winds intricately around among them. Large blocks of Telluride conglomerate are numerous, and surfaces of consider- able extent show only debris of this formation, but still lower may be found areas equally characterized by the San Juan tuff. Some of the larger knolls have ledgolike outcrops, showing that either the San Juan or the Telluride is present in mass. The dips vary, and in the strike of a ledge of one of these are knolls exhibiting the other rocks. No outcrops of shales could be found down to the level of Trout Lake directly east of Roger and Minnie creeks, but farther south, in Groundhog Gulch, Mancos shale was observed (at an altitude of about 10,800 feet) beneath Telluride conglomerate, both formations dipping at angles of 45° or more to the east. The shale at this point was much crushed. The breaking up or fracturing of the fallen material, either at the time of the fall or subsequent to it, appears to have been of varying intensity, depending on the character of the different formations involved and their relative positions with respect to one another. Thus the uppermost rhyolite, when compared with the underlying tuffs and Telluride conglomerate, suffered relatively little, although much fractured. The tuffs and conglomerates appear to have been very completely fractured, while the Mancos shale underlying them now has no recognizable structure, and in fact forms a very small part of the a Howe, Ernest, and Cross, Whitman, Glacial phenomena of the San Juan Mountains, Colorado: Bull. Geol. Soc. America, vol. 17, 1906, p. 251. 20 LANDSLIDES IN THE SAN JUAN MOUNTAINS. slide area. On the geologic map of the Telluride folio it has been possible to indicate these differences, the lower portion being represented as landslide, while the upper part is shown as "Potosi rhyolitic series" and "Intermediate series" (i. e., Silverton volcanic series), surrounded by landslide boundaries. SHEEP MOUNTAIN SLIDE. Another slide in which, although comparatively small, it was possible to differentiate the formations and to show them on the map occurred at the western end of Sheep Mountain. It was described in the Telluride folio a as follows : The main part of this mass is Potosi rhyolite, of two lamellar flows, with the usual flow breccia below them. Under this rhyolite comes some very much crushed San Juan tuff in a thin band less than 200 feet thick at its maximum. Bowlders and pebbles of quartzite and granite found at its base at a few spots indicate a disintegrated layer of the San Miguel [Telluride] conglomerate. Across the southern end of the rhyolite flows runs a cross fracture, beyond which a chaotic agglomerate of pyroxene andesite appears, seeming to belong to the Intermediate member of the volcanic complex [Silverton volcanic series]. The lower boundary of this mass is obscure, in a heavy growth of spruce forest, but shale exposures at several points, and the smooth character of the slopes below, indicate that the map is here nearly correct. The laminated flows dip toward Sheep Mountain, but not regularly, since cross fractures plainly show the mass to be much broken up. On the west face of Sheep Mountain above this slide is a depression drained by two shallow ravines, shown on the map, and one can not avoid the conclusion that the depression marks the place from which the slide block came. If the original mass included much of the San Juan, that material was so ground up by friction that little of it now remains. i This block shows that at the time of its fall the Potosi series extended out along the crest from San Miguel Peak to Sheep Mountain. It is not now present at the extremity of Sheep Mountain, and only small remnants may be still found in the points above 13,000 feet near San Miguel Peak. • DISCUSSION OF TELLURIDE LANDSLIDES. The slides in the vicinity of Telluride that have been described bring out a number of features which are recognized as typical of most landslides but which were not shown in the Cimarron slip! In all the cases mentioned the conditions that existed before the landslide were those of massive volcanic rocks resting upon porous conglomerates which, in turn, lay upon extremely soft shales. Combined with a bold topography these relations presented conditions of great instability for the overlying heavy beds. The fallen material now exposed to view shows that enormous masses of solid rock slipped downward many hundreds of feet, sometimes in large masses which became more or less completely fractured during their descent; at other times repeated slides of smaller masses of equally solid rock resulted in the displacement of an even greater amount of material. The character of these movements is clearly brought out by the field evidence. The material in the upper part of the Yellow Mountain slide retains sufficient homogeneity, notwith- standing numerous fissures, to permit it to be mapped as a part of the Potosi volcanic series, separated from the surrounding rock in place by landslide rather than fault boundaries. The relations of the mass clearly indicate that it came to its position through superficial slipping rather than faulting, but in some respects they are not unlike those of a faulted block. ■ Similar conditions existed at the western end of Sheep Mountain, but between Silver Moun- tain and the Lake Fork, and also in the lower part of the Yellow Mountain landslide, the material of the different formations is so completely mixed and fractured that it is impossible to differ- entiate any single formation and the areas have been mapped simply as landslide. In most cases where blocks of fallen material can be recognized, and where the formations themselves originally possessed distinct bedding lines, the stratification is found to dip at steep angles into the mass of the hill from which the material fell. This is a feature characteristic of a large number of landslides in this and other regions where the nature of the fallen material ie such as to prevent excessive fracturing and the fall itself has not been of the utmost violence.6 This backward tilting of the fallen blocks can naturally be recognized only in cases where the a Geol. Atlas U. S., folio 57, U. S. Geol. Survey, 1899, p. 11. 6 Cf. ideal section through Lookout Mountain, Washington, in Russell, I. C, Topographic fractures due to landslides: Pop. Sci. Monthly, vol. 53, 1898, p. 487. EICO LANDSLIDES. 21 rocks themselves are plainly stratified. Undoubtedly it always exists at the initial stages of the slipping, but if the slope upon which the material is descending is very steep a reversal of the movement may be looked for, and in certain instances to be cited later this seems to have taken place; the natural result is a more complete shattering of the debris. For this reason the slides of the Telluride area can not be regarded as having been of the utmost violence, the movement having been essentially slumping on an enormous scale; and in this respect they resemble most of the landslides in other regions. RICO LANDSLIDES. Few localities have experienced as many landslides as have occurred in the territory immedi- ately adjoining the town of Rico. The area covered by the fallen material probably exceeds that in which solid rock in place is exposed, and it is included within a circle about 4 miles in diameter, with its center about one-half mile west of Rico. In comparison with the great slides in the vicinity of Telluride, those at Rico appear to have been much more superficial. At no place has any slip occurred in which was involved as large a single mass as that west of Yellow Mountain ; but rather, many distinct slides took place, which, through disintegration by various agencies, have come to grade into one another and thus form a confused mantle of fragmental material covering the solid rock. Much prospecting has been done in the Rico Mountains, and in many places the failure to recognize the purely superficial nature of the ground in which exploration was being carried on has resulted in the useless expenditure of time and money. In the recent survey of the region the significance of the large waste-covered areas was soon recognized, and a study of the land- slide phenomena became of prime importance, not only on account of their bearing upon local economic conditions, but also because many structural features of the geology were obscured by superficial material, and in the efforts to distinguish between exposures of rock in place and those forming a part of landslide masses a very thorough knowledge was gained of the varied characteristics of the waste covering the hillsides. Inasmuch as the landslide areas of the Rico region have been described in detail by Cross,0 it seems only necessary to summarize here the more important features. Three localities are of especial interest in the Rico region as illustrating the most note- worthy features of the landslide action in this area. These are the north and south sides of Horse Gulch, the ridge between Burnett and Sulphur creeks, and Landslip Mountain. NORTH SIDE OF HORSE GULCH. One of the most typical landslips of the region, and one whose topographic details are most characteristic, is that which lies on the north side of Horse Gulch. The area covered by the fallen material is about three-quarters of a square mile. The greater part of this area is now covered by vegetation, and direct evidence as to the character or attitude of the forma- tions beneath it is found only in local outcrops, small slides of recent date within the main area, prospect holes, or the topographic details found by observation to be characteristic of landslide surfaces. Along the bank of a ravine on the eastern border the loose material has in several places been washed away, revealing outcrops of greenish sandstones of the Her- mosa. These exposures belong to different blocks, some of them 50 feet in visible length, the strike and dip changing abruptly from block to block and never corresponding to the normal structure found on the east side of the ravine. Some of the blocks show a nearly vertical dip, while in others the beds are inclined 40° or more, usually down the slope. In about the middle of the landslide area and 400 or 500 feet above Horse Creek is a bare spot which is due to the recent falling away of a part of what was doubtless a wooded or grassy slope like that above and on either side. By this secondary slip a jumble of forma- tions has been exposed winch is probably typical of the relations existing in much of the slide a Cross, Whitman, and Spencer, A. C, Geology of the Rico Mountains, Colorado: Twenty-first Ann. Rept. C S. Geol. Survey, pt. 2, 1900, pp. 129-149. 22 LANDSLIDES IN THE SAN JUAN MOUNTAINS. mass. The exposure reveals ledges of much shattered sandstone, shale, and porphyry dip- ping in most widely varying directions; the change from one block to another is abruptly marked by a fracture or crushed zone, and the original relation of the various formations to one another can not be definitely ascertained. Porphyry predominates along a zone at the top of this exposure, and the first inference is that there is a sheet of porphyry here which may be traced for some distance, but, in fact, several textural phases of porphyry are here mingled, and it is questionable whether any one sheet can be identified at this locality. This exposure well illustrates the manner in which the material of the slide area gradu- ally disintegrates and eventually loses all distinctive features. Through the shattered con- dition of such landslide masses they become saturated with water, and at times different portions slump away and break up into masses of loose, thoroughly broken slide material; each fresh break presents a point of attack for the elements, and the destruction of the shattered mass goes on more rapidly. Marked knolls and ridges with fractured and irregular rock outcrops, back of which are the V-shaped trenches marking the fracture lines of individual slide blocks, characterize the central part of this landslide area. The trenches are almost always partly filled in, and fresh fractures in the soil are rare ; they are so independent of any drainage system that their origin seems to be open to no question. Although somewhat obscured by talus and fine debris at its base, the slide extends prob- ably to the creek level; its upper limit is under a cliff of red sandstone of the Dolores forma- tion at about 11,400 feet. Chaotic slide blocks, which are rounded and more or less grassed over, cease at about 11,000 feet, and between this and the solid cliff line is a small area of more angular blocks of red sandstone and porphyry in which there is often a dip toward the mountain. Each of these blocks is clearly marked, and fissures of dislocation between them are like open faults with a measurable throw of 50 feet or less. Some of these blocks have fallen from the cliff in comparatively recent times, and fissures which may serve as boundary cracks of future slips are to be found here and there in the cliff. A feature characteristic of this and other landslide areas in the Rico region is the attitude of the fallen blocks mentioned in the preceding account. The blocks at the head of the slide near the upper cliff, which appear to have fallen in relatively recent times and have moved com- paratively short distances, dip into the mountain or cliff from which they fell, while the strata of the older blocks lower down dip in the opposite direction — that is, down the slope, more or less parallel to its direction. These different attitudes of the fallen blocks have a direct bear- ing upon the theory of the movement of landslide masses and are discussed later (p. 53). SOUTH SIDE OF HOUSE GULCH. An area of more than 1 square mile is covered by landslide material on the south side of Horse Gulch. For a distance of about 2 miles it extends from the crest of Darling Ridge, which is the southern boundary of the gulch, to the level of the creek. The topographic fea- tures of the slope are typical of fallen landslide material and consist of the usual blocks, trenches, and irregular mounds and heaps of debris of varying composition. The formations of the crest of the ridge are obviously not derived by sliding from any other source, but they are in many places so shattered by prominent fractures running in all directions, and the blocks bounded by these fractures are so plainly dislocated superficially, that the whole mass may be considered as broken and not strictly in place. At the eastern end of the landslide area, on the crest of Darling Ridge, is exposed a massive stock of monzonite which has evidently undergone much shattering. The surface of the ground is characterized by a great number of mounds and hollows with curving ravines and irregular depressions between them belonging to no drainage system. The rock of the knobs is often fresh but much shattered, and the hollows between are rounded by the gravel of disintegration washed into them. This topographic detail, while on the top of the ridge, is similar to that on the land- slide slopes. Below these pinnacles on the slope to Horse Creek are some other knobs of monzonite, and the surface is covered by talus and landslide heaps nearly all the way to the creek bed." " Cross, Whitman, and Spencer, A. C, op. cit., p. 133. RICO LANDSLIDES. 23 The slope below the monzonite of the crest is mainly covered with large and small land- slide blocks, intact or in process of dissolution, derived from the Hermosa and Rico forma- tions and from several porphyry sheets, so that geologic boundaries showing the original rela- tions can not be traced; the mingling is not as in ordinary talus below cliffs. A knob or ledge at one point is perhaps Avholly of one rock, or of sandstone with a porphyry sheet, while in an adjacent knoll monzonite is equally pronounced. At the level of Horse Creek considerable mining operations have been carried on in what is now known to be a large landslide mass, or, rather, a series of landslide blocks. RIDGE BETWEEN BURNETT AND SULPHUR CREEKS. One of the largest landslide areas of the district is the broad ridge between Burnett and Sulphur creeks extending from about 11,000 feet on the crest of the ridge down to Dolores River, some 2,400 feet below, and covering more than 2 square miles of territory. In its pres- ent condition this area affords few localities where landslide phenomena are clearly exhibited, but by comparison with other areas the landslide evidence is convincing, and the ridge is of much interest as illustrating an advanced stage in the history of landslide areas, when the ordinary agencies of degradation have nearly completed their work of effacing the scars caused by the successive slips, leaving little evidence in the smooth slopes of the confusion existing beneath. The upper limit of this area is sharply defined by a line crossing the crest of the ridge in a north-south direction, which may be followed into Sulphur Gulch on the north; on other sides the landslide area has no well-defined boundaries. According to Cross, the southwest slope of the ridge is smooth and rounded, entirely cov- ered by grass or timber growth, and contrasts very markedly with the opposite side of Burnett Gulch, with its prominent cliffs of stratified rocks and porphyries. The examination of this southwest slope shows no outcrops of rock in. place except at the end of the ridge and very near the bed of Burnett Creek, nor are there the usual broken ledges characteristic of land- slide blocks. Instead of this, the few exposures where the character of the underlying mate- rials can be seen reveal detrital matter of the texture of ordinary wash or slide rock, while none of the prospect tunnels, of which there are several in the vicinity, has penetrated to solid rock. The topographic detail of this slope, however, is most suggestive of landslides. There are many projecting knolls and local benches, irregular transverse depressions belonging to no drainage system, and general lack of persistent drainage channels. On the northeast side of the ridge there is a steep wooded slope, upon which at several places there are very distinct trenches running horizontally or obliquely along the hillsides, with sharp, furrow-like ridges on the outer side. Some of these are so pronounced that they would seem to belong to rather recent slips. Outcrops of rock are rare and are always of much broken and dislocated material. On or near the crest of the ridge leading from Expectation Mountain are the most dis- tinct evidences of landslides. For several hundred feet below the upper limit of the area the broad top of the ridge is characterized by rounded knolls with flat or shallow depressions between them. More or less distinct ledge outcrops of sandstone, shale, or porphyry are common on these knolls, but the greatest irregularity of dip and strike is found, and the most prominent beds are clearly not continuous. The character of this part of the ridge is represented in Plate VI, A. The dips observed in the mounds and knolls shown in this view are abnormal in most cases, being at steep angles either down the ridge or to the east. No geologic boundaries can be traced across this obscure area, and there is conclusive evi- dence that the debris of the smooth slope is not ordinary slide or talus. From the known structure of adjacent areas it is plain that the massive limestones of the Carboniferous, an intrusive porphyry sheet, and the grits of the lower Hermosa must underlie this mantle of loose material. 24 LANDSLIDES IN THE SAN JUAN MOUNTAINS. LANDSLIP MOUNTAIN. One of the most perfectly preserved minor landslides of the Rico district is that which took place on the southwest slope of a mountain on the divide south of Burnett Creek, for which the name Landslip Mountain was proposed by Cross. On the north, under the summit, are cliffs of reddish Hermosa beds containing several sheets of intrusive porphyry and dikes. The summit itself has a porphyry cap, and other small bodies occur on the ridge to the west. From the summit of the mountain to the saddle on the west, some 300 feet lower, and from this line southward nearly to the bed of the north fork of Wild Cat Creek, the surface is covered by landslide debris. None is found on the north side of the divide. In Plate VI, B, may be seen the nature of the extreme upper part of this slide. The light-colored rock is largely porphyry, but there is also much red sandstone and shale, causing darker shades here and there. It is plain that the larger part of the porphyry belongs to the capping sheet of the moun- tain, but lower sheets undoubtedly appear. The occurrence of the porphyry in sheet form hi the sedimentary section is visible in many places, but accurate correlation of the shattered and disconnected exposures is impossible. The talus, from the disintegrating slide blocks, streams down the slope, but masses of considerable size occur at intervals far down in the timber. C. H. C. HILL. One other landslide area in the Rico region deserves to be mentioned. It is the western slope of Telescope Mountain, locally known as C. H. C. Hill, and lies just north of the town of Rico. The details of this landslide area were studied with special care on account of the extensive prospecting that has been carried on within its boundaries, but it is unnecessary here to enter into a specific description of its topographic features, since they differ in no way from those of the other areas already described. The occurrence in one part of this area of a local soil slip, still in progress, has been previously mentioned. Probably the most important result of the landslides on this slope was the damming of Dolores River. The fallen material, which covers an area of about lj square miles, extends from an elevation of 11,800 feet near the summit of Telescope Mountain to the level of Dolores River at 9,000 feet. Just above the point where the landslide debris reaches the level of the river the stream flows in an open valley with a broad flood plain, but below this point the Dolores enters a narrow gorge, bounded on the west by cliffs of limestone and sandstone and on the east by a steep bank made up of limestone, sandstone, and conglomerate in a wholly con- fused mass of coarse slide. It seems necessary to assume that the present alluvial flat mentioned is due to the dam- ming of the river by the slide. It is probable that before the slide occurred the valley bottom was broad and of very gentle grade along the stretch now occupied by the slide bench. From a point 1A miles north of the gorge the river has a fall of but 50 feet, but on its entrance into the gorge it falls 150 feet in two-thirds of a mile. COMMENTS ON RICO LANDSLIDES. Certain features of the Rico landslides deserve special emphasis. The feature most obvious to one who has studied the enormous landslides of the Telluride region is the comparatively superficial character of most of the Rico slides. Probably without exception the present topographic features are due to successive minor slips rather than to any one large fall com- parable to that of Yellow Mountain. Most of the rocks involved are sediments with sheets of intrusive porphyry, but in some instances massive stock rocks have also been affected, as in the upper part of the ridge between Burnett and Sulphur creeks, and on Darling Ridge, where the rocks in place are much shattered. One of the most noteworthy characteristics of the Rico landslides, and one that Cross considers to have a direct bearing upon their origin, is the extremely shattered condition of fallen blocks, whether of sedimentary or igneous material. The short distance that these blocks have moved would seem ij indicate that their shattered condition can not be attrib- U. S. GEOLOGICAL SURVEY PROFESSIONAL PAPER 67 PLATE VI A. LOOKING DOWN LANDSLIDE RIDGE SOUTHEAST OF EXPECTATION MOUNTAIN, RICO QUADRANGLE. Shows the landslide topography at the stage when it has become almost obliterated by disintegration of the shattered blocks. B. SOUTH FACE OF LANDSLIP MOUNTAIN, RICO QUADRANGLE. Shows several landslide blocks, mainly of porphyry, in process of disintegration by atmospheric agencies. SILVEETON LANDSLIDES. 25 uted to their fall alone, but must have existed previous to the beginning of the landslide movement, while the rocks were still in place. This is certainly so in the case of Darling Ridge and the ridge between Sulphur and Burnett creeks." With the exception of a few minor outlying areas, all of the landslides have occurred near the center of the Rico dome. The character of this domelike uplift or qu aqua vers al, now thoroughly dissected, is clearly shown in the attitude of the sedimentary beds near Rico, where dips vary from 10° to 25°. In practically all cases the fracturing and subsequent movement of the landslide blocks have been at sharp angles to, or across, the stratification planes of the sedimentary rocks, rather than parallel to these planes; in other words, nearly all of the slides have occurred near the center of the dissected dome and not on its flanks, the only noteworthy exception being the Landslip Mountain area. The significance of this domical structure in relation to the landslide phenomena of the Rico region is discussed at greater length later (pp. 47-48). SILVERTON LANDSLIDES. Although minor landslides are found in considerable number throughout the Silverton quadrangle, only two districts are of sufficient importance to deserve special description. One of these is near the headwaters of the Rio Grande, south of Sheep Mountain; the other and larger area is near the head of Red Mountain Creek, a branch of Uncompahgre River, and includes within its borders a considerable part of the well-known Red Mountain mining district. Like the Cimmaron, Telluride, and Rico landslides, those of the Silverton region possess certain features that distinguish them from the slides of the regions previously described. With the exception of one that occurs at the end of Hayden Mountain and belongs strictly to the Ouray province, only volcanic rocks have been involved in the slipping. Structural conditions, such as deformation or faulting, have not played much, if any, part in the occurrence of the Silverton landslides, as they appear to have done at Rico; on the other hand, the Silverton slides more closely resemble the Rico than the Telluride slips, in that considerable areas have been covered by fallen material resulting from successive slips rather than from single slides, as in the Telluride region. Unlike those in the other districts described, there appears to be no good reason why the Silverton slides should have occurred at certain local- ities, rather than in other apparently equally favorable spots in the region. This fact is of some importance in considering the cause of the slides. RED MOUNTAIN LANDSLIDE DISTRICT. The Red Mountain landslide debris covers about 5 square miles of territory, which may be separated into two fairly distinct areas — the Red Mountain area proper and the Ironton Park area. Ironton Pari: area. — The landslide area of Ironton Park extends from Hendrick Gulch on the north to Gray Copper Gulch on the south, a distance of more than 2 miles, while from the level of Ironton Park upward for fully 2,000 feet the hillside surface is characterized by typical landslide topography. Material of landslide origin also covers a considerable portion of the hillsides west of Ironton Park, but its topographic expression is less pronounced. From favorable points of view the hillside south of Hendrick Gulch presents one of the most typical landslide-covered slopes that has been observed in the San Juan region. Although mantled by a heavy growth of young aspen, the characteristic block and trench, or ridge, structure of the surface is well shown. One feature, perhaps better exhibited here than anywhere else, is the crowding together of the individual blocks near the lower part of the slope, causing a steeper inclination of the general surface of the slide area in its lower portion than exists nearer the crest of the ridge. The profile of the lower part of the ridge is roughly convex, while that of the upper portion is concave. o Cf. Darwin's reference to the effect of the Concepcion earthquake in shattering hard slates at the surface "as if they had been blasted by gun- powder": Jour. Researches, 1839, p. 370. 26 LANDSLIDES IN THE SAN JUAN MOUNTAINS. A closer examination of the ridge shows that, while the whole hillside has been affected by landslide action, the present topography is clearly due to successive slips of innumerable relatively small blocks. The very uniform alignment of the fallen blocks and intervening trenches is especially noteworthy, and the crests of the elongate blocks are nearly parallel to one another and to the general trend of the ridge from which they have slipped. The fallen material consists in part of San Juan tuff, and of the massive flows and breccias of the Silverton volcanic series of andesites and latites; and on account of their similarity to one another, or the extremely decomposed condition of certain parts of the Silverton volcanic series, it becomes very difficult to tell how far blocks have slipped and from what points they were derived. Because of their unshattered and massive condition it is believed that individual blocks have moved comparatively short distances. The absence of a well- defined scar back of the landslide material seems to show that no very general movement has taken place, and that the landslide debris, notwithstanding its characteristic topography, is of a decidedly superficial nature. This locality presents one of the best examples of a considerable area covered by the moderate slipping of many blocks, large and small. Red Mountain area. — The Red Mountain district proper extends from Gray Copper Gulch southwestward to the divide at the head of Red Mountain Creek. The northeastern part of the area lies almost entirely on the eastern side of the creek, while in the southern half landslide action has been general on both sides of the stream except in the restricted region of the town of Red Mountain. About 6 square miles of territory are covered by landslide debris on the northwestern slopes of Red Mountain and on the western side of Red Mountain Creek near its head. Although the area is considerably less than that covered by the Telluride slide, a much greater number of slips have taken place. With the exception of a few bodies of intrusive porphyry, whose debris is found in landslide masses, practically all of the fallen material consists of rocks of the Silverton series. The district is at the northern end of an area of extreme decomposition, in which the various rocks have now lost practically all of their original characteristics, rendering it quite impossible to distinguish between the various members of the Silverton volcanic series. It is not improbable that this decomposition of the rocks has been an important factor in the occurrence of the landslides, having sensibly reduced the cohesion and strength of the rocks involved. Few landslide areas present greater topographic evidence of their origin than does the Red Mountain district. The varied detail of its topography is shown in Plates VII and VIII. The character of the southern part of this area, where undrained pools or swamps occur at the backs of many of the blocks, is shown in Plates VII, A, and VIII, A. Such visible drainage as exists is most irregular, and the whole surface is characterized by blocks and ridges which have a roughly parallel north-south trend. In this area, and in that to the north and west of Red Mountain Creek, the rocks have undergone less decomposition than to the east, and the land- slide blocks have retained much of their original form and the surface its typical configuration. Compared with the northeastern area there has been much less shattering of the fallen mate- rial, which consists almost entirely of the massive flows and breccias of the Silverton volcanic series. The most interesting portion is that near the center of the area north of the town of Red Mountain and surrounding the well-known Paymaster, Yankee Girl, and Guston mines. The ,material covering the area which lies between Red Mountain Creek and Gray Copper Gulch has come entirely from the western slopes of the three summits of Red Mountain and consists of decomposed and altered andesite and breccia of the Silverton volcanic series with not a little intrusive porphyry such as occurs at the summit of Red Mountain No. 3. In the southern part of the area the topography is more hummocked than ridgelike, and at first sight the peculiar chaotic mingling of these mounds and hillocks suggests that the whole surface is covered by landslide debris. The amount of this material is, however, less than at first appears, for some of the mounds or hillocks are actually in place, as is shown by the deep workings of some of the mines which are located at these points. Two instances of rock in place projecting through U. S. GEOLOGICAL SURVEY PROFESSIONAL PAPER 67 PLATE VII A. SMALL POND OCCUPYING DEPRESSION ON TRENCH BETWEEN LANDSLIDE BLOCKS NEAR HEAD OF MINERAL CREEK, RED MOUNTAIN LANDSLIDE DISTRICT, SILVERTON QUADRANGLE. B. LANDSLIDE SURFACE BELOW RED MOUNTAIN No. 2, SILVERTON QUADRANGLE, COLO. Shows multitude of small slide blocks with intervening trenches or depressions. The slide area extends across ridge from Red Mountain No. 2 into Corkscrew Gulch. On the left is the knoll above Paymaster mine shown in Plate VIII, B. White Cloud and American Girl mines in foreground. SILVERTON LANDSLIDES. 27 landslide material occur in the northeastern part of this district southwest of Corkscrew Gulch, one of which is shown in Plates VII, B, and VIII, B. Even in the illustration (PI. VII, B) it is evident that a large part of the hillside consists of landslide debris, but at the extreme left and about midway on the slope is a point which projects some distance above the general level of the landslide debris and which on close examination is found to be rock in place. This hill is encompassed by landslide material and stands out with its simple outline in striking contrast to the peculiar topography surrounding it. This, with the less conspicuous outcrops farther south in the vicinity of the mines, strongly indicates that in the time immediately preceding the landslide epoch the topography must have been more rugged than it is to-day; that the valley of Red Mountain Creek must have been steep and narrow, with many spurs and sharp ridges between the tributary ravines, and that the present gentler slopes were formed both by the downfall of the higher points and by the filling in of the lower portions of the valley by landslides. A few spurs or ridges, which for some reason escaped destruction, remain, but otherwise obliteration of the details of the old topography was almost complete. The lithologic character of the fallen material also indicates a complex origin; that is, certain blocks of intrusive porphyry have clearly come from near the summit of Red Mountain No. 3, as has also much of the extremely altered rock of the Silverton volcanic series, but adjacent to such masses are blocks of comparatively fresh andesite that are believed to have been derived from some of the projecting ridges referred to, farther from the seat of decompo- sition. The shattered condition of most of this fallen material is the only means of distinguishing certainly the landslide hillocks from those of the projecting rock in place, which is not shattered but considerably decomposed. The more important points to be noted in connection with this Red Mountain district are the extremely superficial character of the landslide action, notwithstanding the wide area cov- ered by the fallen debris; the fact that the present topography is due to innumerable small slips, and the fact that the slipping appears to have been dependent upon two factors — the decomposed and unconsolidated nature of the rocks and the probable bold topography which existed previous to the falling. In this connection, however, it should be pointed out that at a good many other localities in this region precisely similar causal conditions now exist, and yet no landsliding has taken place — a fact which also held true in the Rico district. This fact, which is believed to be a significant one in considering the cause of the landslides, is discussed later (p. 46). LANDSLIDE AREA SOUTH OF SHEEP MOUNTAIN. The features of the landslide area south of Sheep Mountain are essentially the same as those of the more typical landslides of the Rico district, the only difference being that the rocks involved are all volcanic. Massive flows of latite of the Silverton and Potosi volcanic series rest at this point on the San Juan tuff, which is here not well consolidated. The massive flows above this weak foundation are jointed to an unusual degree, and simple conditions of instability appear to be largely responsible for the landslide action. The present topography is clearly the result of the slipping of many small blocks, and this process appears to be still in progress, since many may be observed on the point of splitting off from the still unhealed scar on the south face of Sheep Mountain. The topography in the upper part of the area resembles closely that of a large kettle moraine, and the presence of considerable true morainal material adjoining the landslide area to the northwest caused not a little difficulty in the differentiation of these two formations. The land- slide material may be distinguished by the sharp angular character of its debris, which is strongly contrasted to the rounded or subangular appearance of the drift. The absence of latite of the Potosi volcanic series in the drift and the abundance of this material in the landslide debris is another distinguishing feature. In some respects this landslide, or at least a portion of it, possesses certain features common to rock streams described in a later section. 28 LANDSLIDES IN THE SAN JUAN MOUNTAINS. LANDSLIDES OF CANYON CREEK, NEEDLE MOUNTAINS. Landslide action of a type comparable in many ways to that of the Red Mountain district- has occurred near the head of Canyon Creek, a tributary of Animas River which enters that stream near the town of Rockwood, flowing from the east and draining the high, inclined mesas that border the southern slopes of the Needle Mountains. In this region the rocks involved in the slipping were those belonging exclusively to the Hermosa formation, consisting here of sandstones, limestones, and shales. The present relief of the locality is extremely moderate as compared with that of adjoining regions, and especially with that of the Red Mountain district. Probably more than 4 square miles of territory are covered by landslide debris occurring in three areas. In two of them that border Canyon Creek directly there is clear topographic evidence as to the origin of the fallen material. In these two localities the debris lies on moderately steep slopes, above which in a few places are unhealed scars, but in most cases steeper and more even slopes are the only indication of rock in place. In the upper part of the southern and larger area many blocks of sandstone and limestone may still be distinguished, often separated from one another by deep, open fractures or crevasses, indicating that movement has taken place in recent times. Lower down the slopes the surface is more rounded and gentler in relief, with numerous ponds and springs, and is covered by a heavy growth of timber, indicating greater antiquity. The smaller area north of Canyon Creek has a very characteristic topography of unmis- takable landslide origin. Marshes and small pools are abundant, the fallen blocks are separated from one another by trenches, and narrow ridges descend, one below another, like steps, for 600 feet. The rocks in place dip about 6° SW., while the direction of the landslide movement has been both to the northwest and to the southeast, at right angles to the direction of the dip. The third area is of slightly different character. It lies about the headwaters of a northern fork of Canyon Creek and borders Tank Creek, a more northerly tributary of the Animas, on the northwest side of a broad, flat ridge that forms the divide between these northern forks and Canyon Creek proper. Five or six small streams drain this region, and, just beyond its lower limits, join to form the north fork of Canyon Creek. The topography is that characteristic of landslides considerably softened by age. The relief is gentle, springs are numerous, and un- d rained pools, bogs, and hollows indicate the locations of old trenches between fallen blocks. As a rule the area bears evidence of considerable age, but in a few places fairly fresh scars may be noted, especially near the head. The puzzling feature of this landslide locality is the fact that there appears to be no point from which the material can have fallen ; there is no high land or ridge in the vicinity, and the moderate slope upon which the material rests, a little over 1,000 feet in a mile and a half, is noteworthy. It is believed that in this region, previous to the occurrence of the landslides, high, narrow ridges existed, and the slipping of material from their sides into the drains or ravines between them not only lowered the ridges but filled the drains and resulted in the present irregular topography of low relief. The upper limits of these slides are shown with fair clearness and may be traced about the ends of the ridges from one drain to another. The lower or outer edges are more difficult to make out, partly because the accumulations are less thick, and also because in a great many cases loose rock and soil has slipped down over glacial gravels or moraine, causing a mingling of the two sorts of material. The drift was derived almost entirely from the pre-Cambrian rocks of the Needle Mountains, and this fact, together with the usual subangular and striated character of the material, at once distinguishes moraines from accumulations of landslide debris composed of the detritus of Paleozoic sediments. When landslide debris comes into contact with or overlaps drift deposits, the presence of both kinds of detritus is readily recognized, but the boundary between them is extremely difficult to define. U. S. GEOLOGICAL SURVEY PROFESSIONAL PAPER 67 PLATE VIM A. RED MOUNTAIN LANDSLIDE DISTRICT, SILVERTON QUADRANGLE. Typical landslide blocks and ridges with intervening trenches. At divide between Red Mountain and Mineral creeks. B. DETAILS OF LANDSLIDE TOPOGRAPHY SOUTHEAST OF CORKSCREW GULCH, RED MOUNTAIN DISTRICT, SILVERTON QUADRANGLE. The ridge sparsely covered by trees consists of rocks in place; the material in the foreground is landslide debris alone. LANDSLIDES IK VICINITY OF OURAY. 29 LANDSLIDES OF HERMOSA CREEK. Hermosa Creek enters Animas River about 10 miles above Durango and drains an area composed largely of sedimentary rocks of the Carboniferous lying directly east and south of the Rico Mountains. From Hermosa Park, where it is joined by the East Fork, to its entrance into the Animas Valley, a distance of 15 miles, the stream flows through a deep, narrow valley, almost canyon-like in the steepness of its walls, which are composed of the upper part of the Hermosa formation, while near Hermosa Park the Rico and Cutler beds also come in. At several points along the stream, about midway between its mouth and Hermosa Park, landslides of considerable magnitude have taken place. A thick growth of timber conceals most of the detail of the surface of these landslides, and it is only through their broader features, which have modified the cross section of the valley at various points, that they are to be most readily recognized. It was found in tracing certain stream gravels down the valley that the deposits were not continuous, but occurred in three or more fairly well defined steplike levels which descended the valley — that is, gravel deposits that occurred at a given locality but a few feet above the present level of the stream were traced for a mile or more down the valley at a very gentle grade to a point where their upper limits were 100 or 200 feet above the present stream level. Points where the gravels occurred at such high elevations were generally marked by a convergence of the lower slopes of the valley, the streams flowing through a ravine, whose banks, generally bare, were seen to be composed of a chaotic mixture of broken and shattered Hermosa material. At such points the gravel deposits ended abruptly, and began again, beloW the ravine, nearly at the stream level. It was found on close examination that at these points landslides had occurred, completely damming the stream for a time sufficient to permit the deposition of stream gravels at or near the summit level of the dam. Subsequently the stream succeeded in wearing its way through the barrier, and returned to its original grade. This damming of the stream by landslides is essentially the same as that which occurred just above Rico, but the Hermosa slides are believed to have obstructed the stream more effect- ively, partly for the reason that the valley was narrower, and also because a greater amount of material appears to have fallen. In respect to individual Hermosa Creek slides it seems necessary to assume that all the sliding occurred at one time rather than that the fallen mate- rial as now preserved came to its place as the result of successive minor slips. Had repeated small sliding taken place the complete damming of the stream would probably not have occurred. As has been said, the rocks involved in the slides were nearly horizontally bedded limestones and sandstones of the Hermosa formation. In this region the upper portion of the Hermosa rests upon soft friable shales and sandstones occurring near the base of the formation. This relation has probably had not a little to do with the occurrence of the landslides. Abrupt cliffs still face the creek on both sides, and the landslides are naturally to be attributed to some structural weakness or instability on the part of the beds at similar points. Here again, how- ever, it is difficult to understand why landslides should have occurred at these localities and not at neighboring ones, where equally favorable conditions appear to exist. A few miles to the east cliffs of precisely the same rock rise 2,000 feet above the Animas Valley, and yet land- slide debris along the feet of these cliffs is almost altogether absent. LANDSLIDES IN VICINITY OF OURAY. A very large number of landslides, some of them of considerable magnitude, have occurred within the boundaries of the Ouray quadrangle. The majority of these slides differ but little from those of the Telluride region. In many cases massive igneous rocks rest upon soft Cre- taceous shales, and slipping has taken place in the more or less simple manner exhibited by the great Telluride slides. Slides of this character have been abundant and have covered wide areas west of Uncompahgre River and north and south of Corbett Gulch. A landslide on the south side of Dexter Creek, about a mile from its mouth, is shown in Plate IX, A. There is a large mass of intrusive monzonite porphyry at this point, which has 30 LANDSLIDES IN THE SAN JUAN MOUNTAINS. invaded the lower part of the San Juan tuff, resting here on Mancos shale. The hillside has an extremely rough surface, is largely without soil, and is composed of great blocks of porphyry, usually much shattered. Some of the blocks are large enough to appear as points or small ridges of rocks in place. The downward movement has evidently been very slight and was accompanied by much shattering and straining of the porphyry, but with the precipitation of only a small part of the rock into the creek below. LANDSLIDE OF THE AMPHITHEATER, PORTLAND CREEK. Portland Creek joins Uncompahgre River at the town of Ouray, and drains a peculiar, short, wide valley with high, steep walls, aptly named the Amphitheater. An area of more than a square mile, representing almost the whole floor of the Amphitheater, is covered by an enormous quantity of debris of the San Juan formation. The broader features of the Amphi- theater are those of a glacial cirque. Although the material filling the bottom of the Amphitheater has a rounded, billowy sur- face and is covered for the most part by vegetation, Portland Creek and its tributaries have carved deep trenches in it, in the sides of which, often more than 200 feet high, the chaotic nature of the accumulation is well displayed. This slide seems to be a good example of a type thought to be due to the disappearance of glacial ice from cirques whose walls have been over- steepened and their foundations weakened by bergschrund quarrying. CANYON CREEK SLIDES. Southwest of the town of Ouray, and on the southeast side of Canyon Creek at the end of Hayden Mountain, landslide debris covers an area of about 1 square mile. The upper part of Hay den Mountain consists of San Juan tuff, resting upon a thin band of Telluride conglomer- ate, which in turn lies on the sandstones and grits of the'Hermosa formation. All of these rocks are represented in the fallen material, which has the characteristic block and trench sur- face, lacking regular drainage, and at the base of which are numerous springs. At the end of the Hayden Mountain ridge the block and trench structure is unusually well developed, and the mingling of the blocks of different formations is not common, indicating that the slipping has been moderate, although involving a considerable area. An abundance of glacial gravels occurs in Canyon Creek, which have been in part cov- ered by the landslide debris. The relation of the two kinds of land waste is often obscure, the subangular form and striation of the bowlders in the marginal mateiial affording almost the only means of differentiation. It is also shown that Canyon Creek was temporarily dammed by the landslide, and that stream gravels were deposited upon the landslide debris before the stream succeeded in cutting through the barrier. The chaotic nature of the fallen material is well exhibited along the present lower wagon road, where the old dam has been cut through by the stream. PLEISTOCENE LANDSLIDES. In discussing the age of the landslides of the San Juan region in a later part of this paper (p. 46) it is shown that in the vast majority of cases the slides have occurred after the disap- pearance of the last glacial ice. The most notable exception is found west of Uncompahgre River, about the headwaters of Coal Creek and various southerly branches of Dallas Creek. The area in which the landslides occur is at the foot of the high mountains, which are the most northwesterly ones of the San Juan group and which extend westward from Uncompahgre River in a nearly straight line for 15 miles, boldly overlooking the open valley of Dallas Creek and the Uncompahgre Plateau beyond. The mountains rise abruptly from a region that formerly was of moderate relief and in which the modern streams have entrenched themselves to depths of 200 to 500 feet. It is on the broad, low divides between these streams that the remnants of the old landslide material occur. The tops of these ridges or mesas between the streams are characterized by low, rolling surfaces, on which no outcrops occur and which pre- sent no suggestion of a block and trench structure; it is onl}r along the sides of the present U. S. GEOLOGICAL SURVEY PROFESSIONAL PAPER 67 PLATE IX A. LANDSLIDE DEBRIS ON THE SOUTH SIDE OF DEXTER CREEK NEAR BACHELOR MINE, OURAY QUADRANGLE. B. NORTHWESTERN EXTENSION OF THE SNEFFELS RANGE WEST OF THE OURAY QUADRANGLE AT DIVIDE BETWEEN UNCOMPAHGRE AND DOLORES DRAINAGE BASINS. On the surface of the prominent hill in the middle distance is ancient landslide material consisting of debris of rocks of the Potosi volcanic series. The mountain to the left is composed of rocks of the Silverton volcanic series but was formerly capped by flows and breccias of the Potosi. 32 LANDSLIDES IN THE SAN JUAN MOUNTAINS. Three of the most typical rock streams which are known to occur in the San Juan Moun- tains and which were among the first to be observed and particularly studied are those of Imo- gene, Pierson, and Silver basins, in the northwestern part of the Silverton quadrangle. These basins lie on the south side of Canyon Creek and drain into that important tributary of Uncom- pahgre River. Although scores of examples might be cited, no others bring out so clearly the many peculiar features of these remarkable masses. ROCK STREAM OF PIERSON BASIN. The rock stream of Pierson Basin, one of the largest observed in the San Juan, is shown in Plate X, A and B, which are panoramic, while the topography of this area is represented in figure 2. It will be seen that nearly the whole floor of this large basin is covered by angular rock debris to a depth of 50 to 100 feet and that the detritus extends from the head of the basin at the foot of the abrupt cliffs all the way to the point where the gentle slope of the basin floor changes to the steeper descent to Canyon Creek. The length of this rock stream is more than three-fourths of a mile, while its average breadth is about one-third of a mile. In other words, on the basis of the lowest estimated depth — 50 feet — the volume of material lying on the cirque floor amounts to nearly 13,000,000 cubic yards. In viewing this enormous mass of debris from a distance one is at once impressed by its very peculiar form, which is like that of a great tongue of some viscous substance that has slowly flowed down from the cliffs at the back of the cirque and gradually extended to the outer edge of the basin. The singular billowy surface, and the curved, often concentric lines which occur near the front or foot of the mass and which closely resemble those caused by the cooling of lava streams, strongly add to the appearance of slow movement. Character of material composing the rock stream. — A detailed examination of the rock stream reveals many features which at once distinguish it from ordinary talus. The rock stream is composed of debris of the rocks of the Potosi volcanic series. The fragments are of all sizes, from huge blocks 15 feet or more in diameter down to coarse sand or angular gravel, but most of them are from 1 to 2 feet in diameter and are sharply angular. Form in which the material lies. — As is shown in Plates X and XI, the material is bounded on all sides by a steep embankment except at the head of the cirque. On the east side of the basin (PI. XI) this embankment meets the ordinary talus coming from the cliffs above and forms a narrow trench which extends all the way from the head of the rock stream to its foot. On the western side of the basin, as shown in Plate X, A, there is a wider space between the edge of the rock stream and the cirque wall; it is practically bare with the exception of a few scattered bowlders and blocks, but the embankment of the rock stream is just as sharp as at the eastern edge. In other words, there is no gradual thinning out of the debris or blending with the original surface of the cirque. The end of the rock stream extends to the point where the floor of the cirque suddenly drops away to the level of Canyon Creek, and the detritus has flowed, as it were, over this point and extends some little distance below, as shown in Plate X, B. Still lower down the slope, below the naked foot of the rock stream, occurs more material of practically the same character, except that it has been subjected to prolonged weathering and is now covered by a dense forest growth which completely hides its form. No description can convey as clear an impression of the character of the surface of this remarkable accumulation as do the illustrations, Plates X and XL For more than two-thirds of its length from its foot upward, and in its inner portion, the surface is characterized by innumerable rounded mounds or hummocks sharply separated from one another by lines of almost crevasse-like sharpness. Near its foot is a longitudinal depression, not clearly shown in the illustration. Almost completely surrounding the interior hummocked portion is a band or zone characterized by long concentric ridges that follow roughly the outline of the rock stream, as shown in the illustration. Source of material. — The material composing this rock stream was derived from the great cliffs, shown only in part at the extreme right of Plate X, A. It consists entirely of detritus U. S. GEOLOGICAL SURVEY PROFESSIONAL PAPER 67 PLATE X A. UPPER PORTION OF ROCK STREAM IN PIERSON BASIN, SILVERTON QUADRANGLE. The length of this stream from the head of the cirque to its distal extremity, shown in Plate X, B, is about three- quarters of a mile and its mean width one-quarter of a mile. B. LOWER PORTION OF ROCK STREAM IN PIERSON BASIN, SILVERTON QUADRANGLE. PROFESSIONAL PAPER 67 PLATE XI ROCK STREAM IN PIERSON BASIN, SILVERTON QUADRANGLE. Looking toward the head of the stream, along its eastern edge, from a point near its foot. Shows the mixture of coarse and fine material composing the rock stream, and the sharp boundary between the rock stream and the ordinary talus to the left. SILVER BASIN ROCK STREAMS. 33 of the Potosi volcanic series and mostly of the flows, only small remnants of which now exist at the top of the ridge. The continuous occurrence of the debris from the foot of the rock stream all the way back to the base of the cliff at its head, and the sharp boundaries that exist on either side of the rock stream separating it from the talus of the lateral ridges of the cirque, seem to indicate that all of the material has been derived from a cliff at the head of the cirque. I07°44-' 45 '30 Contour interval 50feet Figure 2. — Map of Silver and Pierson basins, Silverton quadrangle, Colorado, showing details of rock-stream topography. SILVER BASIN ROCK STREAMS. Silver Basin lies immediately to the west of Pierson Basin and contains three rock streams, one of which is of considerable size, though smaller than that of Pierson Basin. The general appearance of the large stream is best shown in Plate XII, A. In most of its features it is essen- tially the same as the large stream just described. The character and condition of the material is precisely the same, and the steep slope marking the outer limits of the stream is present, but the configuration of the surface is quite different. Instead of hummocks and rounded mounds irregularly disposed over the surface, concentric ridges, which follow the general outline of the edge of the stream, predominate. As seen from a distance, the surface of this rock stream is strikingly similar to that of ropy lava (pahoehoe) of the familiar Hawaiian type. In this case, more strongly perhaps than in any other observed in the San Juan Mountains, one is inclined to believe that the mass is still actually moving, after the manner of glaciers. In 34 LANDSLIDES IN THE SAN JUAN MOUNTAINS. the early study of the rock streams it was thought that such movement must be assumed in order to account for their peculiar form and position, but, with the possible exception of certain instances in the Engineer Mountain quadrangle, no evidence whatever has been found that such movement is now taking place or has occurred in the past. In P^tes XII, A, XII, B, and XIII, B, the close relation of the rock-stream material to the cliffs at the south end of the basin and the lack of any connection with the sides of the basin as sources of supply is clearly shown. Another feature of importance in considering the origin of these rock streams, illustrated by both the stream in Silver Basin and that in Pierson Basin, is the extremely low grade of the floor of the basin upon which the detritus lies. The contrast between this and the steep slope on which ordinary talus rests is clearly shown in Plate XII, B, where to the right the usual accumulations of talus may be seen below the cliffs. Still lower down the slope is a torrential fan composed of the material washed from this talus by wet- weather streams. Lower down the basin and below a solid rock bench, shown in the topographic map (fig. 2) ■on the east side, is another rock stream. Although smaller and of much less volume than the other two streams, it possesses certain features of considerable interest. It is shown in Plate XIII, A, and certain details are brought out in Plate XIV, A. It will be noted in Plate XIII, A, that the outer limit of this slide is marked by a ridge that may be traced continuously around its foot. Within this circular ridge the surface is more or less hummocked and unevenly ridged, like that of the Pierson Basin stream. The particular point of interest here is that the material of the outer ridge consists of debris from flows of the Potosi volcanic series, while the detritus found in the center of the slide was derived from andesites, either flows or tuffs, of the Silverton volcanic series. The line between the debris of these two kinds of rocks is very sharply marked, not only by the trench shown in Plates XIII, A, and XIV, A, but also by the color of the rock, which is indicated in the illustrations, the outer ridge being of a light-pinkish color characteristic of the Potosi, while the material within is dark brown and typical of the andesites of the Silver- ton volcanic series. The position of the slide shows that its material came directly from the high ridge southeast of it. The flows of the Potosi volcanic series, which evidently once capped tli is ridge, now do not extend as far north as the point overlooking this rock stream, the only rock in place above it belonging to the Silverton volcanic series. One naturally assumes that the outer rim of the rock stream, formed of the rhyolite of the Potosi volcanic series, came to its place as the result of some fall which at the time removed the last remnant of the Potosi capping the ridge, and that when this fall occurred only the Potosi rock was involved. At some later time other falls occurred, which carried down the andesitic material of the Silverton. It is difficult to understand how the material could have come to its present position as the result of one fall or through the successive falling of small fragments, for in such cases there would have been undoubtedly a thorough mingling of the debris. Where the timber occurs just beyond this rock stream (shown to the left of the center of Plate XIII, A), there are similar ridges, now completely covered by vegetation. They are believed to be remnants of older rock streams, although if occurring elsewhere they probably would have been regarded as of ordinary landslide origin. The slope upon which this small rock stream rests is considerably steeper than that of the two larger examples, and simple talus has often been found occurring on slopes of lower angle, but one can hardly assume that this deposit of detritus was formed through the simple process of rocks falling as small fragments from the cliffs to lower slopes, partly on account of the peculiar form of the stream, and also because of the unmixed character of the two kinds of rocks forming it. ROCK STREAM IN IMOGENE BASIN. An even more remarkable stream than those described occurs in Imogene Basin above the workings of the well-known Camp Bird mine. This rock stream is shown in Plate XIV, B. It lies on the southwest side of the basin directly under a high peak composed of rhyolite of the Potosi volcanic series. The stream is nearly as long as that in Pierson Basin, about three- U. S. GEOLOGICAL SURVEY PROFESSIONAL PAPER 67 PLATE XII -V-. M $&#?: A. ROCK STREAM AT HEAD OF SILVER BASIN, SILVERTON QUADRANGLE, FROM THE NORTHWEST. The concentric, wavelike ridges characteristic of many rock streams are well shown in this view. B. ROCK STREAM AT HEAD OF SILVER BASIN. Shows the thickness of the stream at its outer edge and its sharply defined boundaries as contrasted with ordinary talus from the cliffs at the right. U. S. GEOLOGICAL SURVEY PROFESSIONAL PAPER 67 PLATE XIII A. ROCK STREAM IN LOWER PORTION OF SILVER BASIN, SILVERTON QUADRANGLE. The outer rim of lighter color than the rest of the stream consists of debris of rhyolite of the Potosi volcanic series; the rest of the detritus of darker tone was derived from andesitic rocks of the Silverton volcanic series. B. ROCK STREAM AT HEAD OF SILVER BASIN, SILVERTON QUADRANGLE, FROM THE NORTHEAST. Shows sharp definition of stream and indicates its great volume as compared with talus piles below right-hand cliff. U. S. GEOLOGICAL SURVEY PROFESSIONAL PAPER 67 PLATE XIV A. ROCK STREAM IN LOWER PORTION OF SILVER BASIN, SILVERTON QUADRANGLE. Detail of surface ; the outer rim of rhyolite debris indicated in Plate XIII, A, is shown on the left. B. ROCK STREAM OF IMOGENE BASIN, SILVERTON QUADRANGLE, NEAR CAMP BIRD MINE. The sharp boundaries of this stream are noteworthy, as is its position at the end of the ridge shown at left of the illustration. ROCK STREAMS OF AMERICAN BASIN. 35 fourths of a mile, but its width is less. The surface of this stream is considerably smoother than that of either of the two large ones previously described, but in general appearance it more closelv resembles the stream in Silver Basin; that is, the surface is ropy rather than hum- mocked or mammillary. The remarkably sharp boundaries of this stream are clearly brought out in the illustration, and some idea of the height of the bounding slope or embankment may be had from the pack train which is ascending along a trail near the foot of the stream. Although in all cases where rock streams have been observed in the San Juan Mountains the material composing them is found to have come from a very restricted point above the head of the stream, the relation of the material of the Imogene Basin stream to its source is shown with unusual clearness. The gentle slopes of the basin's walls on either side prevent the pos- sibility of assuming that any of the material could have come from either of these directions, and the sharp bounding embankments which may be traced directly to the foot of the cliff, shown on the left of the illustration, seem to indicate clearly that the material could have come from no other source. ROCK STREAMS OF AMERICAN BASIN. Accumulations of debris, somewhat like those of the Canyon Creek locality, but differing in many details, occur at the head of American Basin, in which Lake Fork of Gunnison River rises. The locality is about 12 miles east and slightly south of the Canyon Creek district. American Basin has no well-defined, smooth floor, except possibly very near its head, as shown in Plate XV, A. The south end is marked by a line of abrupt cliffs of pyroxene ande- site, as shown in the illustrations. Below these cliffs, on a comparatively narrow bench of bare rocks, enormous masses of detritus have collected. In their general appearance and in their relation to the cliffs back of them these accumulations closely resemble ordinary talus, but their outer limits are marked by steep, embankment-like faces comparable to those bounding the rock streams of Silver, Pierson, and Imogene basins. The continuity of the rock bench upon which the detritus rests is broken at about the middle. Through this breach or depression a great tongue of detritus extends downward for several hundred feet, as shown in Plate XV, B. This tongue, or lobe, is altogether comparable, both in magnitude and in form, to the rock streams previously described, its peculiar features being a higher outer embankment or bounding slope, at the front of which the material has come to rest at a lower angle than in the Silver Basin or Pierson Basin streams. The surface of the stream is marked by a depression bounded by a well-defined ridge, as shown in the illustration. Little or no hummocking or ropiness characterizes the surface of this slide except near its upper part. It is believed that this rock stream is due to a slumping of talus that, in the course of its slow accumulation, had become unstable as a result of overloading at its outer margin. It will be seen at once that the forms assumed by the detritus in American Basin are appre- ciably different from those of the great streams of the Canyon Creek district, but here also they are believed to be distinct from those of ordinary talus accumulations. The mode of origin of the deposits of detritus in American Basin is believed to be fairly well understood, and was described in some detail in the text of the Silverton folio (No. 120), from which the follow- ing account is taken more or less directly. Almost all of the deposits of detritus similar to those of American Basin — and there are many such in the San Juan — occur at the base of cliffs facing the north. North-facing basins with high rock walls are localities favorable for the accumulation and preservation of great snow banks, and it is believed that such snow banks have been repeatedly formed since the dis- appearance of true glacial ice from the cirques. Such banks have often been seen early in summer with their surfaces thickly strewn with fragments of rock, large and small, which have fallen from the cliff above. Rocks falling upon the smooth, even surface of snow banks will roll much farther from the base of cliffs before coming to rest than when they fall directly upon a similar slope of rock debris. Although most of the material reaches the foot of the snow 36 LANDSLIDES IN THE SAN JUAN MOUNTAINS. bank, much falls short, so that with the gradual melting of the snow and the letting down of its load of debris a greater quantity is apt to be deposited at a distance from the cliffs than in the formation of an ordinary talus slope, and a zone at the base of the cliffs is protected from the excessive accumulation of debris. This process is illustrated diagrammatically in figure 3. The resulting form of such accumulations would naturally be more complex than that of simple talus and would be characterized by mounds or ridges between which and the cliffs there would probably be a lesser thickness of detritus and possibly a depression. During the summer months, after the disappearance of the snow, the usual weathering of the cliffs would supply material for the formation of ordinary talus, the outer limits of which would blend with the inner portion of the snow-bank deposits. The profile of such accumulations (fig. 3) would be, near the cliffs, the same as that of simple talus; farther away the slope would flatten out or possibly become reversed, while the outer limits would be marked by a steep embankment. The slightly different forms and the varying size that the snow banks would have from year to year would undoubtedly cause an unequal distribution of the debris, and the uneven, hummocked surface of the deposits might thus be accounted for. In the course of early field observation these snow-bank deposits were believed to be intermediate between talus and the rock streams, and it was thought that perhaps they indicate a transition stage from one form of deposit to the other. It was hoped, therefore, that in studying these deposits light would be thrown upon the origin of the rock streams; but later investigations show that the two kinds of deposits are in no way related genetically, as is brought out later (pp. 49, 52) in discuss- ing the origin of rock streams. It is unnecessary to describe all of the nu- merous rock streams that have been observed in the San Juan Mountains; at least 30 occur in the Silverton quadrangle, and nearly as many have been found in the Ouray and Lake City districts. None of these is markedly dis- similar in any way from those that have been described. Of the more notable ones, that north of Greenhalgh Mountain, in the south- eastern part of the Silverton quadrangle (PL XVI, A), may be mentioned, while those occu- pying a number of high basins on the south side of Henson Creek, in the northeast corner, are especially noteworthy, both from their size and from their characteristic form. An example of these is shown in Plate XVI, B. Figure 3. — Diagram illustrating the influence of snow banks in the formation of talus accumulations like those of American Basin. CLEVELAND GULCH. A mass of waste in one other locality calls for special description. It is difficult to say whether this accumulation is to be regarded as a rock stream or as a landslide similar to the slides previously described. It lies on the north side of Cleveland Gulch, just south of the pass leading to Horseshoe Basin, in the northeastern part of the Silverton quadrangle. The form of the deposit is circular, with a tongue that extends nearly across the gulch. Its greatest dimension, including the tongue, is about one-half mile. The general appearance of the detritus and its relation to the surrounding topography is shown in Plate XVII. It will be seen that the lower or tonguelike portion has many of the characteristics of a rock stream, while the upper portion seems to be clearly of landslide origin. In attempting to find an explanation for this compound rock stream and landslide three possibilities may be considered. These theories really involve the whole question of the origin of the rock streams, discussed later, but may be mentioned here very briefly. The material may have come to its present position as the result of one fall or slip of essentially landslide character. The upper and more solid part may be regarded as having slipped but a short distance, while an outer portion of the parent block became dislodged and U. S. GEOLOGICAL SURVEY PROFESSIONAL PAPER 67 PLATE XV A. TALUS ACCUMULATIONS AND ROCK STREAM AT HEAD OF AMERICAN BASIN, SILVERTON QUADRANGLE. B. ROCK STREAM AT HEAD OF AMERICAN BASIN, SILVERTON QUADRANGLE. U. S. GEOLOGICAL SURVEY PROFESSIONAL PAPER 67 PLATE XVI A. ROCK STREAM NORTH OF GREENHALGH MOUNTAIN, SILVERTON QUADRANGLE. In volume and area this is one of the largest rock streams in the San Juan Mountains. ■»Sf£ B. PORTION OF ROCK STREAM IN HURRICANE BASIN, SILVERTON QUADRANGLE. Shows the billowy surface of the stream near its foot. ENGINEER MOUNTAIN ROCK STREAMS. 37 fell in a highly shattered condition, the falling debris being carried far out across the bottom of the gulch. The rock-stream tongue may have been formed as the result of a later secondary landslide involving a portion of the large block which had previously slipped, or it may have existed before the slipping of the large block above it. Recent weathering from the face of the larger landslide mass has completely obscured the relations between this and the rock stream below, talus from the landslide blending with the detritus of the rock stream. Although satisfactory proof is unfortunately lacking, the intimate relations that exist between the landslide and the rock stream would seem to favor the theory that, whether occur- ring contemporaneously or subsequently to the landslide, the rock stream is of simple landslide origin, the only difference between it and the more typical landslides of the region being that, either as a result of the fall or as a contributory cause, the material composing the rock stream was very completely shattered, while in more typical landslides many blocks of great size are preserved more or less intact. ENGINEER MOUNTAIN ROCK STREAMS. The rock streams in the vicinity of Engineer Mountain, in the quadrangle of the same name, although having less glacier-like form than those in the Silverton quadrangle, present points of special interest, particularly in regard to their origin. The upper part of Engineer Mountain is a peak of bare rock rising 1,200 feet above a bench of Carboniferous sediments on its eastern side. On the north, west, and south the platform or bench is not pronounced, but wooded, gentle slopes rise to a sharply defined junction with the upper cliff's. The peak is a ridge about one-half mile wide, with a very narrow crest marked by two prominent summits. Plates XVIII, A, XVIII, B, and XIX, A, are views of the moun- tain from the east, north, and west, respectively. The mountain owes its existence as such to a large intrusive sheet of trachyte which has resisted denudation more effectively than the softer sediments. The plane of intrusion is in general one of bedding in the Cutler (Permian?) red beds. These strata dip west-northwest at about 10°. In Plate XVIII may be seen the relations of the igneous rock to the dipping strata. The trachyte has a thickness of about 800 feet below the summit of Engineer Mountain, and it is nearly as great beneath the western peak. The upper contact of the trachyte is not shown in Engineer Mountain, but on the west side of Cascade Creek a few miles distant a more extensive sheet, identical in character with that of Engineer Mountain and of similar thickness, is seen intercalated in the Cutler forma- tion. These two trachyte masses may be portions of one original intrusive sheet, the thickness of which at Engineer Mountain was not much greater than that of the remnant preserved. The two masses do not occur at the same horizon, however, and may represent distinct bodies. The trachyte has a pronounced but irregular columnar jointing normal to the base shown in Plate XVIII, and, especially in the upper parts, a rude tabular parting in addition to irregular fractures. The zonal structure so prominent in the view of Plate XVIII, B, is scarcely to be detected by differences in the rock when examined in detail. The great accumulation of detri- tus shown in Plate XIX, A, is nearly as large in ground plan as the trachyte mass of the moun- tain. Its thickness is probably seldom more than 100 feet. The details of topography in the debris area are such as are common in rock streams. Trenches or troughs 40 to 50 feet deep are not rare and the marginal slope of the stream is always steep and 40 feet or more high. On all steep slopes of troughs or border face the debris is in unstable equilibrium and numerous fresh scars show where small slumps have recently taken place. Such falls tend in most cases to modify the relief of the mass. In Plate XVIII, B, may be seen the features of the north side of the mountain. Below the base of the talus fans a rock stream of characteristic flow lines and details of form extends for nearly a mile from the trachyte cliff, ending a thousand feet below the contact. Mingled with the trachyte of this stream at various places distant from the cliffs there is a subordinate amount of red sandstone and shale. It seems probable that this material came from a remnant of the sediments which was present on the summit of the mountain above the trachyte at the 38 LANDSLIDES IN THE SAN JUAN MOUNTAINS. time of a great rock fall involving that summit. It will be noted that the profile line of the present summit, as seen in Plate XVIII, B, is approximately parallel to the lower contact of the trachyte. The rock streams seen in Plates XVIII, B, and XIX, A, do not represent half of the area of similar detritus about Engineer Mountain. On the northwest slope, between the bare rock streams shown in the illustrations, there is a large area of forest-covered trachyte debris repre- senting landslide masses. Here and there some recent movement of a small portion of the mass has caused exposures. This timber-clad landslide debris may be older than that of the bare areas. The bare rock areas are probably not so much due to age as to local conditions, such as snow slides and repeated minor movements of debris, preventing or retarding tree growth. Some portions of the bare tracts are doubtless due to recent landslides. On the southern slope of the mountain there is a large area of much forested slide rock contiguous to the trachyte cliffs. Its boundary is not so clearly marked as is that of the other areas. The trachytic debris of the character described covers an area estimated to be about four times as great as that now occupied by the rock in place. At an average thickness of 50 feet for the slide rock this amounts to a mass 200 feet thick over the area of the trachyte now in place, or more than 160,000,000 cubic yards. It seems unlikely that the trachyte sheet of the moun- tain was more than 1,000 feet thick. If the calculated amount of debris, or any considerable part of it, be restored in imagination to the present mass of trachyte, it becomes clear that the form of the mountain must once have been much bolder than it now is. Presumably the time of boldest relief was immediately following the last glacial stage. The mountain stood directly in the path of ice descending from the high peaks of the San Juan, a few miles to the north. A residual glacier on the north side was probably the cause of the rude cirque seen in Plate XVIII, B, at the rear of which are the steepest cliffs of the peak. With the oversteep conditions existing at the close of glaciation rock falls of great magnitude undoubtedly took place. The jointed condition of the rock and its unstable equilibrium on the northern and western sides of the peak, due to the outward inclination of the columnar structure of the trachyte, were important contributory factors in the cause of these rock falls. This is emphasized by the practical absence of anything suggesting a rock stream at the eastern end of the peak, where the columnar structure inclines inward and structural conditions are those of greater stability; here ordinary talus has accumulated only as a thin coating that in many places does not entirely conceal the underlying strata. GRAYSILL MOUNTAIN. Trachyte like that of Engineer Mountain occurs in a sill several hundred feet thick in the ridge between Cascade Creek and the north fork of Hermosa Creek, which has been named Gray sill Mountain from this dominant feature. This intrusive mass occurs in the Cutler forma- tion, several hundred feet higher, stratigraphically, than the Engineer Mountain body, and if the two were ever directly connected there must have been cross cutting in the space now occu- pied by Cascade Creek valley. The beds of Graysill Mountain dip northerly a few degrees, so that the base of the sill is highest at the south extremity of the mass. At this south end the sill has been denuded of its sedimentary cover and eroded so irregularly that the southeast shoulder of the ridge becomes a prominent feature, known as Grayrock Peak. Its summit is a sharp point; elevation, 12,488 feet. About this end of the ridge the trachyte sill had an original thickness of 800 feet or more. The basal contact is well exposed, and as the rock is jointed vertically, there are cliffs similar to those of Engineer Mountain. A large cirque bounded by precipitous cliffs cuts into the east side of Graysill Mountain just north of Grayrock Peak. Another smaller cirque has been excavated on the south face of Grayrock Peak. Conditions favorable to landslide action existed in these basins and pronounced rock streams are present in each. The larger stream is in the northern cirque, extending outward U. S. GEOLOGICAL SURVEY PROFESSIONAL PAPER 67 PLATE XVIII A. ENGINEER MOUNTAIN FROM THE NORTH. Shows lower contact of trachyte inclined to the northwest, the col umnar jointing, and rock stream at foot of cliff. B. ENGINEER MOUNTAIN FROM THE EAST. Shows lower contact of intrusive trachyte and columnar structure; the small amount of talus and absence of rock streams is noteworthy. U. S. GEOLOGICAL SURVEY PROFESSIONAL PAPER 67 PLATE XIX A. ENGINEER MOUNTAIN FROM THE WEST. Shows rock stream on western slope of mountain. The basal contact of the intrusive trachyte may be seen on the right-hand slope on the sky line; the whole of the rock stream is below this level. r^^ B ROCK STREAM FROM EAST SIDE OF SLIDEROCK RIDGE, NEAR HEAD OF CASCADE CREEK, ENGINEER MOUNTAIN QUADRANGLE. SLIDEROCK RIDGE. 39 from the cliffs of Grayrock Peak for three-fourths of a mile and descending about 1,000 feet. It has all the marked features of rock streams and from favorable points of view is clearly dis- cernible at a distance of 6 miles or more. The rock fall resulting in this stream was apparently due to undercutting by bergschrund erosion at the rear of the cirque. In the smaller cirque on the south face of Grayrock Peak there has been repeated falling of trachyte from all sides, so that the floor is deeply covered with debris. A marked stream descends several hundred feet below the base of the trachyte, but its upper border is obscured by talus and recent small falls. Some small rock streams were noted on the west slope of the end of Gray sill Mountain, two of them being mapped. Another small rock stream lies beneath the northern face of one of the sharp eastward projections of Graysill Mountain about 3 miles north of Grayrock Peak. It is clearly the result of a single rock fall and not one secondary movement of talus. The ridge presents an abrupt face of trachyte about 500 feet thick for a distance of nearly a mile, with considerable talus at the base of the cliffs, but directly above the rock stream is a well-marked scar indicating that a projecting point or great slab of rock has fallen. Another smaller fall occurred at the end of the side ridge, and between its debris and the larger rock stream there is only common talus. SLIDEROCK RIDGE. The name Sliderock Ridge has been given to the divide between Cascade Creek and the head of Dolores River, south of Grizzly Peak. The ridge is a continuation of the Graysill divide, but the features of the two are very unlike, although they are in both cases due to intru- sions of trachyte. Just above where the trachyte of the Graysill divide ends in wedge form beneath the Triassic beds, intrusive sheets of the same rock appear 1,000 feet higher in the Mancos shale near its base, and extend northward 2 miles to the monzonite stock of Grizzly Peak, which cuts them off. There are several sheets in some parts of this ridge, with thin bands of shale between them, but the shale partings are evidently not continuous. The max- imum preserved thickness of the trachyte is nearly 1,000 feet. The rock is altered and iron stained, and irregular jointing is more pronounced than columnar. At the present time the main ridge and its principal spur present smooth but often steep slopes of trachyte debris. In but few places are there cliff exposures. Talus accumulations are of unusual volume, and below them at several localities rock streams are prominently developed. The highest summit of Sliderock Ridge is a rounded peak, 13,148 feet in elevation, close to the quadrangle line and the contact with the monzonite stock. The base of the trachyte sheets in the basin immediately south of this peak is at 12,000 feet and the intercalated shale bands are relatively very thin. The western face of this peak and of the ridge leading south from it is a graded slope of trachyte debris covering rock in place, passing into talus below the contact, and then, gradually assuming rock-stream form, it extends far down the western slope. Underneath this rock stream is Mancos shale, with gentle westerly dip. The stream is a mile or more in length and is nearly as broad in its upper portion. The rock stream has the usual thickness of 50 feet or more and well-defined borders, but evidently there has been frequent recurring slumping or slipping on the shale surface and the whole mass is creeping down the slope. The immense volume of the debris is the principal objection to considering this stream as talus creeping down a slope of soft, moist shale. But if the debris be restored in imagination to the mass of trachyte, it becomes plain that very bold relief must have once existed, probably strongest just after the recent glaciation, and that conditions were ideal for landslides or rock falls. That unstable talus accumulations are not the immediate cause of these slides is indicated directly on the east side of the spur leading southeast from the 13,148-foot peak. This spur (PL XIX, B) is the one facing Cascade Creek for about a mile south of the quadrangle line. From three distinct places on this minor ridge most clearly defined rock streams descend While talus is heavy all along the slope of the spur, there is nowhere an accumulation approach- 40 LANDSLIDES IN THE SAN JUAN MOUNTAINS. ing the amount of debris contained in these rock streams, nor is there anything at the points where the streams occur to make plausible the assumption of extraordinary talus piles. In the basin on the south face of the 13,148-foot point, between the southeast spur and the main ridge, there are also rock streams of considerable magnitude. CONDITIONS FAVORABLE TO LANDSLIDES OF TRACHYTIC ROCK IN ENGINEER MOUNTAIN QUADRANGLE. The presence of great sills or sheets of trachyte, intrusive between sedimentary beds, at elevations above or near timber line is peculiar to the quadrangle. That landslides have been especially numerous about most of these masses seems due chiefly to four conditions: 1. These masses occur immediately adjacent to the high San Juan Mountains, and as they cap ridges or divides between Hermosa Creek, Cascade Creek, and the Animas they were so situated as to be carved in very bold relief by the valley and residual glaciers. 2. The trachyte is strongly jointed, usually in columnar style, normal to the exposed lower contacts ; this promoted production of bold relief. 3. The rocks below were relatively very soft, and undercutting by ice at favorable localities was doubtless pronounced. Water must gain access readily to these underlying beds through the vertical joints of the trachyte and tend to soften them at many places. 4. It is probable that the inclined attitude of the columns, as in Engineer Mountain, has been an important element in producing unstable equilibrium of exposed portions of the trachyte. That rock streams are here so universal as a result of rock falls is primarily due to the much jointed conditions of the trachyte. Nowhere are there landslide blocks of notable size. The rock stream west of Sliderock Ridge is a case where creep of landslide debris has probably extended the stream to no small degree. SLUMGULLION MUD FLOW. The remarkable mud flow that dammed Lake Fork of the Gunnison and caused the for- mation of Lake San Cristobal, in the San Cristobal quadrangle near Lake City, was observed by Endlich and described by him in the report of the Hayden Survey for 1874.° It has recently been examined byJohannsen and Cross in a preliminary way, and the following data are sup- plied by Cross: The flow starts, at an elevation of about 11,500 feet, in a basin or cirque of not very pronounced relief situated on the south face of a ridge of volcanic rock which forms the divide between the Lake Fork and Cebolla Creek. The crest of the ridge, of plateau-like character, is just above the head of the flow. Volcanic rocks occur in nearly horizontal position and consist of alternating beds of tuffs and flows of rhyolite or latite. The determining factor of the mud flow is, however, not specially connected with the kind of rock or its mode of occur- rence, but with its extremely decomposed condition. At a number of places east of the Lake Fork and within a few miles of Lake City igneous rocks of different kinds have been very extensively decomposed by apparent solfataric agencies. At the source of the Slumgullion mud flow certain rocks have been so decomposed that much of the material is a soft crumbling sand consisting of residual rock with abundant particles of gypsum and native sulphur. The nature of the rock decomposition has not as yet been studied in detail. The important thing is the physical character of the altered mass. Apparently, this alteration had been especially thorough beneath several massive latite flows which form the upper 200-300 feet of the ridge referred to, and at the extreme head of a small side tributary of Slumgullion Gulch. These overlying rocks were also extensively decom- posed. At a certain time, perhaps during some abnormall}" wet season, this incoherent decom- posed material became so extensively softened as to be unable to bear the load of rock above and gave way; the overhung material broke into fragments, and the whole mass of mud and rock fragments rushed as a flow southwesterly down the lateral gulch to the main Slumgullion a Endlich, F. M., Ann. Rept. I1. S. Geol. and Gcog. Survey Terr, for 1874, p. 203. CLASSIFICATION OP LANDSLIDES AND THEIR CAUSES. 41 and due west down that to the Lake Fork, 6 miles from the place of starting. On reaching the Lake Fork, whose course is here at right angles to Slumgullion, it turned north and ended about three-fourths of a mile below the mouth of the Slumgullion. The volume was sufficient to dam the main stream and to cause the formation of Lake San Cristobal, which now extends for nearly 2 miles up the Lake Fork valley. The end of the flow is at about 8,900 feet — 2,600 feet below its head. The accompanying view (PI. XX, B) of this flow, taken by Cross from an elevation of 1,600 feet above Lake San Cristobal, graphically illustrates its form and topographic relations from the source to the Lake Fork. In striking contrast to most of the landslide districts thus far considered, the country adjacent to this flow is of moderate relief. This is largely due to glacial and other superficial material and in minor degree to the decomposed condition of underlying rocks similar to that at the head of the flow. The sparse forest growth on the surface of the flow shows that the flow occurred many years ago. On the upper part of the flow the trees are in many places overturned or tilted at various angles, testifying to recent movement, while on the lower portion such disturbance is only local. CLASSIFICATION OF LANDSLIDES AND THEIR CAUSES. Landslides have long been subjects of vital interest to dwellers in mountain regions, and it is natural that most of our information and knowledge of them should have come from such thickly populated mountains as the Alps. In'addition to their more human interest, the part that they have played in the wasting of the land has long been recognized by geologists. HELM'S OBSERVATIONS IN THE ALPS. Professor Heim was one of the first to make a special study of landslide phenomena in the Alps," and his writings on the subject are to-day among the foremost contributions to the literature of landslides. Heim's classification of landslides is comprehensive, and is as follows: f I. Schuttrutschungen (soil slips). Schuttbewegungen (movements involv- n Schuttsturze (earth slides or falls of ter ing detritus). magnitude than I). Felsbewegungen (movements involvingJIII. Felsscblipfe (rock slips). solid rock). | IV. Felssturze (rock falls). V. Gemiscbte und zusammengesetzte (compound slides, with respect to character of move- ment and of materials). VI. Besondere (unclassified and special cases). It is almost impossible to translate these terms literally into English without conveying false impressions; in fact, Heim himself comments on the use of the word Bergsturz, stating that it should be understood to mean the "fall of more or less material from the side or face of a mountain" and not the "fall of a mountain." It is unfortunate that the two English words "landslip" and "landslide" should be used to designate all classes of this general type of land wasting, since both slip and slide imply smooth and easy motion, while there is no term in common use to describe such movements as are referred to by Germans as Felssturze and to bring out the distinction between them and Felsschlipfe. Heim's first two cases, in which detritus alone is involved, differ from one another only in degree, the first being a simple downward movement or slumping of soil, morainal material, or debris in other forms, while movements of the second type are more violent and comparable to snowslides or avalanches. Movements of the third and fourth types, involving solid rock, are more complicated. Heim restricts the term Felsschlipf, or rock slip, to cases where stratified rocks have a dip in the direction of the slope of the hill of which they form a part, and slipping begins along bedding Bergstiirze (landslides). a Heim, Albert, Ueber Bergstiirze, Zurich, 1SS2. 42 LANDSLIDES IN THE SAN JUAN MOUNTAINS. planes of the rocks, while uie term Felssturz, or rock fall, is applied to the movement of rock masses independent of their original attitude or individual character. Heim remarks that, in consequence of this, rock slips are much less apt to occur than rock falls. In illustration of these two types, Heim describes the classic landslide of Goldau and that which destroyed the village of Elm. In the case of the Goldau landslide enormous masses of conglomerate and sandstone became loosened along the lines of their stratification and slipped bodily from the face of the Rossberg to the valley at its foot. The inclination of the beds was about 12°, while that of the slope on which they slipped was about 20°. The landslide which destroyed the village of Elm in Canton Glarus in September, 1881, was brought about very largely by the hand of man. A bed of slate dipping into a hill over- looking the town had been worked as a quarry for many years, and no means taken to support the roof or hanging wall. The overlying strata, gradually undermined, finally broke away from the hill after an unusually wet season, and by their fall demolished the village and killed many of the inhabitants. In this case the fracturing that separated the mass that fell from the solid rock of the hill took place across the bedding planes. The falling of the rock was observed by many persons, and their accounts, as recorded by Heim, will be referred to later (p. 50) in discussing the origin of the rock streams." It is interesting to note that a landslide occurred under essentially the same conditions some few years ago in the Canadian Rockies, partly demolishing the small town of Frank, Alberta.6 Although the cause of the Elm landslide is to be regarded as a rather peculiar and special one, yet it is believed that slides very similar to this in general characteristics have occurred in the San Juan Mountains. Heim's fifth type, that of compound landslides in which one or more of the simpler kinds of movements are combined, receives less attention than the preceding types. Two illustra- tions are given of this kind of landslide. The first started as an extremely slow, gradual Felsschlipf, or movement along the inclined bedding planes of the rocks involved. The move- ment continued as a slow creep for a number of years, during which time all semblance of the original bedding of the slipping mass was entirely lost, and a large area was covered by completely broken up rock material. The second example was that of a large mass of limestone splitting off transversely to its bedding from a cliff face and falling upon an accumulation of clayey detritus saturated with water, which, with this added load, began itself to slip. The detritus involved in this second movement, together with the blocks of limestone that had fallen upon it and started it, in the course of its slow onward movement came to the edge of a ravine, into which it fell, damming the stream and forming a small pond. The movements in this case were at first a Felssturz, which in turn started a Schuttrutschung, which eventually developed into a Schuttsturz. This class may be regarded as an extremely useful one, into which may be grouped all land- slides that do not fall naturally with any of the earlier types. The sixth and last type, Besondere Bergstixrze, includes such cases as soft clays squeezed out between heavier massive beds and caused to flow as mud streams. Here also belong coastal slips, which are supposed to have originated in a similar manner, and also movements along the faces of alluvial fans entering lakes, caused by the squeezing out of soft clays in the lower parts of such deltas. Slips along roadways or railway cuttings and cavings due to mining operations are likewise included in this last group. Heim recognizes four fundamental causes of the occurrence of landslides, as follows: 1. Undermining, either by natural processes or by the hand of man. 2. Inherent weakness of underlying beds. 3. Earthquakes. 4. Stresses within the mountains themselves, which seek readjustment on account of changes due to erosion and weathering. a Buss, E., and Heim, A., Dor Bergsturz von Kim: Zeitschr. Deutsch. geol. Gesell., 1882, pp. 74, 435. b McConnell, R. G., and Brock, R. W., Report of the great landslide at Frank, Alta., 1903: Ann. Rept. Dept. Interior, Canada, 1903, pt. 8. CLASSIFICATION OF LANDSLIDES AND THEIK CAUSES. 43 In addition to these, except possibly in those cases due to earthquake or readjustment of stresses, the excessive saturation of the ground or weakening of the strata through the presence of water must be regarded as a final or extremely important cause of all landslides. A dis- tinction is made between the remote and the immediate causes. Conditions favorable to land- slides may continue for long periods, and yet no movement may take place until some event, such as an unusual amount of rainfall or an earthquake, gives the touch necessary to start the unstable mass on its downward movement. penck's views. Penck has stated very clearly the theoretical conditions which control the more remote causes of landslide action.3 If 67 equals the weight of a mass of rock undermined or in more or less unstable equilibrium, and F a surface, inclined at an angle (fig. 4) from the horizontal, which is that of least cohesion of the rock mass with the parent rock, the value of this cohesion for the unit of surface being c, and p equals the coefficient of friction, then the downward pull of the mass is 67 sin a; its cohesion with the country rock Fc, and its friction on the same 0 cos ap. The mass will then remain in its position as long as 67 sin a < G cos ap+ Fc; or, if p = tan co, then — 67 sin (a — to) cos CO co if there is no room or opportunity for movement in the direction in which the maSS is inclined. ditions controlling landslide action. (Copy of The angle of inclination 3 of the face of the cliff (in the diagram inPenck's MorP»e, vol. i,P. 223.) same plane) must be steeper than the angle a of the cleft or joint plane in order that movement may take place after the elimination of cohesion; that is, movement will occur when /? > a > co. Rock masses in which such conditions prevail may be designated as undermined or over- steepened, and in them a yielding or weakening along joint planes is necessary to cause a landslide. Such, without going into further detail, may be regarded as the internal conditions gov- erning landslides. These relations probably hold true for all classes of material, with the exception that in the case of detritus or clays cohesion becomes an element of greater impor- tance than simple friction. It is agreed by all observers that conditions favorable to landslides as expressed by a > co, or /? > a > co may continue for long periods without any movement on the part of the threatened mass, and that some external element is necessary to give the final shove, as it were, which sets the unstable material in motion. Probably the commonest of the external causes of landslides is the saturation of the ground by meteoric waters. By this process the weight, 67, is increased and the coefficient of friction reduced, while if the element of cohesion enters into the conditions it also may be affected by the presence of water. In a large majority of landslides of which there are definite records and the preexisting conditions are known, long- continued or unusually heavy rains occurred before slipping took place. The Elm landslide and the Cimarron slide in Colorado suggest themselves at once as illustrating this point. Another external element, of which there are fewer authentic records, but which is doubtless none the less potent in causing the downfall of masses of rock in unstable equilibrium, is an earthquake, which Heim includes in his list of four principal causes. There are few accounts a Penck, Albrecht, Morphologie der Erdoberflache, I, 1894, pp. 222-231. 44 LANDSLIDES IN THE SAN JUAN MOUNTAINS. of earthquakes in regions of considerable relief that do not record the occurrence of landslides, and some slips of great magnitude have occurred, as that at Calabria in 1783, by which the form of both mountain and valley was considerably altered. The existence of stresses within mountain masses is well recognized by engineers who have been engaged in tunneling operations in mountain regions, as in the case of the St. Gothard tunnel. The suggestion by Heim that such stresses may, in some cases, account for landslides is well worthy of consideration, but it is obviously very difficult to place the responsibility for landslides on so obscure a cause, and one would naturally hesitate to appeal to such a hypoth- esis unless all other causes were out of the question. It is probable that landslides attributed to this cause — the sudden release of internal stresses in the mountains — may take place without any of the preexisting conditions suggested as necessary by Penck. Keeping these general facts and theories in mind, we may turn to a consideration of the causes and character of the San Juan landslides. In the description of some of the landslides the evident cause of the slipping was stated, but in other cases, on account of greater com- plexity or obscurity, the discussion of the causes of the slides was deferred to this part of the paper. Cross has already stated his theories as to the origin of the Telluride and Rico land- slides, and the present writer agrees with him in large part. NATURE AND CAUSES OF SAN JUAN LANDSLIDES. It has already been shown in the description of the San Juan landslides that certain of them occurred in regions of sedimentary rocks, while others were restricted to areas in which volcanic rocks only were present. In taking up the discussion of the nature and the causes of these landslides it is well to recognize this distinction, since certain of the slides are in all probability due to the fact that sedimentary rocks of varying degrees of hardness or resistance have been involved. In considering the causes of these landslides three sets of conditions must be analyzed. These are the physical condition of the rocks affected, such as jointing or shattering and the relation of hard and soft layers; the structural conditions of the same rocks; and, finally, the topographic conditions. PHYSICAL CONDITION OF ROCKS AFFECTED BY LANDSLIDES. Sedimentary rocks. — Although almost all of the sedimentary rocks found in the San Juan region have been affected by landslides, certain formations have been particularly subject to these movements. In general, there appears to be a definite relation between hard massive beds involved in the slides and soft yielding ones which underlie them. Of the soft or incom- petent formations none has figured so prominently in landslide action as the Mancos shale, which consists almost entirely of very soft, friable, sandy shales with a thickness of about 1,200 feet. The lack of firmness or security in the foundation of such rocks is obvious, and some of the largest landslides of the region, such as those of the Telluride and Ouray districts and the Cimarron landslides, are to be attributed to the inability of the Mancos shale to support heavy loads. Landslides characterize the entire zone in which the volcanics rest on the Mancos shale on the north side of the San Juan Mountains' from the Uncompahgre Valley eastward. Rocks of the Hermosa and Cutler formations have been involved in many landslides in the Rico, Hermosa Creek, and Canyon Creek (Ouray) districts and on the southern slopes of the Needle Mountains. Although variable in the character of its beds, the Hermosa formation is usually shaly or consists of soft friable sandstones near its base, wliile in its upper portion heavy beds, either of limestone or of massive sandstones or conglomerates, occur. The ina- bility of these underlying beds, to support the load of the higher horizons is believed to be one of the important causes of the landslides of Hermosa Creek, Canyon Creek in the Needle Moun- tains, and the creek of the same name near Ouray. In the Rico district, although the relation of hard and soft layers figures prominently in the occurrence of landslides, the movements in CLASSIFICATION OF LANDSLIDES AND THEIR CAUSES. 45 that region must be attributed in part at least to forces of greater potency, as suggested in a later paragraph. Volcanic rocks. — In the cases of landslides that have occurred in regions of volcanic rocks alone, somewhat similar conditions have prevailed in certain places. In such instances the weak, incompetent rocks have been relatively soft or partly consolidated tuffs, or rocks that have undergone much decomposition. The landslide that occurred near the headwaters of the Rio Grande may be mentioned as an example of movement due in part at least to such a cause. Where volcanic rocks have been involved in landslides, however, more complex causes have usually prevailed, and in some examples no evidence has been found of a yielding or incompetent layer underlying the material which fell. Other conditions of physical weakness that have played important parts in the occurrence of landslides in regons of both volcanic and sedimentary rocks are those of an extensive primary jointing and secondary shattering. Of the jointing the best examples are to be found in the trachyte sheets of Engineer Mountain. In. the Rico landslide district the shattered condition of the rocks is particularly noteworthy, as was pointed out by Cross in his discussion of the landslide phenomena of that district.0 Cross considers that this shattering has been the most important internal cause of the Rico landslides, and emphasizes the fact that the shattering is independent of the lithological character and structural attitude of the formations involved, and that there is nothing in either of these conditions especially favorable to landslides. In fact, as was pointed out in the description of the landslides, the attitude of the beds is that of structural strength rather than weakness at points where slips have occurred. Similar conditions are believed to have existed, though in a less marked degree, in the Red Mountain district. In this area volcanic rocks alone have been involved in the landslides, and the influ- ence of hard and soft layers may be practically eliminated from the discussion of the causal conditions of these landslides. It is, however, a region of pronounced fracturing, as shown in the numerous fissure veins, and is near a center of marked decomposition in which all the rocks of the Silverton volcanic series have been involved. In this area the rocks can hardly be described as shattered, but they are traversed by an extremely intricate system of joints, a condition clearly shown when one attempts to trim a small hand specimen, a light blow being sufficient to cause a small block to break into innumerable angular fragments bounded by joint planes intersecting at all angles. Although decomposition of the rocks has doubtless played a part in the Red Mountain landslides, this internal cause of landslide action can not be regarded as important. Its best example is found in the Slumgullion mud stream or slip, as was pointed out in the description of that occurrence. STRUCTURAL CONDITIONS. Structural conditions have played little or no part in the San Juan landslides. The Rico district is the only one in which the sedimentary beds have suffered marked deformation, and there, as has been already pointed out, landslide action has been confined to the eroded center of the dome, the lines along which the landslide masses separated from their original positions being transverse to the bedding of the sedimentary rocks. Instances of Felsschlipfe, or land- slides in which movement has taken place along bedding planes in the direction of dip, are of minor importance. One example is known — in Elk Creek on the northern slopes of the Needle Mountains — in which the attitude of the beds is regarded as largely responsible for the occurrence of landslides. There massive quartzites and slates of the Algonkian dip at angles of 35° to 45° in the direction of the valley, and a landslide of great size has occurred, whose debris lies partly on the hillside and partly covers the floor of the valley. In all respects it corresponds to the typical Felsschlipfe of the Alps and is much like that of the famous landslide of Goldau. It is noteworthy that the form and appearance of the deposit of landslide debris in the valley are those of a rock stream. a Cross, Whitman, and Spencer, A. C, Geology of the Rico Mountains, Colorado: Twenty-first Ann. Rept. U. S. Geol. Survey, pt. 2, 1900, pp. 145 et seq. 46 LANDSLIDES IN THE SAN JUAN MOUNTAINS. In the Rico district, as well as in certain parts of the Silverton area and elsewhere, promi- nent fault systems have doubtless had something to do with the cause of landslide action, but, as pointed out by Cross in his discussion of the subject in connection with the Rico landslides, some of the regions of most intense faulting, as in Silver Creek, are almost free from landslide phenomena, while many of the most pronounced landslide areas are not those in which faulting of any consequence has taken place. TOPOGRAPHIC CONDITIONS. All of the conditions thus far considered have been those involving the elements of cohesion and friction of Penck's analysis. The angle /? of the cliff face is essentially a topographic con- dition, and is believed to have been one of the most important of the causes or conditions governing landslide action in the San Juan region. At the final retreat of glacial ice this mountain region was characterized by bold and rugged topography, and evidence of this may still be found in favored localities. Conditions of oversteepness on the part of valley walls existed in a great many places. In certain of these localities the rocks possessed sufficient stability to resist the forces which in other localities caused enormous masses of rock to. fall from their insecure positions to the valley bottoms as landslides. This condition of oversteepness must have existed very generally throughout the San Juan Mountains, although especially well developed in certain parts and less so in others on account of the character of the rocks. It is a noteworthy fact, as stated in the description of more than one locality, that no landslides have occurred at many points where the conditions would seem to be most favorable and of essentially the same character as those that are assumed to have contributed to the cause of landslides at other localities. This fact only serves to emphasize the point brought out later, that at few places can the landslides of the San Juan Mountains be attributed to any single cause, and although the influence of oversteepness or of topographic conditions is believed to have been a powerful one, in a great many cases it can not be regarded as the all-important cause. All of the conditions thus far considered are of the kind referred to in an earlier paragraph as internal causes of landslides, and of these the physical condition of the rocks and the topographic conditions have been by far the most important, the structural attitudes of the formations involved in sliding being of so little importance as to be negligible. EXTERNAL CAUSES. Three external causes are believed to have been responsible for the initiation of movement on the part of the landslides in the San Juan, acting either independently or together, but in all cases at points at which internal conditions favorable to landslide action existed. These three causes are earthquakes, the readjustment of internal stresses in the mountains, and the saturation of the ground by meteoric waters. In considering the origin of the Telluride and Rico landslides, Cross lays great stress on the importance of earthquakes. In the case of the Telluride slides the occurrence of Mancos shale below massive volcanic rocks which are traversed by fissures, permitting the descent of surface waters to the underlying sandy shales, presents favorable internal conditions for land- slides, but the magnitude of these occurrences seems to Cross to require nothing short of an earthquake shock to start landslide movement, and the present writer concurs in this opinion. In considering the origin of the Rico landslides, Cross,' after mentioning their superficial character and their relation to the topography and to the existing faults of the region, which have been referred to briefly in the present paper, takes up specifically the question of their origin. He says, on page 149 of the Rico report: The immediate cause of the Rico landslides is manifestly the very unusually shattered condition of the rock formations on steep slopes, and the discussion of origin must be directed to the seat and nature of the force to which the intense shattering is due. The evidence concerning this force contained in the observations which have been recorded may be summarized as follows: 1. The principal landslides are confined to a small circular area in the heart of the Rico uplift, but do not cover all of that area. CLASSIFICATION OF LANDSLIDES AND THEIK CAUSES. 47 2. The slides are more recent than the topographic details of the mountains and valleys, excepting only some recent and minor features. 3. The shattering of the rocks varies locally in degree. 4. The shattering is independent of lithological character and structural attitude of the formation, and there is nothing in either of these conditions especially favorable to landslides. 5. The principal landslide slopes are in the courses of many known faults, but several intensely faulted areas of rugged topography do not exhibit landslides. 6. Many fault veins seem to have been opened again by the shock producing the shattering of the formations. 7. The shattering extends below the surface zone of actual sliding, and to unknown depths. The consideration of all observed facts leads to the comprehensive statement that in geologically vefy recent time a part of the central portion of the Rico Mountains suffered a severe shock, shattering the rocks at the surface and to unknown depths. As a result of this shattering many landslides have occurred where other conditions were favorable. This shock must have had its source in greater or less depth, and may be referred to as an earthquake shock. Two sources of earthquake shock are recognized, namely, the release of tensions resulting from structural movements of the earth's crust, and volcanic energy. Continuing, Cross says: The Rico Mountains represent a center of upheaval and intense- faulting, and of igneous intrusions of a nature not strictly volcanic. It seems natural to suppose that seismic disturbances must have taken place at the surface of the Rico dome during the periods of faulting and during the intrusion at least of the monzonite magma in the channels represented by the stocks of to-day. But those disturbances took place at so distant an epoch that the connection of the shocks now under discussion with either of them is not plausible. Cross considers the recent movement along old fault lines as a possible cause of earthquake action. Supposing the recent shattering of the rocks of the Rico district — to be the result of faulting, an adjustment of the rocks under stresses still existing at this center of uplift, the opening of old faults may be explained, and the great shattering on new and irregular fractures may be regarded as a natural distribution of the shock in the superficial zone, where resistance to fracture is less than in depth. But while little positive evidence appears to oppose this hypothesis, it must be considered remarkable that Silver Gulch, the locality of most intense and deep-seated faulting, judging from surface dislocation, has not been the scene of landslides. On the other hand, the locality where the shattering force seems to have vented itself in greatest violence is certainly not one of the principal fault areas of the region, although some faulting is to be considered probable. In Cross's opinion, the earthquake is to be attributed to volcanic forces. After referring to the fact that Rico lies adjacent to the great San Juan volcanic area, which is one of the most extensive in the United States, and that it is reasonable to assume that earthquakes have occurred from time to time in this region, Cross goes on to show that with a given violent disturbance, of volcanic origin, beneath the Rico dome the resulting shock might be trans- mitted to the surface in one of several ways. Such a disturbance of deep-seated origin might cause movement along old fault lines accompanied by marked effects at the surface and also a distinct oscillatory or wavelike movement of the ground emanating from the zone of fracturing and due to the sudden shock of faulting. Probably the most pronounced effect at the surface resulting from a deep-seated shock would be brought about by the transmission of the impulse directly to the surface through some homogeneous material, such as the massive rock of stocks. It seems to the writer that there are certain objections to the volcanic origin of the earth- quake shock, chief among which is the fact that volcanic activity ceased in Tertiary time, while earthquakes that touched off the Rico landslides are known to have taken place in Pleistocene or Recent times. Observations in regions of active volcanism tend to minimize the violence of earthquakes attributed directly to volcanic causes alone, while the most violent earthquakes of recent years are not believed to have been connected in any way with volcanic phenomena." The local conditions would seem to be especially favorable to seismic disturbances attributable to crustal movements or to the release of stresses in the mountains. This last condition seems to be well worthy of consideration. It has been shown that the region is characterized by a domelike uplift of sedimentary rocks which were intruded, either at the time of the uplift or immediately preceding it, by sheets and stocklike masses of monzonite porphyry — conditions especially favorable to the introduction of stresses that would naturally a Geikie, Archibald, Text-book of geology. 4th ed., vol. 1. Dp. 369-370. 79146—09 4 48 LANDSLIDES IN THE SAN JUAN MOUNTAINS. seek readjustment from time to time during the process of the dissection of the dome. It would seem that the shattering of so much of the rock of the region might be attributed directly to such readjustments without necessarily implying recent movement along old fault lines or that the shocks causing such shattering were also the ones that started landslide movement at the same localities. Although the shattering of the rocks is known to extend to considerable depth, as shown in many mines, it was pointed out in the earlier description of the Rico district that the land- slides were essentially superficial in character, and in a majority of cases the present features are the result of repeated slips, so that one must assume repeated earthquake shocks to jar off the shattered material from its position of rest on the hillsides. It is necessary to suppose some rather unusual condition to explain the extensive shattering of the rocks in the Rico region, and the readjustment of strains in the deformed region would seem to account for this in a satisfactory way. As has been said, it need not necessarily follow that the shocks resulting from such readjustments were the same ones that caused the beginning of landslide movement; on the contrary, it is natural that such shocks should be repeated frequently during the process of readjustment. Readjustments of this nature may not be deep seated in origin or directly related to movements along old fault lines, but may be purely superficial and comparable to the release of strains in unannealed glass. At the same time it is not improbable that movements of deep-seated nature may have taken place along some of the old faults. Recent movements occurring along the faults of Silver Creek might have resulted in earthquake shocks of great violence at points at some distance from this center, while Silver Creek itself might have been practically unaffected. The writer agrees with Cross that, in the case of the Rico slides at least, appeal must be made to earthquakes to account for their occurrence ; the exact cause or nature of these shocks is, after all, a matter of secondary importance. Although earthquakes may be recognized as a cause of many landslides, they need not be called upon in all cases to account for the San Juan landslides. Excepting the absence of corresponding structural conditions, the landslides of the Red Mountain district in many respects are of the same character as those of the Rico region, and one feels compelled here to apply the earthquake theory on account of the lack of any other satisfactory explanation. According to H. C. Lay,a minor earthquake shocks have been felt from time to time in the San Juan region. One that occurred on the 1st of January, 1894, was felt at Telluride and at Red Mountain, some 6 miles to the east. Men at work in a number of mines were driven to the sur- face as a result of the shock, while other persons at near-by points did not notice the earthquake. It is reported that slight earthquake shocks followed the first one on the two succeeding nights. In the summer of 1897 three more shocks were noticed at Telluride and Ouray, and at Ridgeway, 15 miles to the north, which is built on alluvium filling the Uncompahgre Valley. The first of these shocks was violent. Lay remarks that "it is likely that slight earthquakes are more common than is generally believed, escaping notice during the day on account of other noises, and not identified at night because mistaken for distant blasts or else because not then perceived by reason of the heavy slumber general in high altitudes." As for the other landslides of the San Juan region, it is believed that the simple agency of water is sufficient to account for their final movement. The mountains to-day are, throughout a large part of the early summer, subject to excessive rainfall, and to this cause the Cimarron landslide was directly attributed by Cross. Localities where this cause alone would be sufficient to start landslide movement may be found in all parts of the mountains. Practically all of the landslides of the Ouray district are of this character, as are those of Hermosa Creek and Canyon Creek in the Needle Mountains. A further point in favor of such a direct cause is found in the fact that in almost all of the landslides described the present form of the fallen material seems to be due to repeated falls of small blocks rather than to one great downfall — a process naturally to be expected in cases where favorable localities were affected by wet-weather conditions. a Recent geological phenomena in the Telluride quadrangle, etc.: Trans. Am. Inst. Min. Eng., vol. 31, 1902, pp. 558-567. NATURE AND CAUSES OF ROCK STREAMS. 49 SUMMARY. Briefly summarized, the probable causes of the San Juan landslides may be regarded as of two kinds: (1) Those due to the internal condition of the rocks in the areas affected; and (2) those due to certain external forces or impulses. Of the first, the physical condition of the rocks themselves is probably the most important, and involves not only the relation of massive beds resting upon insecure foundations, but also a jointed or shattered condition of the rocks. Topographic conditions as expressed in oversteep slopes have also played an important part in the occurrence of landslides. The external causes appear to be essentially two — those in the nature of earthquake shocks and others due to the saturation of the ground from excessive rainfall. Earthquake shocks, or, what may possibly be regarded as the same thing, the readjustment of stresses within the mountains, are doubtless responsible for the shattered condition of the rocks in certain localities, as well as being the final cause of the movement. NATURE AND CAUSES OF ROCK STREAMS. Rock streams were first described in the Silverton folio (No. 120), and their origin was briefly discussed. It was shown there that for obvious reasons, such as their distance from the source of supply and the peculiar configuration of their surfaces, they could not be regarded as ordinary talus accumulations. It was stated (on page 25 of the text of the Silverton folio) that "the more streamlike of these deposits, from their configuration, from the nature of the materials composing them, and from their relations to the cirques or corries in which they occur, are to be considered as rather unusual types of moraines." The debris was supposed to have been supplied as a result of landslides to the surfaces of small glaciers which lingered on in the cirques some time after the retreat of the ice in the main valleys. In this place something more may be said concerning these remarkable accumulations. IMPORTANT FEATURES OF ROCK STREAMS. The most important and peculiar features of the rock streams brought out in their descrip- tion in earlier pages may be repeated here for purposes of discussion. In general appearance these accumulations resemble long tongues or lobes of talus stretching far out from the base of the cliffs from which they were derived over the nearly level or gently sloping floors of the cirques. The deposits are usually bounded by a sharply defined steep front or outward face or embankment. Their surfaces are seldom smooth, but are marked by irregular hummocks separated from one another by deep, narrow depressions, or by concentric ridges that he one within another from the end of the stream inward. The material of the rock streams consists of angular blocks of rock, variable in size, but usually averaging about a foot in diameter. Masses 15 feet or more in diameter are not uncommon, while an abundance of fine angular gravel or coarse sand is noticeable near the outer margins of these rock streams, especially at the foot of the steep embankment. Very broadly considered, these rock streams have certain features in common both with landslides and with ordinary talus accumulations. The character of the detritus is essentially the same as that composing raw, fresh talus slopes, while the relation of the material to its source of supply is similar to that which exists in the case of landslides. The distance at which the material lies from its source is also comparable to that of fallen landslide material. The outlines of many of the rock streams again resemble those of accumulations of landslide debris. The configuration of the surface of these deposits differs almost as strongly from that of the familiar landslides of the San Juan Mountains as it does from talus. In practically all of the San Juan landslides the hummocked surface, to which the mammillary or ribbed surface of rock streams might be regarded as analogous, is due to fallen blocks, shattered perhaps, but still more or less massive and retaining in general the form in which they descended the path from their source. In the few instances where the debris lies in the form of loose scattered rock, as on Landslip Mountain in the Rico region, on the south slope of Sheep Mountain near 50 LANDSLIDES IN THE SAN JUAN MOUNTAINS. the headwaters of the Rio Grande in the Silverton region, and perhaps in the case of the land- slide in Cleveland Gulch, that feature seems to be due to the secondary breaking up of the fallen blocks, although, as was said in the description of the Cleveland Gulch occurrence, this relation is not altogether certain. That the rock streams have developed their present form through the crumbling or breaking down of large landslide blocks is improbable, largely because of the difficulty of accounting for the presence of blocks of sufficient size to bring about such accumulations at such distances from their source of supply. The actual distance might be no greater than that at which even larger blocks may lie in the case of landslides, but with the rock streams the slope upon which such blocks should have had to descend is usually of too low an angle to permit the assump- tion that they could have reached the required position through the result of simple landslide action. It was largely on this account that in the text of the Silverton folio the landslides were supposed to have taken place upon small glaciers which transported the blocks across the gently sloping floor of their cirques and deposited them far from their source. It was also supposed that the gradual settling of such material on the surface of a melting glacier might account for the peculiar configuration of the surface of the deposits. Such a theory is an entirely plausible one, and in many instances there are no serious objections to its application. In certain cases, however, there are decided difficulties in applying such an explanation. The rock stream of Imogene Basin may be cited in this connection. This stream lies on the west side of the basin rather than in the middle. It is difficult to conceive of glacial conditions that could have permitted the deposition of this material in such a simple straight line traceable directly back to its source, which is at the base of a salient cliff and not at the head of a cirque or valley, as shown in Plate XIV, B. Even more striking instances of rock streams descending from the sides of valleys are found in North Fork of Henson Creek on the north side of Dolly Varden Mountain and near the head of Bear Creek, a tributary of Uncompahgre River, where, as shown in Plate XX, A, a tongue, more or less talus-like, it must be admitted, but still possessing many rock-stream characteristics, extends outward from the northern ridge toward the center of the valley. Another instance, and perhaps the best, is shown in Plate XIX, B — a rock stream from Slide- rock Ridge near the head of Cascade Creek, in the Engineer Mountain quadrangle. In these cases it would seem impossible to assume that the material or debris had reached its position through the agency of glaciers. It was shown in the Silverton folio that after the time of maximum glaciation the walls of the cirques were left in an oversteepened condition by the sapping or undermining action of the ice at the Bergschrund, and that at the disappearance of the ice these walls were left unsupported. It is only natural to assume that landslides ensued. A further cause of landslides may be found in the extremely jointed condition of the rocks found in rock streams. The fact that rock streams do not occur in some cirques and are found in others may be due in part to this condition of the rocks. It is a fact that a majority of the rock streams are found in the region of volcanic rocks, while few are found in the Needle Mountains, which are composed almost exclusively of pre-Cambrian granites, schists, or quartz- ites, although the topography is very bold. In considering the origin of these remarkable deposits one can not help being influenced by Heim's account of the Elm landslide and by the description of the Frank disaster. ELM LANDSLIDE. The Elm landslide is almost the only one of magnitude in modern times whose fall has been described by ej^ewitnesses, and the following account, by W. M. Conway, of the actual progress of the slide is of unusual interest and value as suggesting a process by which the San Juan rock streams may have been formed. Conway," after describing the conditions that existed before the slide, goes on to say: o Conway. Sir William Martin, The Alps from end to end, 1900, pp. 176-183. U. S. GEOLOGICAL SURVEY PROFESSIONAL PAPER 67 PLATE XX A ROCK STREAM FROM SIDE OF RIDGE NEAR HEAD OF BEAR CREEK, SILVERTON QUADRANGLE. ► - *&j . L,M B. SLUMGULLION MUD FLOW, SAN CRISTOBAL QUADRANGLE. Seen from the west above Lake San Cristobal. Shows the flow from its source to the lake. The stream flowing along the southern border of the mud flow is now forming a small delta in the lake, shown on the right of the illustration; the smooth slopes at either side of the mud flow are largely covered by glacial gravels. NATURE AND CAUSES OF ROCK STREAMS. 51 Suddenly, at a quarter-past five, a mass of the mountain broke away from the Plattenbergkopf. The ground bent and broke up, the trees upon it nodded and folded together, and the rock engulfed them in its bosom as it crashed down over the quarry, shot across the streams, dashing their water in the air, and spread itself out upon the flat. A grayish-black cloud hovered for a while over the ruin, and slowly passed away. No one was killed by this fall, though the debris reached within a dozen yards of the inn where sightseers were gathered. * * * This first fall came from the east side of. the Plattenbergkopf; seventeen minutes later a second and larger fall descended from the west side. The gashes made by the two united below the peak, and left its enormous mass isolated and without support. * * * It overwhelmed the inn and four other houses, killed a score of persons, and drove terror into all beholders, so that they started running up the opposite hill. * * * During the four minutes that followed the second fall everyone seems to have been running about, with a tendency, as the moments passed, to conclude that the worst was over. Then those who were watching the mountain from a distance beheld the whole upper portion of the Plattenbergkopf suddenly shoot from the hillside. * * * The mass slid, or rather shot down, with extraordinary velocity, till its foot reached the quarry. Then the upper part pitched forward horizontally, straight across the valley and on to the Duniberg. People in suitable positions could at this moment clearly see through beneath it to the hillside beyond. * * * No individual masses of rock could be seen in the avalanche, except from near at hand; it was a dense cloud of stone, sharply outlined below, rounded above. * * * A cloud of dust accompanied it, and a great wind was flung before it. This wind swept across the valley and overthrew the houses in its path like haycocks. * * * In this last phase of the catastrophe 10,000,000 cubic meters of rock fell down a depth (on an average) of about 450 meters, shot across the valley and up the opposite slope to a height of 100 meters, where they were bent 25° out of their first direction and poured, almost like a liquid, over a horizontal plane, covering it uniformly throughout a distance of 1,500 meters and over an area of about 900,000 square meters to a depth of from 10 to 20 meters. The internal friction of the mass and the friction between it and the ground were insignificant forces compared with the tremendous momen- tum that was generated by the fall. The stuff flowed like a liquid. FRANK LANDSLIDE. The Frank landslide occurred early in the morning, at a time when few people were about, so that there are no very satisfactory accounts of the progress of the slide. Such as they are, they serve to show that the slide was of essentially the same character as that which destroyed the village of Elm. In the Frank landslide the nature and appearance of the fallen material are the features of special interest, and the numerous illustrations accompanying the report show the similarity between the San Juan rock streams and the debris of the Frank slide. An abstract of McConnell and Brock's report" follows. The town of Frank was an important coal-mining center on the Crows Nest branch of the Canadian Pacific Railway, and was situated in a valley at the foot of a high mountain or ridge near the base of which the coal deposits were worked. In the early morning of April 29, 1903, a huge mass of rock, nearly half a mile square and probably 400 to 500 feet thick in places, suddenly broke away from the east face of the moun- tain and precipitated itself with terrific violence to the valley beneath, destroying a portion of the town and killing a number of people. Turtle Mountain, part of which fell away, is a sharp ridge which, with the exception of a short talus slope near the base, rises very steeply in a succession of cliffs to a height of 3,100 feet above the valley. It was the central and highest peak of this ridge that broke away. The mountain consists of Cretaceous sandstones or shales at the base, limestone (part at least of Devonian age) forming all of the upper portion. The limestone has been thrust over the newer rocks along a fault plane by mountain-building forces. The Cretaceous beds were overturned, dipping into the mountain at an angle of 82°, while the limestones have a westerly dip of 50°. The basal beds of the limestones have been much folded and crumpled by friction, due to thrust- ing forward of the series along the fault planes. They form a weak base for the precipitous mass above. The mountain is thoroughly dissected by fractures and jointing planes. DESCRIPTION OF THE SLIDE. The great mass of rock from the central peak, urged forward by the momentum acquired in its descent, and broken into innumerable fragments, plowed through the bed of Old Man River and, carrying both water and underlying sediments along with it, crossed the valley and hurled " McConnell, R. G., and Brock, R. W., Report of the great landslide at Frank, Alta., 1903: Ann. Rept. Dept. Interior, Canada, 1903, pt. 8. 52 LANDSLIDES IN THE SAN JUAN MOUNTAINS. itself against and up the opposite terraced slopes to a height of 400 feet. Blocks of limestone and shale mingled with mud now cover the valley to a depth ranging from 3 to probably 150 feet, over an area of 1.03 square miles. CHARACTER OF THE MOVEMENT. The separated rock mass seems to have been shattered by impacts against the side of the mountain in its descent, and probably long before it reached the bottom, into myriads of frag- ments, some of which were doubtless flung far out into the valley. The movement of the broken rock mass can not be characterized as a slide in the ordinary sense of the word. The rocks must have traveled to their destination largely by a succession of great leaps or ricochets, probably accompanied by a certain amount of rolling and sliding. The character of the movement is clearly shown in the gradually lessening bounds, ending in a short roll of a number of fragments, which were thrown forward beyond the main mass. (Cf . Pis. X, A, X, B, and XII, A.) While the movement of the individual fragments consisted of a succession of bounds from the surface and caroms from flying rocks, the movement of the mass taken as a whole suggests that of a viscous fluid. On the level flat the movement was onward, with a tend- ency toward lateral dilation, but when terraces or other elevations were encountered a portion of the material was deflected and flowed along the obstruction. The cessation of the movement appears to have been remarkably sudden. At a number of points around the edge of the slide the rocks piled up into a high rim, and then, the velocity acquired in their descent becoming exhausted, fell gently forward. The slide rock consists mostly of angular fragments of limestone ranging in size from grains up to great blocks 40 feet in length. Large rocks are common everywhere, and in places, especially along the central portion of the slide, the greater part of the debris consists of frag- ments from 3 to 20 feet in diameter. In portions of the slide the spaces between the rocks are filled with material resembling bowlder clay, probably derived from the bed of Old Man River. The surface of the slide is singularly uneven. The rocks are heaped up into mounds and short interlacing ridges inclosing hollows, somewhat resembling a terminal moraine. In some places the lumpy condition of the surface suggests that the material traveled in waves, the waves retaining their form when motion ceased. The slide rock usually terminates abruptly in a steep slope 6 to 30 feet in height, and in places is heaped up at the edge into a prominent rim. CAUSE OF THE SLIDE. The slide was due, not to a single cause, but to a combination of causes. The primary cause was undoubtedly the form and structure of Turtle Mountain. The mass was in a state of unstable equilibrium, possessed a weak base, and was thoroughly traversed by fissure and jointing planes, in which water and frost were continuously at work removing one by one the supports which held it in place. Recent earthquake tremors, particularly that of 1901, no doubt hastened the time of final disruption. The opening up of large chambers in the coal mine, situated near the base of the mountain, may have been a contributory cause, by allowing slight readjustments in the strata forming the hanging wall of the seam, producing jars that might dissever some of the few remaining bonds. The heavy frost on the morning of the slide, which followed hot, summer-like days, appears to have been the force which severed the last thread and precipitated the unbalanced mass. ORIGIN AND NATURE OF THE SAN JUAN ROCK STREAMS. The striking similarity that the Frank landslide bears to so many of the San Juan rock streams can leave the origin of these latter deposits open to no doubt. Although it is not impossible that ice may have played an important part in their formation, the writer believes that they are strictly landslides and owe their present form entirely to the nature of their fall and to the character or physical condition of the rocks involved in the fall. While it is reason- able to suppose that the accumulations of detritus in American Basin may have been due to the NATURE AND CAUSES OF ROCK STREAMS. 53 rolling out of falling debris from the cliffs on the surface of snow banks, as suggested on a pre- vious page, yet these, too, might be attributed to landslides alone. In the case of the larger rock streams there seems to be no alternative hypothesis so well suited to explain their peculiar form and position with respect to the cliffs back of them. In the description of the Elm landslide the statement was made that the upper portion of the large rock mass pitched forward when the mass struck the bottom of the valley. In most of the landslides of the San Juan as well as in other regions, it has been observed that when large blocks have slipped down their upper portions have fallen backward, and have not pitched forward; that is, the blocks tend to rotate backward about axes parallel to the strike of the slope down which they are descending. If the movement, on account of the steepness of the slope, becomes extremely rapid, or is in the nature of a fall rather than a slide or slip, the upper portion of the falling block or mass would tend to pitch forward as the result of the sudden checking of motion in the lower portion when the mass strikes the bottom of the valley or meets some obstruction in its path. The result of such a sudden shock would in many cases be a more or less complete shattering of the mass and a violent outward projection of the rock fragments. It is believed that the San Juan rock streams belong to this class of landslide, of which the occurrence at Elm is the type. The rock streams are the result of rock falls as distinguished from rock slides, in which the movement is less violent and the inclination of the path of the slide undoubtedly less steep. The fact that almost all of these rock streams lie above timber line may account for many of the differences in form that exist between them and some other landslides. It is possible that many of the landslides at lower altitudes, now covered by soil and vegetation, may be, in reality, entirely comparable to rock streams, their more distinctive features being obscured by their covering of vegetation. In considering the fall of blocks at lower elevations account must be taken of the fact that vegetation was undoubtedly present on the slopes upon which the masses fell, and this may have helped to break the fall and to prevent shattering of the blocks, whereas in the high cirques above timber line bare rock lay at the base of the cliffs. Whether the landslides fell upon the bare rock floors of the cirques or on ice, the peculiar talus- like character of their material as distinguished from the block form of other landslides must be attributed very largely to the condition of the rock at the time of or previous to the fall; that is, the rock involved must have been extensively jointed and easily shattered. That similar deposits do not occur in the Rico region is probably due to the fact that the topography of the Rico Mountains was of a gentler type than that characterizing the high cirques of the interior San Juan Mountains, and that the movement of the rock masses at Rico was essentially a slumping or sliding, while in the high cirques of the San Juan the movements were typical Felsstiirze or rock falls. It is noteworthy that in the case of the Elm landslide the material flowed for a distance of more than a mile down the valley from the base of the cliff from which it fell, while in the San Juan region no rock stream has been observed of a greater length than three-fourths of a mile. J. G. Anderson3 has recently described certain peculiar "stone rivers," such as those of the Falkland Islands mentioned by Wyville Thomson, and others in Arctic islands, which in some ways resemble the rock streams of the San Juan Mountains; but judging from Anderson's account, the average thickness of the "stone rivers" is much less than that of the rock streams, while their length as compared with their width is considerably greater. From surveys made by Anderson it appears that the "stone rivers" of the Falkland Islands have the rude outlines of small river systems; that is, a main stream is fed by smaller tributaries. The "rivers," with their branches, do not head beneath cliffs, but usually on hillsides of moder- ate slope, and increase in volume downstream. It is not shown that the large "stone rivers" of the Falklands are now in motion, but smaller examples observed in Arctic islands have a slow, glacier-like flow. " Sohnuction " is a term proposed by Anderson to describe this flow. " Solifluction, a component of subaerial denudation: Jour. Geology, vol. 14, 1906, pp. 91-112. 54 LANDSLIDES IN THE SAN JUAN MOUNTAINS. The Arctic "stone rivers" are in reality mud streams containing coarser material, such as gravel and large rocks, derived from the saturated ground left by melting snow banks. On page 95 Anderson says: It is not very difficult to find out the mode of formation of the mud glaciers mentioned above. When, in summer time, the melting of the snow has reached an advanced stage, often the bottoms of the valleys are free from snow, while big masses still rest in sheltered places on the valley sides. Every warm and sunny day new quantities of water trickle from these melting drifts into the rock waste at their lower edge. As the masses of detritus are composed not only of coarser rock fragments, such as blocks, slabs, and gravel, but also of finer particles filling the interspaces between the coarser material, they are able to absorb considerable quantities of water. When once started they form a semi- fluid substance that starts moving down hill. Evidence of solifluction has been found in high basins in the San Juan during early spring, where soil at the foot of small talus slopes has been pushed outward o,nd thrown up in the form of miniature ridges by the slow downward creep of talus. Salisbury has suggested some process analogous to solifluction to account for one of the smaller rock streams in a basin near Telluride. In describing an illustration of this rock stream" he refers to it as "An accumulation of talus, etc., in the upper part of a mountain valley. The body of loose material in the bottom of the valley has slipped, crept, or rolled down, making what has sometimes been called a talus glacier." Chamberlin and Salisbury6 make the statement that "The loose debris on steep slopes sometimes assumes a sort of flowing motion and descends the slope with some such form and at some such rate as a glacier." As an illustration of such a "talus glacier" a picture is given of the rock stream at the head of Silver Basin. Although such explanations might hold true in the case of some of the smallest rock streams, hardly to be distinguished from ordinary talus, in the writer's opinion they can not account for the notable examples of rock streams described in this paper. There can be little doubt that the detritus of which the rock' streams are composed flowed down the valley sides or basin floors; not, however, "at some such rate as a glacier," but with a sudden violent rush that ended as quickly as it started. Evidence of this is found in the cases of the Elm and Frank landslides. A study of the San Juan rock streams, carried on through a number of field seasons, has failed to show that they are now in motion or that they have come to their present position as a result of slow, glacier-like movement. In only one of them does such movement appear to have taken place — the rock stream from Sliderock Ridge, in the Engineer Mountain quadrangle, which was originally formed as the result of a rock fall, but whose debris has probably crept downward to a very moderate extent on the soft underlying Mancos shale. It is entirely possible that the tongue of detritus extending downward from the rock stream of the supposed snow-bank type in American Basin, shown in Plate XV, B, may have resulted from a subsequent slumping of accumulated waste at a point where the rock bench upon which the debris rested offered insufficient support. If this is so it is the only instance of the kind observed by Mr. Cross and the writer in the San Juan Mountains. CLASSIFICATION OF SAN JUAN LANDSLIDES. In the present study it has been shown that landslides of a number of well-marked types have occurred in the western San Juan Mountains. Considering only the character of move- ment and materials involved, three main classes of landslides may be recognized; they are practically the same as those of Heim's classification. In their subdivision the nomenclature and definitions of Heim have been slightly modified. As a matter of interest three kinds of slides suggested by Heim, but of which no examples have been specially observed, are included in the classification; they are submarine slides under the head "Movements of detritus," and such miscellaneous slides as those occurring from the sides of artificial cuts, and the sinking a Salisbury, R. D., Physiography, 1907, p. 107, fig. 97. 'Chamberlin, T. C, and Salisbury, It. D., Geology, vol. 1, 2d ed., 1905, pp. 232-233. CLASSIFICATION OF SAN JUAN LANDSLIDES. 55 of ground over caverns and mines. Of these minor landslides, those from artificial cuts have taken place frequently, as have settlings of the ground over some mines, but in no case have such movements been of a magnitude worthy of record or discussion. Slides from the ends of deltas in lakes have not been observed, but it is not improbable that such slips have taken place in Lake San Cristobal, especially from the delta of the Slumgullion slide. Classification of the San Juan landslides. MOVEMENTS OF DETRITUS. Kind of slide. Examples. C H. C. Hill, Rico. Cimarron landslide. Slumgullion, San Cristobal quadrangle. Rock stream of American Basin. Submarine slides at edge of continental shelf, or from ends of deltas. (?) MOVEMENTS OF SOLID ROCK. Rock slides; large masses of rock rotating backward on axes parallel to strike of slope down which movement takes place. Rock falls; rocks shattered; if of sufficient magnitude shattered rock may move with great velocity outward from base of cliffs as a flow of newly made detritus. Majority of San Juan landslides, noteworthy examples being at the end of Hayden Mountain, Ouray, and in Red Mountain and Ironton Park districts, Silverton. Rock streams. MOVEMENTS OF BOTH DETRITUS AND SOLID ROCK. Rock falls or slides on detritus, resulting in the movement of both. Rock slides of Canyon Creek, Ouray, on glacial gravels (?). MISCELLANEOUS. Slides from artificial cuts Sinking of ground over mines or caverns. Many examples of minor importance. A few instances. No attempt has been made in this scheme to suggest a universal classification of all land- slides, but it is believed that practically all of the landslides that have been observed in different parts of the world may be placed in one or another of the groups. Whether this is actually the case or not, one can not help being impressed by the number and variety of the San Juan landslides; of the eight quadrangles of which the surveys have been completed, all but one, the La Plata, contain notable examples. In the Telluride, Rico, Silverton, and Ouray quadrangles nearly 100 landslides, including rock streams, are of sufficient size and importance to be shown on the geologic maps; they represent a total area of more than 60 square miles, or more than 6 per cent of the area of the four quadrangles mentioned. A study of the topography has shown that in many cases oversteepening of valley or cirque walls by glacial erosion has been an important cause of landslides; another common cause has been the highly jointed or shattered condition of the rocks, while in most instances the saturation of the ground as a result of excessive rainfall has reduced the coefficient of friction along lines of weakness and at the same time increased the weight and instability of the soil and rock that subsequently moved. In many of the landslides of the Rico, Telluride, and Silverton quadrangles such internal causes appear to have been of secondary importance, and some external cause, such as earthquake shock, is believed to have started landslide action. INDEX. A- Page. American Basin, rock streams in 35-36, 52-53 rock streams in, view of 36 section of, figure showing 36 Amphitheater, landslides at 30 Anderson, J. G., on stone rivers 53-54 Animas formation, occurrence and character of 9 Arctic islands, stone rivers in 53-54 B. Bear Creek, rock stream on 50 rock stream on, view of 50 Brock, A. W., and McConnell, R. G., on Frank landslide 51-52 Burnett Center, landslide at 24 Burnett-Sulphur Creek ridge, landslide at 23 Canyon Creek, landslides on 28, 30, 44, 48 Cascade Creek, rocks on 37 rock stream near 50 Chamberlin, T. C, and Salisbury, R. D., on rock streams 54 C. H. C. Hill, landslide on 15-16, 24 landslide on, tree split by, view of 16 Cimarron Creek, landslide on 12-15 landslide on, view of 14 Cleveland Gulch, rock stream in 36-37 rock stream in, view of 36 Coal Creek, landslides on 30-31 Conway, W. M., on Elm landslide 50-51 Corkscrew Gulch, landslide near, view of 28 Cross, W., on landslide 13-15, 17-18,20, 23, 45, 46-47 on mud flow 40-41 work of 7 Cross, W., and Spencer, A. C, on landslides 21,22 Culture, description of 8 Cutler formation, occurrence and character of 9,12,38 slips of 44 D. Dakota sandstone, occurrence and character of 9, 12 Dallas Creek, landslides on 30-31 Darling Ridge, landslide at 22 Dexter Creek, landslide on 29-30 landslide on , view of 30 Dolores formation, occurrence and character of 9, 12 Dolores River, damming of 24 drainage of 8 Drainage, description of 8 E. Earthquakes, landslides due to 43-44, 46-49 occurrence of 48 Elbert formation, occurrence and character of 9,12 Elk Creek, landslide on 45 Elm, Switzerland, landslide at 42,50-51,53 Engineer Mountain, rock streams on 37-38 rock streams on, views of 38 rocks of 45 Engineer Mountain quadrangle, landslides in 40 Endlich, F. M., on Slumgullion mud flow 40 Erosion, occurrence of 10-11 Expectation Mountain, landslide near 23 view of 24 F. Falkland Islands, stone rivers in 53 Farnham, Prof. , on Cimarron slide 13, 14 Faulting, relation of, to landslides 46 Frank, Alberta, landslide at 42, 51-52 G- Page. Geologic history, outline of 10-11 Geology, outline of 8-12 Glaciation, evidence of 11 relation of, to rock streams 49-50 Goldau landslide, nature of 42 Grayrock Peak, rock stream on 38-39 Graysill Mountain, rock streams of 38-39 Greenhalgh Mountain, rock stream near 36 rock stream near, view of 36 Gunnison River, drainage of 8 H. Hayden Mountain, landslide on 30 Hayden Survey, on landslides 13 Heim, Albert, on Alpine landslides 41-42, 54 Henson Creek, rock streams on 36,50 Hermosa Creek, landslides on .' 29,44,48 Hermosa formation, occurrence and character of 9,11-12 slips of 29, 44 Historical geology, outline of 10-11 Horse Gulch, landslide in 21-23 Hurricane Basin, rock streams in, view of 36 I. Ignacio quarteite, occurrence and character of 9 Imogene Basin, rock streams in 34-35,50 rock stream in, view of 34 Iron ton Park, landslides in 25-26 L. Lake Fork, damming of 40-41 Landslides, age of 18-19, 30 cause of 14, 42-49 classification of 4H2, 54-55 distribution of 55 evidences of 16-17 theory of 43 diagram showing 43 study of 7, 41-44 Landslip Mountain, landslides at 24 view of 24 La Plata sandstone, occurrence and character of 10,12 Laramie formation, occurrence and character of 9 Lay, H. C, on earthquakes 48 Lewis shale, occurrence and character of 10 Lookout Peak, view of 12 M. McConnell, R. G.,and Brock, R. W., on Frank landslide 51-52 McElmo formation, occurrence and character of 10 Mancos shale, occurrence and character of 10, 12 slips of 19, 44 Mesaverde formation, occurrence and character of 10, 12 Mineral Creek, landslide topography near, view of 26 Molas formation, occurrence and character of 9,12 Mud flows, cause of 42 N. Needle Mountains, landslides in 28,45,48 O. Ouray limestone, occurrence and character of 9,11-12 Ouray quadrangle, landslides in 29-30,44,48 P. Penck, Albrecht. on landslides 43^4 Physiography, description of 10 Pierson Basin , map of 33 57 58 INDEX. Page. Pierson Basin, rock stream in 32-33 rock stream in, view of 32 Pleistocene time, landslides in 30-31 Portland Creek, landslides on 30 Potosi volcanic series, occurrence and character of 10, 12 rock streams of 33,34 slip of 19,20 R. Red Mountain, landslides near 25-27,45 view of 26,28 Relief, description of 8 Rico formation, occurrence and character of 9,12 Rico Mountains, fossils in 9 Rico quadrangle, landslides in 12,21-25,44-45,53 prospecting in 21 Rio Grande, drainage of S Rock streams, character of 31-32,49-50,52-54 descriptions of 32-41 explanation of 35-37,52-54 investigation of 7,31-32 S. Salisbury, R. D., on rock streams 54 Salisbury, R. D., and Chamberlin, T. C, on rock streams 54 San Cristobal Lake, formation of 41 San Juan Mountains, location of 7-8 San Juan River, drainage of 8 San Juan tuff, cliffs of, view of 12 occurrence and character of 10,12 slip of 19, 20 San Miguel River, drainage of 8 Sedimentary rocks, occurrence and character of 9-10 slides of 44-45 Sheep Mountain, landslides at and near 20. 27 Sheep Mountain slide, description of 20 Silver Basin, map of 33 rock streams in 33-34 view of 34 Silver Creek, landslide on 40 Silver Mountain landslide, age of 18-19 description of 17. Page. Silver Mountain landslide, map showing 17-19 vie w of 18 Silverton quadrangle, landslides in 25-27 Silverton volcanic series, occurrence and character of 10. 12 slip of 20 Sliderock Ridge, rock stream on 39-40,50,54 view of 38 Slumgullion Gulch, mud flow in 40-41 mud flow in, view of 50 Sneffels Range, view of 30 Snow banks, agency of, in forming rock streams 35-30 Soil, sliding of 15-10 Stresses, release of, earthquakes due to 47-49 Structure, description of 10 relation of. to landslides 45-46 T. Telescope Mountain, landslip at 24 Telluride area, landslides in 17-21,44 Telluride conglomerate, occurrence and character of 10 slips of 19, 20 Topography, description of 8,11 expression of 11-12 relation of, to landslides 46, 49 Trachyte, occurrence and character of 38-40 Trident Mesa, landslide near 13 Trout Lake, landslides near 17 Turtle Mountain, fall of 51 U. Ute Creek, landslide on 16 V. Volcanic action, landslides due to 47 Volcanic rocks, occurrence and character of 10 slides of 45 W. Water, landslides due to 14,48 Y. Yellow Mountain landslide, description of 19-20 o <£ ' U S GEOLOGICAL SURVEY GEORGE OTIS SMITH. DIRECTOR PROFESSIONAL PAPER G6 PLATE II , ,".: "**!}r™ LEGEND Qal °S I ,V(.S Malpais "basalt Rabbit Spring tiinuutloii tin* i.iti/r */j»nW»v an. I n.irn/i. Speai&ead rhyohte. Ft.... r.rflow* | Pozo tcuiimtimi Hit* t.rtll* '/ryji'rJj pl\vrr Baeite vitrophvre Flow* Dacite Intrusive- Pcutae* into ftow& Mttofareu mitfrptii Milltown andesite Flows ami amaU tneruxforur 37*M'I 1 17* 15* R « E ■ . 3 Kendall t Itfffithtti? anil l.itin. Vindicator tIiv >litt- Flow J Al.iskiii- and granite Canibrian shale Ti7 Outcrops of siliceous ledges R.H.Cha . ge of section. Topography by Wm.Slranahan. Triangutal I upman. Surveyed V. Beamat. GEOLOGIC MAP OF THE GOLDFIELD DISTRICT, NEVADA Scale anion l Idkiiutftar Contom: interval 20 feet . Jftettttn in ntfiai xta le vcl Geology by F. L.Ransome, as>- -Emmons and G H Garrey. SurvV«d in 1905 and 1908. Shaft Tunnel Prospect pit Land corners :; m:iii U S. GEOLOGICAL SURVEY GEORGE OTIS SMITH DIRECTOR -7 E PROFESSIONAL PAPER 66 PLATE LIST OF SHAFTS, TUNNELS. MILLS. ETC The number* run generally trom left to right in ranks oi sections from top to bottom For alphabetic lilt see leit. Where name of shah has not bean ascertained the name of the claim, if known, ,1 .nseted m parentheses H Krug.r) 7 Goidbug 4 Ott, Wait i (Lucky St. it. No !> 6 Jupiter ' Gold'ield Oomln-on II Koane I] I Greet Band No ?> 14 Spoken* i5 Greet Bind (".-I ift Greet B>nd (old) " Greet Bind Diede-r. 18 TopMnOm, L 4, M 19 Greet Bend E.ten.ion JO Skylark 71 Pierre end Pugh 77 Golden Dili, 33 Daily »r.n«. 14 Belcher 15 iDm, Tifanflte '■ 76 Combined 77 Morriion IS Dm, (Tru.tl) 79 Camp JO Cl*i'y 31 G> • ••■•.. )7 0 m, No t J 3 Gold Coin 34 Eurake 3 5 Belmont 3e 'Black Butt* EitetMton) 37 Oeviitold] IB (Black Butt* No ij 39 Black Butt* Comolidated 40 Beumgartan 4i Gordon & Oitetter 41 Bleck Butte tunnel 43 CjuartiiL 44 (South QuartlUe) 41 Black Bum Bonan.-a 4( M-dn[gr,t-Pi«nee 47 Bulldog 48 Slack Butt* E.'en.l0n 49 Highland 50 Mammoth St 'Red Rock) S7 Goldfield CI Mill 53 Goldllald Coniolldaled Mm 54 '/„„■■ 55 (Joihua) 56 Meyn* 57 i ft.., SB Da..rt fto.a 59 Kandall 60 Wllkei 61 Loftui-Oa.il 67 SanJitu-m (ol 6) Sandilorm 79 Oddia-Roaa 130 Mohawk Ledge Ml Hlgglnion 137 MeNaughton i3) Jumbo Anne. 134 Ricka'd No > 135 Rad Top 136 Harriion 13 7 Comolldalad Rad Top 13B F.I1CO 139 Kmkaad Mill ■40 Booth 14t Col la Mm aaat i 147 NlgMh.wk 143 Oio 144 L«guna fold) 145 Muihatt 146 Laguna (new) 147 Mohawk- Rail Top <48 Rad Top Friction 149 Jumbo Eitennon L 150 Claimont iSi Curt,. 15! Combined IS! (Polvorde) 154 Jumbo Wonder 155 Kaal(n No 6 156 Original Valval 157 Chicego-Velvat >S8 AIU 159 O Keen '61 Haiall Combination Milt 712 Combination 713 White Rock No. 3 714 While Rock No. 4 715 January-White Rock 216 White Rock No 6 217 (Butte) 718 Gold Coin 219 Burnt 270 Oddle 771 Combination Fraction 777 Little Florence (on Comb 223 Calltorn la-Florence 274 Rail I, 275 Florence-Wheeler 726 Gotwaldt 227 Mooia 278 Gibraltar 779 Combination Entennon 2J0 Mltchell-Falrtleld (Stoneh. 231 Black Eegle 737 Goldliald-Red King 733 Portlind 7 34 Barnai 735 p.rklmon 736 Florence Eitenllon No 2 237 Sprague-Sleln 238 Rotabud or O. K 739 Roger. 240 Mohawk- Florence 241 i_in|s Florence (Florence L 747 Hall-floranco 243 Flo.ence-Goldtield Red Km 244 Rod K.nj 745 Chicago-Florence 746 Florence-KI-by 747 Pollard- Florence 748 Florence E.tenilon No 1 749 Goldllald Rod Hill. M S. L 2S6 Red Hill 25' Florence-Amelia 252 Goldlieldi-Chedd 7S1 Florence Anne* I Enginee.!" 254 Florence 255 Florence Mill 256 Oalir-Flo'once 757 Baltimore Belle 258 Florence Anne. No. 7 259 Florence Jumbo 760 Baby Florence No 7 761 Little Floionce 7C7 Florence Contol'datad 763 Zlnn-Floranee, 764 P.nn 765 Jumbo Ledge 766 Bleke 267 Melonoy 268 Fuller 269 Jumbo 270 Jumbo Ledge Lane 271 Century 277 Leymanca 273 Imperial 276 Original Atlanta 77J Atlinte-Cherokee 778 Portland-Florence 279 KeH 760 February-Atlanta 28i Hooper- Manning 287 Florence-Hopkim 783 Keelyn G and G 7S4 Liverpool 785 (Golconda) 786 TeiwGolconde 787 Gold Mountain 7S3 Goldllald Mining and Ore 289 Gold Star 790 Nevada Eaplotatlon Co 291 Gaonon 797 Atlanta B. and M 293 Delmonte 294 Crown 295 Third Chance 796 Goldfield Fargo 797 Kama* City 798 C. O D 299 Gold Bar M and L )0O Gold Bar 301 Floranea-C O 0 302 Victor 303 Vencendor 304 Gold Bar Fraction 305 Goldllald Merger 306 Blue Bull (old) 307 Blue Bull (now) 300 Hat 309 Pe.ker 310 Yellow Tiger 311 -Hidden I.e..*,. a i 317 Imperial 313 Oakland 314 Sunnyiide 315 Funcaa-Mphawk 316 Albemerl* 317 Wlldhoraa-tunnei 318 Monarch 319 Madonna 370 Did 371 (Ni 377 Mllltown Fraction 373 Plttiburg-Ne.ad 374 'Oivonn Boy) 375 Congo tunnel . Eagle EM Douglas, Geographer. R.H.Chftpman, m en ergo of section . Topography by Wm S+ranahan and W. M Beatr.a Triangulationby R.H. Chapman. Surveyed in 1905 and 1908, TOPOGRAPHIC MAP OF THE GOLDFIELD DISTRICT, NEVADA WITH LIST AND LOCATIONS OF SHAFTS Scale 44rf>oo Contour interval 20 feet Ititttun MnuJR *«t It-vel 1909