DEPARTMENT OF THE INTERIOR

MONOGRAPHS

OF THE

UNITED STATES GEOLOGICAL SURVEY

WO TL TUIMT a Ox xc OC IL

WASHINGTON
GOVERNMENT PRINTING OFFICE
1898

Stas
U7
V3 | UNITED STATES GEOLOGICAL SURVEY

CHARLES D. WALCOTT, DIRECTOR

CHOLOG Y

OF THE

ASPEN MINING DISTRICT, COLORADO

With ALTEAS

BY

JOSIAH EDWARD SPURR

SAMUEL FRANKLIN EMMONS, GEOLOGIST IN CHARGE

WASHINGTON
GOVERNMENT PRINTING OFFICE
1898

CONT eS.

Page
EERE RORECVANGMUDT ANS maeeoNe Nee once). oo eve eee Sona Bene sioe ss Sea sae moc Ve Seem nese xili
ID RISRVAC Bie een eI pe ees ae a ae Many Sas la BALE Sew ca Secu ale Pie ae Oe Ne XV
INTRODUCTIONS D yar Hap Human On Sipe ene eae sa eee tates a ihe eee ee ete ere i _ Xvii
OS it © Trae re eae eae cee dpe aR Aes the SS es Set ae Sip IAS _ Xvii
IDISCOMSRY <b atk eke tooedeeeeuuel soceae Sens SO BeSE cena eoces lesnescoopasatsescasesaeae A xix
Deve lopmlenttaer saree eects se sees Ee ls see ae eters Msn BUN eats Ml ere Xx
IASB R MONS oases sen ose SASS eat oat See er ees Sa Saas Sp SEES Dap eerie Ha ae eps amet Xxi
Hx] OL uevUl OLA ape ee tee ee ee aa Uae ee ee tno Mees aeons hee eters scree, BOREL
FOU ClO Mee ioe tam wee ieee mete = is ke ok LES ee Pie of ace eee a ry eee Se XXVili
Geolosicalnnvesticabion Steses ssn =e ee a Ute eel Sere see Ae HOG
Literature_.__.__-_ Esp NESE IU ae el epee A eee ee Shh tm ely LE le XXxii
OURDINES ORE THATS MONO GRAPH erso ee Se ea BE SU eee a ate ate secrapeiee See sees ae XXxili
CoNPrnne rocks orm ayilOns same ee ee eae ee ee Ea reed Mat een ere 1
(Ghannmlives se Saco ae Mat thet Se See es ee See en a Ce ae Ae te Re ee 8 SNR Or Al ae 4 il
Camilbriankse dinvenltse sertseersra a ees = ae Ae eh cee oN yn Se ye SES 5 eee arte we Sel 4
SHIEH NC Ses ek ek Ss Bee eR a i ae er ae ae a ee 9
IRA hiner Wanial terse ll eseemae een ee Role Gk ee ot any sac gree mya neal Ste of veh s_Aty 13
Carboniteroustormalon sees se ase. eee toe es pie we SI eee ee ene Se ess 22
Weadvalllewimestonemeeeme ccs sea nie fy cot lean ole eu) Wee Ate Re See ee ier ae ae 22
plays). Glollavenitiyey. 52-5 eek ae SA en Sele OE aa Ae i ee ak ee ee ee eee oe 22
Rinveablwewhimeston eran na sens teers oF aksee = cere anne ak Soa sorte See eiar sean aoe elas 28

Weber formation._____._.__.__-_-____- SS A NS Re Rg I abate on Wn aft ws pe Re 3
Mar OOTBROTINVA TION ae ane oe ase ne ee ee Bore ae serene ee ee fa ee epee reg 33
EDI ASST GAOT ALON See ye ees hes ee, AA A CA I STR ie cul ee eee 37
Red sandstones.._- ___- et ne rps RO Ee agen ps BoP Oe Raat cae any AO aha aed RRA ERE fe 7
(Gunmisonwtonrmahlone see ee eee sea anes Be Se Ne EGA au Sais Sex trae oe Pee 39
(Cretaccouspsericsiest teats alate nets Sone Lh epmaen UNI Sel sty alee el AIL ey tt US Seay 41
Dako tawhormia tiOniyss sans oe ei oe coe Oe teenas oe eet tn 3, Baraka eed Bae Ae eI 2 | meeees ee Re 41
Colonad Oso ali On ee A Pe En Ree ct: be RPE NE er 41
Montanastormation=; ease sac ie se as ae eae aoe ie Se re eee ea cee 42
aramietOrmatl Orbe mer sey ey les ya ene SEN PS RRO A ele Ri eyes sede MA a 43
iPre-Cretaccoustuncomiormity eee setae 42 2 here pee eee See aetee = ere ee eee eee Sen 43
Cretaceous Meth aTsya Ui COM OT ype eee eee ee ee 44
Tn brs eehOC KS rem ater ee oye rs eee meen spe sien SUNN hy SEI re ENE Fey I pe) SE 45
Diorite-porphyry ___.._.-_-.------- Sen Wee IS hr ieee ooo ee ee enn ame sere eae ee tes 45
@QUaAKtz POLO DVT re soe A Nee eee aa at ae es See oben = OE Bes Soeee ssi oie 48
(Acero fmubOmniUsive OCK Gace some oe ete ee ee ee Nek Ri Mepis aw ee 53
CHAPTER II.—General descriptive geology___.__---.-..------.----------------------------- 54
PAIS OMY SCC LE LBTT el) ee oe hemes oy ey eRe NY re A ates ete NO Se DES) el pee 54.
Aspen Mountain.__.____.- Migs EMR AE CARCI TAS IN U6 i tape Be ae Ce Re Sot eR 56

vl CONTENTS.

CHAPTER II.—General descriptive geology—Continued. Page.
Aspen special map—Continued.
Aspen Mountain—Continued.

ING Gtinyst soe oo es suas oa SaaS oma ks none censnebomenas wants dad nsceSaaondeoestoses 56
iaiemiista - Baan 2udilly gh Nie oS a a aA an re ee eae 58
Résumé of Gaerne. on ren eoomvicinn UN Se NT Aa Rc FTA 72
Smuggler Mountain --_.-__. Bae at UC age els Sta a ar ee 74
Résumé of structure on Saimin iniorrnayioten See SRE ko RUE aR a pe ete 77
Ried! Mottaret oe ee aera ae ae pe poe Ne OE eee 78
IDASCMIDHOM OF FACHMOOS.. 2 -c2n0 seo= sess 22> 2 eses 225 on sc esau ees scere 2s =s5ss2s22-20=- 79
Résumé of structure on Aspen special map.-.--...--_- ---._..-.--..----.---.------- G2
“ MoyoininelKonnine) JOennls SOM TMA) aoe neese se aoe cesses Meas oe See ee seess tonece ese eeesse= 84
Résumé of structure. -_-.---.-----.--------- 5 Se SERS GEeRR aah a er eee ore eee 105
DeseniptOmko ty se Cul OTS eee eee eee 108
Résumevolsbam tim os =e eS ee ee re meee ee ree ree ep ete seen ne Siege ae Sates peli
enadomspeciallinm(a|p peer ese sen eee ee eee ae Ree eee eee eee eee 117
Tao Molbnyee oo 2 ceed qn = sob spe ee ease ne ans eaee ie Sn euuobApdocWes enesdses Senzoese> ose 117
IDE Ul Ae ee Se ae SE aa CEE AM ease Ee abo as Ssek tema as aca aseasHe ca seSnet essase 120
Description of sections __--.--.--- OSE ae Me aa Saree le sso so ebe Sessa 125
Telpaanare IPake Goerenell MMARYO) 2. oe ce, s eeea sees cose sess sscese cease sse cose arse sae so98 S252u5=: 126
TRONGHIINE? 3 Soo she eSe cede eseeososans Sebsbeodessosuss song asarecus aenteq ose sobese< 127
Mal tins hee eee eee re Chas eee soecesee She Lee eee Ee eee eee 128
RESUME lO iS tit FUT ess ore apse ee re fer ee a aes 130
Description of sections] = 9s) 82a eas ee ee eel PAL a A ah ed eR a 131
BANS STAN CATS te CTT A ar ee 132
@utlineotstructurers-9 24 ste ne wean eee eee ees hs ie OL a 132
Description of secti ons. ss eer ca ae ee ye ee ae le aero nts 137
Résumé of structure in the Aspen district. _.-._-....--.--------------------.---.=:- 143
CHaptrrR III.—Description of mines and productive localities ...........---..-.-.-----..- =. Wail
‘Aspen, Mountain’ 9: 5282 fae ane eee ae teeta ee cae ee By Vea BENS ee ell aoe ee 151
West side of Aspen Mountain. ----- DONE ECs Sen A Spe Se or eet en LOU)
AspenuiMoun talmymuimin grr ype eee eee eee eee ee ee eee 161
West Aspen Mountain .__--._-_.---.. -._--- Meese a ee es Se Se ep Ac aie Ue a? i a 165
Tourtelotte, Parke 22 see ee eae Se eee Ne yey para en ep pay ne ay Soe ea 167
Mrtoveharelounns) [erhale janybanbave TEN) o.oo ee ecco ese cmenuseeassecess+ scosasessas anes: 179
Smureler Mountainys 2522 See a- oe ee ee ee ae ee ee ee ae TE ee ee 180
Mollie:Gibson mines": 4.2 ace te oe eee ee ae ee ee See ee ee ree meee 181
Smuggler mine - Se DPN oP es ae eRe Pa amcwoe Vemunaaooesa, lel
Summary of M. afte eaneon andl Sameclin mason. Ba foe ay 5 eS Re CAE 187
Cowenhoventtunnel 2.222603 oy ye ee ae a Se ee ee 188
Della'S) mine 7.2.2 je et ee Ne ae se Cy yea ee Se 189
Bushwhacker mine. 829 2.5. ee) ee ies ee re Sa ae he en ee 193
Park: Regent mime : ios hes ey ere a a ye eae eee 194
Mineral Marmiminey = 2/2020 2) cs Se ERS a I BU ee eee ene Sooo NC CRE 196
‘Alita Are entimin ery ce Lhe so he = eyes Cee es aya are Se Sea Sem REDE es 196
ShonbrFaller MIOUMMIRnIM Waa? WRI) — = aoa ssao so ocao eee Sasson seas sess ss eessee Jessse = 197
Résumé of Smuggler Mountain geology_--....-_-.---------------------------------- 198
Denados esos el gens Sot ced Soo Soa e be ene Se Se ee Ee Oe eee eae 199
‘AispeniContactimine pte. eee ee sae eae Re ate. Sater a ae ee 200

Trea dville iain exe) ya es oe I eee eee vee o/h pe en Lap arc eS ea 201

CONTENTS. Vil
CHAPTER III.—Description of mines and productive localities—Continued. Page.
Lenado—Continued.
Bim etallic pou clses seem a Ae yet te Se ec oe We de fcc ee Sm OE 202
esi lives heli peter poten ees er ay ts ee vare meres ey eS mh Sale ee ey A a cha Sp 202
FRIESTIIN CLOLES COLO Ryan eens ae ee eee ae tas Sune Mee haa = oe ee 202
@ucen si Gil c heat see as sere Seger BS wee ALS Be ee AU ego) Scie cee eee Sees 203
WGitilepAmmnilenm in eMyase ene eis ee ena eee en Uh A ape Se eet BAe oe eee anaes 205
CHAPTERS IVE——Chemicalyseolopyren etter s 5. cs a sciete Se Sota eso ec ese ean eee eee ae 206
Wolomization meee aN aan eas as Poe ese cee cigh wa on a 206
ANSON CVO)GI TANT SS Ee oS pe Ss PS eR ae ee et A eye 208
een tsrOMd OOM IZA ON ere eer ere en on sets ome eae ee Lee ines oe eee SE le eee Paul
Dolomizationvat GlonwoodtSpringsi 2-22 5s- sees. sees ee ee eee ee 212
SIlICiiCa tT ONMEEEE ee MRE eae ce Soh Re Laa. aise een Ney tells Ce IRs es woe 216
LNGTEREN ON sie oe | eS EIS cS Sete ROI a ae ere Th a oa ee 221
Ore deposition.____ ._.-..------ ese NES RE BAERS COS ee ae ee A eS a SURREY SAE 224
Nia LUC Ol Ones ammeter a eri a tae ete Sener Se ee ve ARSE oe Hae ESS Cee ae 224
(Gans e sin eral seeee ee ey ee Pape a te ery ete te ee leas gee iN Ee Mee Nee oe Bee 225
Compositionvoorestam as tech eee ceo oe ee emisa kee cee ce nes eiee en eee ten eebiasisaeoone 226
Palas enesispofaveinpmatetialsie we aen seen ane pene eee Peemacins aae See ee ce ola eee 227
Pocnsyotroreidepositionestees sess sac eee as Sere ee Rey Rees Ne ak eee 2 i 229
Extent oredepositionrees jae ee ees an ee et es tan eee Mace en ase 231
ARGUE OF Tania iA ON Go =O meee Saba mee ase a eee Soe oaseasae Sabucencsaceseees 232
Influence of different rocks on ore deposition.__. .__._-____--_.-.--.---------------- 232
Process Olemineralizatlomesan. Aes e sae oes cole aeyc eet See eee ee esee eee cee 233
CaulsevomsprecipitaTloniOtOresese essa) sae == ante nn Se ee eee ee ae ee 284
Oricinaltsourcerofametalsre wee came acta ee ee Naim ias eee a eka ue eh aes 235
Changesnmroreisincerdepositlome sear jos oes smear een tn haere oe een Se ee 236
Mechanical changes __..-_-._-- oe chee Ue at at Renee eealS A oGk Rpe LM Sean cy me a 236
(Glastron Canes £5 28 Zee oe ee acdsecas hoe eee ase Gass He aa. OAS iSaeEeS ears neeeo Se _ 236
HISTO fen CTA) Semesters ee eee trea A Se ey She gh Se cae ME ene A ee OS ee Se 242
CHAPTER V.—Surface changes since ore deposition..-__._.._.-......_-- .------------.----- 243
PATTOUM TO MeLOSION Gee se neers a eye eye eet et en ne te eee Se aE ae eS Se 243
Wittere nti aleeroSio nies yee ate seyeee Cee Nees a ae et ical 12 2% Se ee ie oye eee ee 243
Intlivencevotetanmltsirs pw ate wer Awe See eee sya Evel Shaye =e a RE vet apes Sa ER 244
(CHG IONA, «Se ae ee ale eerie Soe pe EEE Se ES HoH a be Semana eee ssh Hoe 244
DirectionrolicennO vem ent sense = = see es et ee ae ey ear ee as ee ese 246
DIMETISIONS Ohl CosSheObac sey kee cise tks He eee Se ce os eerie eee ee oer 246
UOATIN SIMONE A COL N Seay tie oe Tne eae ea a AST te te ya Re ek 246
Ebumteri@reckselacleraacrs chm sere SC Mee el hi ee Siate ae PRN oe oh ao ei ie NAD 249
ResumermherlaciaWwaction: +82. Messe = ee oe cei ne estes eee UA rn Oe pee en) P 250
INPPENDIXG—— Measurementiofitamltse os 2 cess o2 2 se ceee ene eee ce eee ee ace eee ee ye eee eee 251
SSNS ERS erage ae pt rae Nee PEER Oe he ee yea Shy ie SE vee I a atte oe oye te ee cia ete 257

CLUS TI TION So

Page
PuateE I. General view of Aspen and vicinity___..__.----.-_-_____-.---__-__-__--------2.- 1
TM, Wests Aisjasia Wimmer oboe eel one eee Meee Dee aes 70
III. Red Mountain from Aspen Mountain _____._________-__--.-....._.... -..--..-.- Wis)

IV. Faulting of Cambrian quartzite and Silurian dolomite on hill on east side of
CoppersG ul Chis m ses amen See ene RE emer pe ne Ry kes oe a ee AE RE as 98
VY. View across Queens Gulch to Castle Butte. _...._-..-.-...----. -----.--------.- 100
Wiles CastlemBattemromtheteasty ass 226 a eee Nae eee eR Seeley he WES oe 2 te 102
WARE anliinscatpronitacelois © ast] es EU tte pase een a= one eee eee nee 104
VIII. View across Castle Creek up Ophir Gulch, showing Burro fault scarp.____.____- 106
XAT Saray aneraulupscalpy ss, oo Aes oss en ee eh eS ee oe ene San osm owe eee ewe 108
XGp OllVerPDelistaullinscan phen ses aoe ne ee aes eee, Se ae ne eee tee aoe 110
XI. View from Lenado. looking east up the canyon __________-..--.------..--.------- 114
XII. Fold in Cambrian quartzite on the north side of Lenado Canyon____.___________- 116
XIII. Silver Creek Valley, eroded in Weber shales ______.._ -._-._-----------------.-- 118
XIV. Maroon sandstones on north side of Woody Creek Valley___..._.-_-. ._----__-__- 120
XGVEVAeWwao melon ter hank districts s=s2-) 2-2 sseos ose aaatents Suen So se- sees seease OS
NG Vile Cretaceouslakeanwies iiOLehegy Ute ree aera se eee ee le nye ene ee een 3S
Vili CastlewWreekavalleysand Eveds Mio win tation 140
XVIII. Roaring Fork Valley at Aspen, and Aspen Mountain __-----_-.-_-----_-.--_-__-- 142
XIX. West side of Red Butte and of Red Mountain. -._...._...../_.----------.------- 144
KX. A. M. and 8. mine, No. 6 stope _-______.__.. eas < SHe essa saat ee sae ane es 156
PNOXU Se AS Mire an dts nmin en G.olcondaristope sss sate ee ee ee ee ee 158
SOM, Asfoem Mourn timoyen IRyerel Whormialipiin ooo ees ces oae sooo sose oe seb Seses + sace- 164
XXIII. Spar Gulch from near Best Friend shaft...._.........-...-.-----.---- .-.------- 178
ROXU NV No uT bel Otter ean key] OMe Tap OL b1 OTN ry ea ee eee ree Se Se 180
PXOXGV Pe MOTE bOL OGLE Era: Ken Up) 1) C91) O TL O Ta ee oes ee ee epee ee rs ee ere Pp Ere 180
XX Smug cler Mounbaimt ser se mere ere aes sabe sea Sie eee Se Selene ere 182
ROX ADM ona Out Aes - ewe siese eee cere CN ALR aOR, SWB 3) cpa en ecard eet eet eer 198
XEXeV A GpenkiContactwnine! Wenad ores sess ee = Meee ee ae eee ey at me) a ree 200
DOMID (Ernlkeln eulorayes Srlkyere siti, WEIMER) = 8 ee oe pte eee Seed eo eae sSeeae 202
XXX. Queens Gulch, from west side of Castle Creek_.._...-.__._.. ....-_----.---.----. 204
XXXI. Stratification and joint planes in dolomite, West Aspen Mountain _-._._._._____- 216
EXC TAS PCrOlGiOULCrOp) 42 es aa See At nae ep et any eee pn e) ay StS eS tC ae SO 220
XXXIII. Glaciated surface on ridge between Roaring Fork and Castle Creek valleys _____- 244
XXXIV. Glaciated surface between Hunter Creek and Woody Creek _._.-__..-....-___._. 246
XXXY. Glacial valley of Roaring Fork, and remnant of pre-Glacial valleyaosesn eso eeee 246
PNOXOXEV) Lee Mican ders ore oarin SSE OT kare pe set set ee a ee ee oa ye ee 246
PROXGXGVA LT Lerraces Onl edeviOuUn tant Sanam Serra sean ne fA aan ae one Seen ea oe ee 248
XXXVIII. Moraine of Hunter Creek glacier, on Red Mountain __..----.........--.-_-.--_.. 248
XEXOXI XM le ye OluElun ter! ©reekapee see eee ee meen ee ee ence wa Ee Ly tee 250

x ILLUSTRATIONS.

PiatE XL. Sections of Bonnybel, Durant, Aspen, and Late Acquisition mines___._._. ------

XLI. Sections of Pride of Aspen, Camp Bird, Iowa Chief, Mollie Gibson, and Smug-

gler mines _..-.----.--.--------- -----------+--- =. ++ ---- 6+ +--+ ----------------

XLII. Sections of Smugeler, Della S., Bushwhacker, and Park-Regent mines___. -___.-
XLIII. Sections of Park-Regent, Aspen Contact, Dubuque, and Little Annie mines ____
Fig. 1. Oxidized fine-grained dolomite, with residual areas ___.-..-.-----------------------
9. Zones of reduction in oxidized fine-grained dolomite _.-_....-.-----.---- Ao) Am ata
8. Nodule of lithographic dolomite in dolomitic sandstone -__. -.-_-..-----------------
4, Sandstone veins in dolomite _--..-.-------------- CN Aas yh Galea eer spa aS aE NSC Eee SF en
Be Mrachures ma Wie ela LiI eS tiO 110 see aera tee ohe
6. Deformation of drift in Della S. mine, by movement along fault__-.._-----_..-.-_--
%, Diagram of Smuggler and Mollie Gibson ore bodies -.__._.-- --..-----------------
8. Successive stages of faulting in Smuggler and Mollie Gibson mines______._---------
OM CTASSCEOSSIS 1) eee ee eee
10. Microscopic fractures in granitic quartz -._____..___. -.-- .. .--. -------------.-----.
11. Fossil changed to mative silver .---.-2.-2--.----------. ------ ===. ee

AULA Slale8 US.

Sheet.

IMMOSTREO 3 cease cusdasssedsaasas cater cess GeESes so SseE eden ane ooSose ners see SseESossons: I
Wontentsie-anesae see Sa eee ese oot aa Stat 5 8 ase toe ss Ss ete ena keeeeeeeas soe eeeeas Il
Megen dene fy sets sos se BS Se SSE OSS Ree eS ao DRE SARE ea See ee ae eee Til
ASpemiablasisheeimto OL Ta DME see aw oat eee team Puen ene ee ye Un uy. seen IV
FAlsHeni@istnicusheeritoposraphye see. o52 (ase see eee eee oe ee eee ne 2 eee ee V
PAS DENIGISLTIGHSHCClVoCOlO Wises = 2a. je amen esas See earn Sea eee ee See see VI
Aspenidistrictsheensechlons; Ambo) Gees seer eee ceeeeceereee omer e eee crease eee eee ee VII
Atspemispecialesheet mtOpOerap Dyas saa se aoe oe eas See oe eee ee Ny VIII
PAiSpenispecialsheetwreol ogy ee=ree ae ae seas ters, Sots se ean ae eer eee) Sore a ee Ix
ASioEm Goceiall aE, Senos) AN Wo) Oo cane sSacces sens see SooeS secu Uare Heeb sckoeone sebeees x
TNourtelotte Parkispeciallsheet, toposraphy----22---. 22.2222 22-25. oe eee eee eee XI
Mountelotierbanikespecialysheen eee olo civae eee ae eee nee XII
Tourtelotte Park special sheet, sections A and D ____._______-._.______._____..___-- oe See XIII
Tourtelotte Park special sheet, sections B, C, H, and F ____________. =. 2-262. 222-22 XIV
Tourtelotte Park special sheet, sections G, H, andI_.__._________________.._.--____-__-- XV
Eun bersPankspecialysh ee temo [ Oo Ted Uiiys yeep ete eee eee ent eae XVI
Hunter Park special sheet, geology. .____._._.-____._...------..--.---- SRY eae nt XVII
Elmibe ry at kaspecialeshee ta SEGtl Orsi A wt) © pee eee eae aan eet re XVIII
“Lenado special sheet, topography _-_-.*-- be AE he Pee ee eee Go 2 Ea eeneea las XIX
Lenado special sheet, geology and sections A and B _________.___ ._______---___-.----.--- xx
Tourtelotte Park mining district sheet, geology and topography __.____.___--.--__-_-._-- XXI
Tourtelotte Park mining district sheet, sections A to C _____.____ __________.--_---_----- XXII
Tourtelotte Park mining district sheet, sections D to F_____-_____._____.._____.._..-.... XXIII
Tourtelotte Park mining district sheet, sections G and H ___.___.__..____.___..__..-____- XXIV
Aspen Mountain sheet, geology and topography _---. BA Ra ots a ees SET ae nee le anes SN XXV
AoE MiowiaiENN HaACOu, See MOMs AN WO) e225 osecs. 22 2cscesetesssecnceeees eccececspoe: © 2OMWII
Smuggler Mountain sheet, geology and topography_______._.__._____- Ste i croaale one Rand XXVII
Shemueysllerr MiG wianenia Sate, SeCMOMS AN WO 1D)... 22 = sone nese seo co oses cose meee seeemosnemes = XXVIII
Aspen Mountain sheet, section D, and Smuggler Mountain sheet, section H____._.__.___- XXIX
Lenado mining district sheet, geology and topography, and sections AandB ___.__._._- XXX

SIG IE IIB IS NR TE RCAUN TS UPTO ae

DEPARTMENT OF THE INTERIOR,
Unirep Stares GEOLOGICAL SURVEY,
Washington, June 30, 1896.
Sir: I have the honor to transmit herewith the manuscript of the text
and drawings for the illustrations and atlas of a report on the Geology of
the Aspen Mining District of Colorado, by Mr. Josiah Edward Spurr, and
to request that it be printed as one of the monographs of the Survey.
Very respectfully, your obedient servant,
S. F. Emmons, Geologist in Charge.
Hon. Cuarues. D. Watcort,
Director Umited States Geological Survey.

xii

PREFACE,

Field work in the Aspen district was begun by the writer and Mr.
Tower about July 1, 1895, and continued to about December 1 of the same
year. ‘The summer months were chiefly spent in the study of the surface,
while the fall and early winter were devoted to the investigation of under-
ground phenomena, as shown in mine workings.

At the beginning of the work the first reconnaissance showed that the
structure of the district was peculiarly complicated, and it was recognized
that in order to finish the imvestigation within a reasonable period of time
the methods of work must be modified in proportion to the degree of
complication. Work was begun in the most complicated district—that
represented in the northern part of the Tourtelotte Park special map (Atlas
Sheet XII). Here at first a system of cross-sectioning at intervals of a few
hundred feet was tried, but it was found that the complication was such
that no accurate results could be obtained. The system was then adopted
of examining the whole ground thoroughly by following continuously
formation and fault lines where these outcropped, and locating accurately
every place where bed rock could be found. These results were plotted
together on a topographical map as a record of fact to which all final solu-
tions must conform, and a preliminary complete working map, which filled
out by inference and estimation what the record of fact did not furnish,
was constructed. ‘This being finished, special maps covering the important
mining districts were constructed on a much larger scale. In these districts
the mines were carefully gone through, the mine maps obtained, reduced
_ to a common scale, and plotted together on the topographical maps. When
all the data which could be obtained from this underground work had been
collected, they were combined with the information already obtained from
the surface, and maps on the 300-foot scale were constructed, the details

being worked out by a system of cross-sectioning preliminary to the final
xV

Xvi PREFACE.

areal mapping. From these smaller maps the structure was worked out by
- degrees into the larger maps which inclosed them; and when all possible
information had been assembled, final maps were constructed, ‘which,
however, differed from the preliminary ones only in detail.

The winter months were spent in working out more carefully the
structure of the region, and in microscopic and comparative study of the
rocks and ores. In the spring of 1896 the writer was unexpectedly
requested to proceed to Alaska, and it became necessary to write this report
in asomewhat hurried manner. It was not practicable, therefore, to devote
much care to the writing, and the report is by no means so complete as it
was originally intended to make it. Many things have been lightly passed
over, or even omitted altogether, which might profitably have been worked
out more elaborately. It is hoped, however, that the report may be of
some use to the mining population, for whom it is chiefly intended, el
that from a scientific point of view it may also possess some value.

During all the field and office work on the Aspen district the writer
has been ably seconded by Mr. George Warren Tower, to whose ability
and energy much of the credit of accomplishing such a large amount of
work in so short a time is due.

In conclusion, thanks should be offered to the people of Aspen, who,
with scarcely a single exception, have done everything in their power
toward facilitating the work. To Mr. D W. Brunton and Mr. D. Rohlfing
especial acknowledgments are due, but to name all the gentlemen from
whom favors have been received would simply be to furnish a list of
prominent mining men in Aspen; nor should the common miner and
prospector be omitted, whose ready courtesy and hospitality will long be a

pleasant remembrance.
Jostan EDWARD SPURR.
Wasuineton, May 20, 1896.

INTRODUCTION.

By 8. F. Emmons.

POSITION.

Aspen is one of the most picturesquely situated mining towns of the
Rocky Mountain region. It lies in the valley of the Roaring Fork River,
at a point where that stream issues from the area of granite and gneiss
which constitutes the uplift of the Sawatch Mountains into the upturned
Paleozoic and Mesozoic strata that encircle it. The Roaring Fork heads
in the Sawatch Mountains, on the west side of the main crest and about
opposite the Twin Lakes of the Arkansas Valley. Its general course is
northwest, and below Aspen it flows along the eastern flank of the Elk
Mountain uplift for about 50 miles to its junction with Grand River at
Glenwood Springs. The scenery along this stream above Aspen is very
sharply contrasted with that below, and in both regions is largely dependent
upon the geological structure. Above is a relatively broad and straight
valley, lying between rounded and generally rather barren-looking hills
of granite and gneiss, bare of vegetation and forbidding of aspect. At
Aspen the character of the scenery changes; the hills are well covered with
vegetation, and are remarkably steep and rugged in topographical form;
the valley bottom is now broader and is filled up, to a certain extent,
with horizontally bedded gravel deposits, which form a nearly level plain,
admirably adapted for the location of a town.

As has already been remarked,’ the scenery and topographical forms of
the Elk Mountain region are characterized by a peculiarly alpine aspect,
in strong contrast to those of the eastern flanks of the Rocky Mountains.
This is due in part to the greater rainfall on the western slopes, and in part

1Geologic Atlas U. S., folio 9, Anthracite-Crested Butte, Colorado, 1894.
MON XXxXxI IT xvii

XVill INTRODUCTION.

to the underlying geological structure of the region. The valleys are
generally narrower and deeper, the mountains more rugged and precip-
itous, and the surface of both is more luxuriantly covered with forest and
plant growth.

The most striking and characteristic feature of the scenery at Aspen
is the narrow spur or ridge to the west of the town, lying between the
valleys of the Roaring Fork and Castle Creek, which is generally known
as Aspen Mountain. The northern portion of the spur to which this
name is applied rises from the valley flat on which the town is situated in
a slope whose steepness is exceeded only by that of the western slope of
the same spur toward Castle Creek. How steep either slope must be will
appear when one considers that the base of the mountain is only from a
mile to a mile and a half wide, while its crest is 2,000 to 3,000 feet above
the valleys that lie at the base on either side. As seen from the town, this
ridge appears to have three summits, to which the names Aspen, West
Aspen, and East Aspen mountains have been given, the first being the
main crest of the spur, West Aspen Mountain its rugged northern point,
and Kast Aspen Mountain the more rounded portion of the spur, stretching
northeastward at the gateway of the Roaring Fork Valley, where the river
issues from the granite region of the Sawatch.

East of the town, between Roaring Fork and Hunter Creek, rises the
steep but rounded spur called Smuggler Mountain, named from the mine
that was early opened upon it, while northward, forming the eastern wall
of the lower part of the valley, is the long, flat-topped spur called Red
Mountain.

From the following report it will be seen that the great mineral wealth
of this region is found in a narrow belt of Paleozoic rocks, which are steeply
upturned against the granite and broken in the most complicated manner by
a network of faults; that it is along these faults, and proceeding from them
outward where they traverse calcareous and dolomitic beds, that the princi-
pal ore deposition has taken place; and that this faulting, which commenced
with the earliest folding of the sedimentary rocks and has continued to a
certain extent to the present day, has been most intense and long continued
on the ridge known as Aspen Mountain, which is so striking to the eye by
reason of its peculiar form, and which, as the present investigation has
shown, presents evidence of dynamic disturbance greater than that of any

INTRODUCTION. XIx

area of similar size yet observed in the State, not excepting even the
remarkable region of the Leadville mines.

If one examines a general geological map of Colorado it will be noted
that at just this poimt the strike of the Paleozoic rocks resting upon the
Sawatch granite changes abruptly from a little west of north to northeast.
The geological significance of this change of strike is that here is the point
where the two converging uplifts of the Sawatch and the younger Elk
Mountains come together, and that, whereas north of this point there was
room for the sedimentary beds included between them to be compressed into
broad anticlines and synclines, here they came so close together that there
was no room for the development of more than embryonic folds, and the
rock strata were crushed, squeezed, and broken into narrow blocks or sheets
by a complicated system of faults.

DISCOVERY.

Though it is doubtful whether the early prospectors possessed a suffi-
ciently broad geological knowledge to have observed the above facts, it is
tolerably certain that those who first came here in 1879, men who had been
working in Leadville, had observed on the maps of the Geological Atlas of
Colorado that the Paleozoic rocks that carry the silver at Leadville nearly
encircle the Sawatch uplift, and that, with the keen observation that charac-
terizes men of their profession, they selected limestone beds of the same
horizon as the ore-bearing zone at Leadville in which to make their
investigations.

In the summer of 1879 the Durant, Iron, Spar, Monarch, Late Acqui-
sition, and Smuggler claims were located. During the winter work was
suspended, in great measure because of the Indian revolt on the neighbor-
ing Ute reservation. In the spring of 1880, however, the Emma, Aspen,
Vallejo, Mollie Gibson, Argentum-Juniata, Della 8., J. C. Johnson, Park-
Regent, and other claims were located. The town, which had at first been
called “Ute,” was rechristened Aspen, probably from the abundance of that
tree on the neighboring hills. Explorations continued along the strike of
the limestone belt, and claims were located along it for a distance of 30 to
45 miles, reaching the valley of the Frying Pan on the northeast and that
of Taylor River on the south. Ashcroft, at the head of Castle Creek, was
at first the most important mining town, but although the geological indica-
tions around it are most promising, but few considerable bodies of rich ore

XxX INTRODUCTION.

have been discovered in that region, the only mines now producing being
the Express mine, at the Leadville horizon, and the Montezuma group on
Castle Peak, in the Maroon formation and diorite, at about 13,500 feet above
sea level. The richer deposits near Aspen itself made but little show upon
the surface. On Smuggler Mountain and along the base of Aspen Mountain
their outcrops are buried beneath glacial gravels; moreover, the ore contains
much less iron and manganese than the Leadville deposits, and hence the
outcrops of the ore bodies are not so readily distinguishable from ordinary
altered limestone or dolomite.

Thus in 1881 and 1882 the prospects on the Castle Creek slope of
Aspen Mountain were considered the more promising, and it was not until
1884 that the existence of the very rich ore bodies on Spar Ridge was dis-
closed by the workings of the Emma and Aspen mines. As a.result of the
excitement consequent upon these discoveries, the town of Ashcroft was
moved almost bodily to Aspen, many houses having been dragged over
the 12 miles that separate the two towns.

DEVELOPMENT.

For the first six years of its existence the great drawback to the
development of the district was its inaccessibility. It could be reached
from existing railroads only by crossing the summits of lofty ranges of
mountains. The shortest and most generally traveled line of approach
from the east left the railroad at Granite, 15 miles below Leadville, in the
valley of the Arkansas, and ascending the Lake Fork, passed Twin Lakes,
crossed the summit of the Sawatch by Hunter Pass, and descended to
Independence and thence down the Roaring Fork to Aspen, a distance of
about 40 miles. A second route, 72 miles in length, leaving the railroad
at Buena Vista, lower down the Arkansas Valley, crossed the Sawatch by
Cottonwood Pass or Chalk Creek Pass, each about 11,000 feet high, into
the valley of Taylor River, and ascending that, crossed Taylor Pass to
Ashcroft, and thence followed down Castle Creek to Aspen.

The first shipment of ore from Aspén came from the Spar and Chloride
mines on Aspen Mountain; the ore was transported on the backs of burros
or jackasses to Granite or Leadville to be smelted. The cost of such
transportation was at first from $50 to $100 per ton, but as competition
increased these rates were reduced, near the time of advent of the railroads,
to $25 per ton.

INTRODUCTION. Xxl

In 1886 the Colorado Midland Railroad, which had built its line from
Colorado Springs to Leadville in order to get part of the profitable ore-
carrying business of the latter place, was induced by the promising devel-
opments of ore at Aspen to project a line to that point. This work had
hardly been undertaken when the Denver and Rio Grande Railroad Com-
pany, whose line was already built down the Eagle River to Red Cliff, felt
obliged to enter into competition for the Aspen trade, and a railroad-
building contest ensued, each striving to reach the objective point first.
The line of the Colorado Midland, which was a broad-gauge road, ascended
the Sawatch Range directly opposite Leadville, passing through its crest
by a tunnel at Hagerman Pass, and descending Frying Pan Creek to
the Roaring Fork. The route of the Denver and Rio Grande Railroad
was longer, but it was then a narrow-gauge line, and it followed valleys all
the way, descending the Kagle and Grand rivers to Glenwood Springs,
and thence ascending the valley of the Roaring Fork. In spite of the
difficult engineering and the many tunnels in the magnificent canyon
of Grand River above Glenwood, the Denver and Rio Grande reached
Aspen first, in October, 1887, while the trains of the Colorado Midland did
not actually reach the town limits until February, 1888. By the advent
of the railroads the expense of transportation of ore to the smelters at
Leadville, Pueblo, or Denver, was reduced to $10 or $15 per ton, and
in later years, under special circumstances, this rate has been reduced as
low as $5 per ton, the charges being in a measure proportioned to the
value of the ore, thus favoring, in the interest of all concerned,
the working of ores of lower grade than would otherwise be possible.

LITIGATION.

Another cause besides the difficulty of transportation that has retarded
the development of the Aspen mines has been the many lawsuits in regard
to the ownership of the most valuable ore bodies that have sprung up as a
natural conseqence of the peculiar unfitness of the United States mining
laws for giving a clear title, or even any title at all, to deposits of this
nature.

It is not the province of employees of this Survey to discuss the merits
or demerits of rival claims to mining property under survey; indeed, as
they often enter properties in regard to which suits are pending, it is their

XXil INTRODUCTION.

practice to avoid any knowledge of the points at issue, at least until their
examinations are completed and their conclusions reached, in order that
their opinions may be drawn solely from the facts of nature, with no possi-
ble bias from such litigation.

The suits in regard to Aspen mines, however, have been notorious as
showing the relative advantages and disadvantages of the two methods of
giving title to mining claims—i. e., according to what may be called the law
of the apex, which is peculiar to the United States, or according to square
locations, or vertical side-line boundaries, which is the practice in regard to
all other land titles, and the method of granting mining titles that obtains
among all other nations which have important mining industries. At the
request of the writer Mr. D. W. Brunton, a leading mining engineer of
Aspen, who has taken active part m most of the suits, has furnished the
following brief statement of the points at issue in the more important
mining suits at Aspen, and of the manner in which the disputes have

respectively been decided.
MINING SUITS.

In November, 1883, the Spar mine, situated on the crest of what is known
as Spar Ridge, on Aspen Mountain, had followed the contact between the blue
limestone and the brown dolomite to and into the Washington No. 2, a mining
claim lying immediately west of the Spar, and had uncovered considerable ore
bodies in the Washington No. 2 claim. The Washington claimants were then
engaged in mining ore within their surface boundaries, and the owners of the
Spar brought an injunction suit in the circuit court of the United States at Den-
ver to restrain the Washington claimants from mining ores within the end lines
extended westerly of the Spar claim. The contention of the Spar claimants was,
in substance, that they owned the apex or outcrop of a contact vein lying between
the blue and brown limestones, which vein, on its dip and downward course into the
earth, extended beyond the westerly side line of the Spar and into the territory
of the Washington No. 2 claim. This contention was denied by the Washington
No. 2 owners, who claimed that the ores of Aspen Mountain, or at least those
included within the Washington No. 2 claim, did not occur in any true lode or
vein, but that the same occurred in segregated masses, pockets, and impregna-
tions, fortuitously distributed through the limestones forming the mass of the
mountain, and that, therefore, the same did not come within the purview of the
statute permitting the owner of the apex or outcrop of the vein to follow the same
on its dip beyond his vertical side lines and into the territory of adjoining
claimants. This was the original apex suit in Aspen, and was settled, in a few
months and before any trial upon the merits was had, by the owners of the Spar
purchasing the Washington No. 2 claim.

INTRODUCTION. XXill

The Durant mining claim lies immediately south of the Spar claim, and in
1884 its owners started an incline upon the contact between the blue and brown
limestones, directing the same toward the rich ore bodies discovered about that
time in the Emma and Aspen claims, which claims lay from 300 to 500 feet
west of the Durant claim. In the winter of 1884 and spring of 1885 the Durant
claimants instituted injunction proceedings, followed by ejectment suits, claiming
all the ores within the end lines of the Durant claim extended westerly, by reason
of the alleged existence of the apex of the vein containing these ores within the
Durant mining claim. The substantial result of these injunction proceedings was
to prevent the production of ores from the richest mines on Aspen Mountain
pending the determination of these suits, which were four or five in number.
The defendants in the various suits denied the existence of any vein or lode of
ore in Aspen Mountain within the meaning of the statutes governing extra-
lateral rights, and alleged that the ore bodies consisted of segregated masses,
pockets, and impregnations, occurring sometimes in the blue limestone or calcite,
sometimes in the brown limestone or dolomite, and sometimes at or near the
contact between these two formations. It was also claimed that the limestone
strata containing the ores of Aspen Mountain were synclinal, the east crest or
Spar Ridge forming one edge or outcrop, and the other outcropping on what is
known as West Aspen Mountain. It was further demonstrated that rich ores
occurred in various places at or near the surface of the blue limestone strata
throughout this synclinal area, and that these were sometimes connected by ore-
- bearing faults or fissures with the main ore bodies of the mountain. They also
denied the continuity of the so-called apex or outcrop throughout the length of
the Durant claim. These cases were bitterly contested, vast amounts of money
being spent in the employment of counsel, and still larger amounts in develop-
ment work made by each party, looking to the establishment of its favorite theory.
The first and only case to come to trial upon the merits was that of the Durant
against the Emma, which was tried in December, 1886, occupying some three weeks
in the United States circuit court at Denver. The result was a verdict in favor
of the apex claimants. The so-called side-line claimants, the defendants in this
suit, immediately paid up the costs under the statutes of Colorado, and were
awarded a new trial, and at once instituted a more vigorous policy of development
for the purpose of refuting the position of the apex claimants, and during the year
1887 large amounts of money were expended by both sides in preparing for the
next contest. The side-line claimants, among which were the owners of the
Washington No. 2, Emma, Vallejo, Aspen, Aspen Mammoth, and other claims,
contributed to a common pool, known as the side-line defense fund, for the purpose
of defeating the apex claims.

In 1888, before any further trials were had, a settlement was effected between
the owners of the apex and side-line claims, the substance of which was that
the side-line claimants deeded one-half of the ores contained within their sur-
face boundaries to the apex claimants, the apex claimants, on the other hand,

XXIV INTRODUCTION.

releasing to the various side-line claimants one-half of the ores contained within
the surface boundaries extended downward vertically of such side-line claims.

Throughout this litigation the ablest mining lawyers in Colorado were engaged
on one side or the other of the controversy and the best mining experts and geolo-
cists of the country were employed to formulate theories and direct the developments
on behalf of each side. It is conservatively estimated that the cost of the litigation
up to the time of settlement, including attorneys’ fees, expert witnesses, and devel-
opment made for the purpose of these suits, and which was useless for any other
purpose, was more than the sum of $1,000,000. .

Next in importance came the litigation on Smuggler Mountain between the
Standard Mining Company, of Kansas City, as owners of the J. C. Johnson and
Chatfield claims, against the Della S. Mining Company, the latter company owning
a number of claims lying westerly from and below the J. C. Johnson and Chatfield.
This contention began in the latter part of 1890 and ended in February, 1892, and
involved the ownership of exceedingly large and valuable ore bodies on Smuggler
Mountain. The theories of the contending parties are well stated by Judge Hallett
in his charge to the jury, from which the following extracts are taken:

PLAINTIFF’S POSITION.

The position of the plaintiff in this instance is that the locations to which they have estab-
lished titles, the J. C. Johnson and the Chatfield, have within their limits the apex of the vein
which, in its descent into the earth and through the side lines of these locations, extends into that
adjoining, which is owned by the defendant. So that by virture of the ownership of the top or
apex, under this statute, they are entitled to claim the lode from the top of the ground extending
into the territory adjoining. i

*% C9 * * * * *

THEORY OF THE DEFENSE.

The theory of the defense is that, after the vein was deposited in this fissure or opening from
the top of the mountain downward, there came a fault which broke off the lower part from the
upper and removed the upper part some distance easterly, something over 200 feet easterly, so as
to entirely dissever and disconnect them in such a way that the ownership of one can not be said
to be the ownership of the other. In this there are two propositions: One that the fault occurred,
and the other that the vein was deposited before that fault occurred. * * *

The trial occupied ten days, the jury returning a verdict in favor of the Della
S. Mining Company, thus in effect finding that the vein which has its apex in the
J. C. Johnson claim had been faulted subsequent to the deposition of the ore bodies,
and that the J. C. Johnson vein ceased at the eastern edge of the fault plane, and
that the Della S. vein, commencing at the western side or edge of the fault plane,
constituted a separate and independent vein within the Della S. territory. Within
afew days after the trial the case was settled, the entire property passing to the —
Della 5. Consolidated Mining Company.

Spar Ridge, upon which occur the so-called apexes of the Durant,
Spar, Emma, Aspen, and other ore bodies, is a knife-edge of bare rock

which trends with the strike of the limestones that inclose the ore, and on

INTRODUCTION. XXV

which, if anywhere, it should have been possible for the original locators
so clearly to define their ore body as to avoid such disputes as these, which
so seriously detract from its value. A perusal of the following pages will
show, however, that it was utterly impossible for anyone to foretell from
the surface indications what would be the form and position of these bodies
in depth; and further, that while the inference that it was a deposit follow-
ing a contact or bedding plane between two sedimentary beds was a proper
and just one from surface indications, this contact is in reality a fault and
not a single bedding plane; and that the ore has been deposited in this
portion of the district, not along any single plane, but by waters following
a complicated system of faults of constantly varying strike and dip, which
it was utterly impossible to define in accordance with the terms of the
United States mining law; and that the only possible way of defining
the claim to such ore bodies is by vertical side lines, irrespective of the
form or direction that the ore body may take in depth, a method to which
the mine owners inevitably come in the long run, whether by compromise
beforehand or after they have wasted their means in the enormous expenses
inevitably attendant upon such lawsuits. In the other case quoted by Mr.
Brunton, where there could be no outcrops of the ore bodies whatever, the
hill being deeply covered with gravel and wash, the great skill exercised
by the engineers employed by the mines and the acumen shown by the
learned judge, who is famed for his knowledge and correct understanding
of ore deposits, in explaining the two questions in dispute, did not result
in a verdict that is strictly in accordance with the facts, for the present
investigations have shown that the fault in question must have been
formed prior to the deposition of the ore, but that movement on it has
continued since that deposition, a condition of things that the law has not
and could not have foreseen.

The conditions attendant upon the deposition of ore bodies in general
are found to be more and more complicated as accurate studies of them
progress, and they are not found to be identical in any two mining districts.
It is therefore an inherent impossibility so to frame the definition of an ore
deposit, if the owner is allowed to go outside of his surface boundaries
vertically projected, that it will not give rise to litigation in a vast number
of cases, or work great injustice to a large proportion of claim owners.

XXvl1 INTRODUCTION.

EXPLOITATION.

In the exploitation of its mines and the reduction of its ores Aspen
has shown itself to be unusually enterprising, and has led the way in many
improvements in either branch of mining As early as 1882 smelting
works were built at the northern edge of the town, which were run more
or less continuously up to 1887. That they should be financially success-
ful when obliged to depend on the ores from a single district was hardly
to be expected, and when by the advent of the railroad they were brought
into competition with centrally situated works at Denver and Pueblo,
which drew their ore supplies from all parts of the mountains, they were
naturally closed down. Extensive lixiviation works, designed by C. A.
Stetefeldt, were erected in 1891 on the north bank of Castle Creek, and
operated until the crash of 1893. They employed a modification of the
Russell process. The financial success of these works is also said to have
been doubtful.

There have been many sampling works in the district, the first of
which was opened in 1883. At present there are two, the Aspen Sampler
and the Taylor and Brunton works, and through them passes fully 90
per cent of the ores that are shipped from the district. These extremely
useful institutions act as middlemen between the miners and the smelters.
To the former they pay promptly the market value of their ore, carefully
determined by reliable scientific methods, after deducting the necessary
charges for sampling, freight, royalties, and smelting charges. To the
latter they are enabled to furnish mixtures of ores containing the various
metals in proportions desirable for smelting charges.

Situated as it is at the junction of three rapid and considerable moun-
tain streams, which furnish a readily available water power, Aspen has
unusually good opportunities for the location of power plants for generating
electric currents, which may be used not only for lighting purposes, but
also to transmit power to the many mines situated on the steep and diffi-
cultly accessible mountain slopes. It was among the first, if not the very
first, of the mining districts to make use of electric hoists (July, 1888) and
electric pumps in the mines. The entire plant of the new Free Silver shaft
on Smuggler Mountain, designed for a depth of 1,000 feet and more, is run
by electricity. There are at present two public companies for furnishing

INTRODUCTION. XXVIl

electric light and power to the town and its mines, and no city in the
State has better light for domestic purposes than Aspen.

For the transportation of ore down from and supplies up to the mines,
situated high up on the hills, several aerial wire tramways of different
systems are in operation. On both Aspen and Smuggler mountains long
drainage tunnels have been run for drainage and extraction purposes. The
longest of these, the Cowenhoven tunnel. which is owned by a separate
and distinct company, is over 8,300 feet long, and is designed to tap all
the mines beyond the Smuggler on Smuggler Mountain.

Of late years, since the largest and richest of the magnificent bodies of
silver ore thus far discovered, and for which Aspen is justly famous, have
been worked out, and since the mining profit has been so greatly reduced
in all the mines of the district by the decline in the price of silver, the
system of leasing the whole or parts of a mine to individuals or groups of
miners has become common, as it is in other parts of Colorado. Under this
system, while the mine owner may receive less profit from rich ground,
the loss, if any, is distributed among a number of individuals and becomes
proportionately smaller im each case. Greater economies are practiced
where each miner has a personal interest in keeping the costs down to
the very lowest figure, so that it is possible under this system to extract
ore at a small profit, especially in old and abandoned workings, on which
the company itself would probably lose money.

Various systems of leasing are employed in the district. Sometimes
one or more individuals lease the whole of a mine and sublet it in portions
to individual miners or groups of miners. The lessee frequently pays men
to work for him at “grub wages,” furnishing them only food and allowing
a contingent interest in the profits.

In other cases the mine is divided into blocks of varying dimensions,
which are leased to the highest bidder, the company retaining control of the
mine and furnishing power, foremen, engineers, timbermen, skip tenders,
etc., and requiring each lessee to work in a systematic manner and to keep
his portion of the mine in proper condition.

XXVIil INTRODUCTION.

The royalties paid vary greatly with varying conditions of lease and
with the grade of ore that may be expected. In a certain mine the royalty
was fixed for the year 1895 by the following sliding scale:

Royalty on ore.

Carrying Ag. (average to the ton)— Per cent.
Wid) To) 20) OUNCES 2 ose Sscces Sones sesesadseness 10
iDiyopen 2A0) tio) Sil) OWLNCOSs oes sees Ssosseseoceosee 15
From 30 to 40 ounces---.------.------------- 25
Iprgoren, 20) (Ko) Bi) OWENS. oes coe ase eosae s 35
From 50 to 60 ounces.-...-------------------- 40
From 60 to 70 ounces__-------.--------------- 45
From 70 to 80 ounces. .----.--.--------------- 50
From 80 to 90 ounces. -.-.--..---------------- 55
From 90 to 100 ounces.-__.--------.----------- 60
From 100 to 120 ounces___-------------------- 65
Overd20iouncess: a2 3-4 bans s See eee see ee 70

The average returns under this schedule for twelve months are given
at $6.48 profit per ton to the lessee and $5.24 to the company.

Another important mine, whose ores are exceptionally rich, charges a
flat royalty of 70 per cent of the net returns.

PRODUCTION.

The ores of Aspen are essentially silver ores, and contain remarkably
small amounts of other metals, with the exception of lead. Very consider-
able bodies of ore, notably the wonderfully rich bodies of polybasite and
native silver found in the mines of Smuggler Mountain, are practically free
even from lead.

Traces of gold have been found from time to time, but there is only
one authentic case on record where the amount in a lot of ore was sufficient
to be paid for by the smelter.

Copper occurs in appreciable amount in the Dubuque mine, in Queens
Gulch, and in some of the deeper mines. It is not, however, noted in the
settlings of the samplers, and hence must be in very small amount in the
aggregate.

Zinc has been found in considerable amounts in the Aspen Contact
mine, at Lenado, and in the Smuggler, Dubuque, and others, but does not
play an important part in the average contents of the ores.

INTRODUCTION. OXIDE

Lead is abundant in certain ore bodies, and may run as high as 70 per
cent, but it is not possible to give the aggregate production of this metal
in the district, for the reason that it is seldom accounted for in the mint
statistics. In the Census reports for the year 1889 its value is given as 34
per cent of that of the total metallic product, the balance being silver.

It has not been found possible to obtain figures of production directly
from the mines in all cases; hence this method of determining the aggre-
gate silver product of the district had to be abandoned, and recourse was
had to the only other available source, the records of the mint at Denver,
which were gathered for it by different individuals in different years, and
hence are liable to a large personal error. They may include some ores
not strictly belonging to the Aspen district, the returns being made as from
Pitkin County. In the following table, made up from these data, there
having been no return given by the mint official for the year 1885, the
amount for this year was determined by interpolation between the preced-
ing and following years, and for the year 1889 the figures of the census
were taken as having probably been estimated with more care and detail.

Finally, the figures for the year 1895 were obtained by calculating the
tonnage given by samplers as the average contents in silver given by 306
assays of average ores, and adding 225,000 ounces shipped direct from
mine to smelter.

Silver product of Aspen mining district, 1881 to 1895, inclusive.

Year. Ounces of silver.| Coinage value.

TGS Tae eee tah ee eee 23, 204 $30, 000
1882s es2 St ass a aes ae 23, 204 30, 000
1883 4-22 usec eeeebee esses 42, 540 5d, 000
OB Ae et ane eee ee eae 464, 073 600, 000
SSS 2s ee ae AS yeas 460,000 | 594,734
SSCP eae eee eee eee 454, 247 587, 296
TSSTMeeine eS ae Soe 639, 336 826, 597
1SBG peers ees atlas Ce 5, 536, 649 7, 158, 327
SOO Rae ie sey opy he Seer 5, 677, 308 7,340, 184
VES 0 Bee eee es sao. eee tes 5, 246, 458 6, 783, 145
ICO a cee peas Saaee eee asee 6, 963, 289 9, 002, 830
Sc eee ae SIE 8, 256, 467 10, 674, 722
LUC) Sete era ie, eae Ne 4, 443, 310 5, 744, 749
SOAS a: RE ss eee een 6, 039, 799 7, 808, 850
BO EH ot oe ae eee 4, 963, 690 6, 417, 555

Totalee4ae eos see 49, 233, 574 68, 653, 989

Xxx INTRODUCTION.

The notable changes in the above table are, first, the almost tenfold
inerease in production from the year 1887 to 1888, due to the advent of
the railroads, and to the compromise of the apex side-line suit; second, the
decrease of nearly one-half from the year 1892 to 1893, due to the sudden
decline in the price of silver, and in part to the working out of some of the
large bodies of very rich ore that had increased production greatly during
the two or three previous years.

GEOLOGICAL INVESTIGATIONS.

The mines of Aspen were mostly discovered and opened by men whose
most recent mining experience had been at Leadville, where the silver ores
were found principally at or near the contact of limestone with overlying
sheets of porphyry, and where the great faults, having been formed since
the period of ore deposition, were barren of original deposits. In this new
district, therefore, the miners naturally looked for similar conditions, and
finding ore between the blue and brown limestone at their outcrop, assumed
that it was a contact deposit between these two beds, and located claims
accordingly.

When, in the summer of 1887, while engaged upon the survey of the
southern Elk Mountains, the writer made a hasty reconnaissance of the
Aspen mining district and its immediate vicinity, the contact theory was
still held by a large part of the mining community, and those who did not
partake in this belief had no very definite theory to offer in its place.

The writer’s underground observations, which were made in the com-
pany of upholders of either belief, led him to conclude that the ore had
been deposited along fault planes and from there outward into the body of
surrounding limestone, but he saw that only thorough and careful work,
based on most detailed maps, both of surface and of underground workings,
could finally determine these questions on a scale of accuracy proportionate
to the magnitude of the interests involved. He therefore urged upon the
Director of the Survey the importance of having such a monographic study
made of the district, but it was not until the summer of 1890 that it was
found practicable to commence a survey for special topographical maps
of the region. ‘These maps, made under the direction of Mr. Morris Bien,
were completed in the summer of 1891, and as soon as printed were dis-
tributed among those interested in Aspen mines. These persons, who had

INTRODUCTION. ROXEX

opportunity in their daily work to subject the maps to the severest tests,
have borne testimony to their high degree of accuracy. The geological
examination of the district, which was planned for the summer of 1892, was
necessarily postponed in consequence of the provisions in the appropriation
act passed by Congress in July, 1892, which not only cut down the amount
allotted to geological work, but specifically reduced the number of geolo-
gists employed, and resulted in the discharge from the Survey of the four
geologists who were especially devoted to economic work, of whom the
writer was one.

The present Director assumed control of the work of the Survey in
July, 1894, but it was then too late to undertake so elaborate a piece of
work as the Aspen survey, and it was therefore postponed until the season
of 1895.

In consequence of a severe attack of pneumonia in the early part of
that season, the writer was incapacitated for the arduous physical labor
involved in the work planned, and was obliged to trust the practical
execution of the work to Mr. J. E. Spurr, who had been his assistant dur-
ing the previous season, and to content himself with acting in an advisory
capacity and making two short visits to the district during its progress.

Mr. Spurr was occupied in the field work from June to December,
1895, and was assisted during this time by Mr. G. W. Tower. Too great
credit can not be given to these two geologists for the zeal and energy
which they have displayed in unraveling this most difficult problem in
structural and economic geology in so short a time and in so thorough a
manner. The magnitude of the work will be appreciated by an exami-
nation of the following pages and the atlas of maps and sections which
accompanies the volume.

Having received orders to proceed to Alaska for an examination of
the interior regions in the valley of the Yukon, Mr. Spurr has been obliged
to complete his office studies of the material gathered, and the platting of
the geological data on maps and sections, as well as the writing of the
text, so as to leave for his new field of work by June 1. It has been
thought best to publish the volume at once, even though, owing to the
great pressure under which it has been written, there may have been less
attention given to the form of presentation than if it had been more delib-
erately considered. For the facts, as well as for the theoretical conclusions
presented, Mr. Spurr desires to assume the entire responsibility.

XXXil

1887.

1888.

INTRODUCTION.

LITERATURE.

The following list comprises the principal scientific publications upon
Aspen and its mines, as far as known to the writer:

il,

(a)

5, 10.

Geology of the Aspen Mining Region, Pitkin County, Colo., by A. Lakes: Biennial report
of the State School of Mines, Denver, 1887, pp. 45-84.

. Preliminary Notes on Aspen, Colo., by S. F. Emmons: Proc. Colorado Scientific Society,

Vol. Il, Part 3, 1887, pp. 251-277.

. Geology of the Aspen Ore Deposits, by L. D. Siver: Eng. and Min. Jour., Vol. XLV, Mar.

17, 1888, p. 195, and Mar. 24, 1888, p. 212.

. Notes on the Geology and Some of the Mines of Aspen Mountain, Pitkin County, Colo.,

by Carl Henrich: Trans. Am. Inst. Min. Eng.. Vol. XVII, May, 1888, pp. 156-161.

. Aspen, Its Ores and Mode of Occurrence, by D. W. Brunton: Eng. and Min. Jour., Vol.

XLVI, July 14, 1888, p. 22, and July 21, 1888, p. 42.

. Geology of Colorado Ore Deposits, by A. Lakes; Denver, 1888, pp. 119-153.
. Notes on the Geology of the Aspen Mining District, by W. E. Newberry: Trans. Am.

Inst. Min. Eng.. Vol. XVIII, June, 1889, pp. 273-278.

. The Use of Electric Power Transmission at Aspen, Colo., by C. E. Doolittle: Trane, Am,

Inst. Min. Eng., Vol. XIX, Oct., 1890, pp. 282-288.

. Electricity in Mining as Applied by the Aspen Mining and Smelting Company, by M. B.

Holt: Trans. Am. Inst. Min. Eng., Vol. XX, Oct., 1891, pp. 316-324.
An Experiment in Cooperative Mining, by D. W. Brunton: Eng. and Min. Jour., Aug.
3, 1895.

OUTLINE OF THIS MONOGRAPH.

The various divisions in the geology of the Aspen district are treated in this report in
chronological order. Thus. Chapter I treats of the original structure of the sedimentary and
igneous rocks and of the conditions under which they were laid down or intruded; Chapter IL
treats of the physical changes which have come about since their deposition, consisting mainly
of folding and faulting; Chapter IV treats of the chemical changes which came about subsequent
to or were attendant upon the physical changes, and were produced chiefly by metasomatic
interchange, dolomization, silicification, ore deposition, and other phenomena; and Chapter V isa
slight sketch of some of the surface changes which have occurred in comparatively recent times,
since the ore deposition. Between the description of the physical and chemical changes is inserted
a chapter describing in detail the mines and productive localities, this description being essential
to the understanding of the various geological phenomena, especially that of ore deposition.

The fundamental rock in the Aspen district is a granite, with occasional gneissic structure.
Above this come successively the sedimentary beds of the Cambrian, Silurian, Devonian, Carbon-
iferous, Juratrias, and Cretaceous. The beds of the Cambrian, Silurian, and Devonian are
comparatively thin, while the Carboniferous, which is divided into three distinct formations—the
Leadville, the Weber, and the Maroon—attains a great thickness. The Juratrias and the Creta-
ceous are also very thick, the latter containing the various subdivisions of the Dakota, the Colorado,
the Montana, and the Laramie. Separating these different beds at intervals are various uncon-
formities and planes of erosion, which help one to read the history of the rock and to understand
the conditions under which the beds were laid down.

Into these sedimentary rocks were intruded, probably in Cretaceous time, rocks of igneous
origin. These are of two distinct types—one a diorite-porphyry and the other a quartz-porphyry.
Both occur as sheets nearly parallel to the bedding of the sedimentaries, and as occasional cross-
cutting dikes. The diorite-porphyry occurs chiefly as a single sheet, which widens toward the
south and ultimately runs into the main diorite mass of the Elk Mountains. The quartz-porphyry,
on the other hand, has probably ascended along narrow channels in the immediate vicinity of
Aspen, and the structure of this rock shows it to belong to a type which characterizes the
Mosquito Range, on the east side of the Sawatch, rather than the Elk Mountain district.

Subsequent to the deposition of the Laramie and the intrusion of these eruptive rocks,
physical disturbance began. Among the first changes was the elevation of the Sawatch Range,
so that the beds which lay round its flanks assumed a general dip away from the main uplift. At
about the same time occurred some minor folding, which was apparently due to a lateral thrust
exerted from the westward, and in the Aspen district was most pronounced in a narrow zone.
Here an overthrown anticline was formed, which culminated in a great break, called the Castle

MON XXxXI——YIII Xxxlii

XXXIV OUTLINE OF THIS MONOGRAPH.

Creek fault. Probably beginning at the same period, but continuing afterwards, was the develop-
ment of a domelike uplift, which affected both granite and sedimentary rocks in a restricted
region east of the Castle Creek fault, now occupied by Aspen Mountain and Tourtelotte Park.
This uplift was marked on the north side by asharp bending-up of the strata, while on the west
side the movement took place along the previously formed Castle Creek fault; on the other side
the extent of the uplift can not be accurately judged, on accouns of its running into the granite.
The bending-up of the beds was accompanied by faulting, which has gone on continuously from
that time to the present day. At the beginning few faults were developed, but these appear to
have had an important throw. As erosion progressively removed the overlying load of strata,
the faults became more numerous and complicated, but the amount of throw in each case grew
less, A number of distinct fault systems have been identified, differing chiefly in point of age.
This difference in age is shown by the faulting of one system by a later system, and also by the
fact that certain faults have developed before and certain others after the ore deposition. It is
also shown that some faults have developed almost entirely in post-Glacial time, and that in
many cases the fault movement is going on at the present day.

Along the channels afforded by faults hot-spring waters rose and brought about certain
chemical changes. One of the most interesting of these is dolomization, and the combined
evidence at Aspen and at Glenwood Springs, where the change is now being brought about by
hot ascending waters, shows that the process is essentially a chemical interchange effected
between the calcium carbonate in the limestone and carbonate of magnesia brought in by these
circulating waters. Thus zones in the limestone following watercourses which are parallel to
the bedding or which cut across it are locally altered to dolomite. There is, however, evidence
of an earlier period of dolomization, which preceded the faulting and probably came about very
early in the history of the rocks. Thus the Silurian sediments and those of the lower part of
the Leadville formation were early converted into dolomite, probably by the action of magnesium
salts contained in the waters of a shallow and evaporating sea.

Associated with the formation of the dolomite along fault fractures and watercourses is
the deposition of silica and of iron, and both these processes must be referred to the same
cause as the dolomization.

The ores of the district consist chiefly of lead and zinc sulphides, carrying silver, with a
gangue of barite, quartz, and dolomite. On oxidation the sulphides change to sulphates, carbon-
ates, and oxides. The deposition of the metallic minerals has taken place almost exclusively along
the faults, but it is only in certain places that the fault zones become sufficiently mineralized to
form valuable ore, for it is chiefly at the intersection of two or more faults that rich shoots are
formed. The intimate association of the metallic sulphides with dolomite, quartz, and other
gangue materials suggests a common origin for all—that they were deposited by ascending hot
waters. Since the ore has been found chiefly at the intersection of faults, the theory is advanced
that solutions ascending along one of these channels were precipitated by solutions which
circulated along the other.

Among the more recent chemical changes in the rocks, mainly subsequent to the ore depo-
sition and its attendant phenomena, is the formation of sulphates. Thus a considerable quantity
of gypsum has been locally precipitated, and soluble sulphates occur as incrustation on rocks
which have been exposed to oxidizing influences. By a process of reduction there has also been
locally formed a large amount of native silver.

OUTLINE OF THIS MONOGRAPH. XXXV

The ore deposits have been laid open to the hand of man chiefly by erosion, which has
stripped off the overlying rocks and has carved deep valleys through the metalliferous deposits.
It is estimated that since the beginning of disturbance 15,000 feet of sediments have been removed
from that part of the Aspen district which lies east of the Castle Creek fault. The most recent
of the erosive processes was glaciation. There is evidence that a general ice sheet at one time
covered the whole of the Aspen district, moving over hill and valley westward from the Sawatch
This has left its trace in the rounded and fluted forms into which the hilltops are carved, and in
deposits of morainal material, generally finely ground. Subsequently this ice sheet shrank to
smaller dimensions, so that there resulted local glaciers which followed the course of preexisting
valleys and carved them into their present forms. These glaciers have left lateral and terminal
moraines. At about this period, also, there existed in the Aspen Valley temporary lakes, probably
resulting from damming-up of the glacial waters.

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GEOLOGY OF THE ASPEN MINING DISTRICT OF
COLORADO,

By J. E. SPURR.

CH ART ER 1:
ROCK FORMATIONS.

sRANITE.

Oldest of all the rocks in the Aspen region is granite. This rock,
often changing into gneisses and schists, forms a permanent floor on which
all the sedimentary rocks rest, and through which, so far as is known, all
the other igneous rocks have forced themselves to reach the position in
which they are now found.

Description—This granite presents a considerably diversified appearance
even over a limited area, but these variations are all in reality shght struc-
tural modifications of one type, for chemical and microscopic work shows
that the rock possesses a remarkable uniformity. The variations from an
originally uniform rock seem to have been brought about by slight differ-
ences in local conditions, and often by changes which have occurred since
the original consolidation of the rock; and in many cases the nature of
these changes can be discerned. Within the limited area shown on the
special maps of the Aspen district (which was as far as careful study was
carried, although frequent reconnaissances into the surrounding territory
were made for confirmation of the results here obtained), the granite is
mostly of a massive character. The most common variety is moderately
coarse, of a general light-green color when fresh, and reddish-brown when

weathered. It has a coarse granular texture, and the constituent minerals
1
MON XXxI——1

2 GEOLOGY OF ASPEN MINING DISTRICT, COLORADO.

of granite can be easily recognized megascopically—bluish quartz, yellow-
ish or pink feldspar, and mica. The mica is brown when fresh, but most
of the granite has been slightly altered, and this alteration changes the
color of the mica to a dark green, which gives the characteristic color to
the rock where it has not been actually exposed to the atmosphere. Where
such is the case the active oxidation changes the condition of the iron in
the mica and its alteration products, so that the prevailing color of the
rock changes from green to the red of iron oxide. The beginning of this
alteration is first seen megascopically in the feldspars, for, as is shown by
the microscope, the first solutions of iron derived from the mica and other
ferruginous minerals penetrate into the colorless feldspars along their
cleavages and there deposit their iron as oxide. It is in this manner that
the characteristic pink color of the feldspars is produced

Variations of the granite occur in places not far from Aspen, in the
form of considerable areas of gneisses and schists, but in the Aspen district
such rocks are not found to any extent. In some places, however, there is
a slight gneissic structure developed, and these beginnings of parallel
arrangement are interesting as having a bearing on the history of the more
completely altered rock. A common type of such gneissic rock is coarser
in grain than the ordinary variety, is of a dark-green color, and is made
conspicuous by its brick-red feldspars, which have developed a porphyritic
habit. There are irregular but in a general way parallel parting planes
running through this rock, which are often polished and striated; these
show that the parting is due to deformation of the granite at some time
later than its consolidation, and is not an original characteristic. This
conclusion is also reached by microscopic study. Another type of gneissic
granite is considerably finer grained than the ordinary rock, so that it has
almost a schistose appearance. This rock seems peculiarly liable to oxida-
tion, and is therefore often of a reddish color. It contains many small
flakes of dark mica, which have a parallel arrangement, and in many places
these mica plates, while still preserving their perfect parallelism, are concen-
trated into spherical or lenticular bunches, which do not have crystalline
boundaries. The bunches are similar to the ‘‘eyes” of the so-called
augen-eneiss, so that the rock is transitional between this rock and
granite. Whether the large porphyritic crystals of the one variety of
eneissic granite and the lenticular aggregations of mica in the other have

GRANITE. 3

a common origin, and whether they have any genetic connection with
the sheared structure which is found in both cases, is not certain; but
the absence of such porphyritic development in the massive granite is
significant.

Microscopic structure—'he essential constituent minerals of the granite, as
seen under the microscope, are quartz, feldspar (mostly microcline), biotite,
and muscovite, and it thus belongs to the rocks classed by Rosenbusch
simply as granite, or ‘‘granite proper.” No hornblende or augite was found.
As accessory constituents there are magnetite, apatite, and zircon. Most
of the minerals are usually comparatively fresh; but there is a slight kao-
linization of the feldspars and an alteration of the biotite, resulting in the
abstraction of iron, which is first concentrated along the cleavages of the
mineral and then carried out into the rest of the rock. The feldspar usually
shows microcline structure, the partial development of which can sometimes
be seen in a crystal which otherwise has the characteristics of orthoclase,
indicating that the structure has been induced by pressure, as suggested by
Rosenbusch.

The gneissic varieties of the granite have under the microscope a struc-
ture in general like that of the massive rock. In the fine-grained variety
mentioned above there are some slight but interesting metamorphic changes.
The mica in this rock is both biotite and muscovite, occurring intergrown,
and comparatively fresh. The usual accessory minerals, apatite and zircon,
are present chiefly as inclusions in the quartz, feldspar, and mica, and tour-
maline is found in small quantities. The occurrence of this mineral is
interesting, since it was not found in the massive granite, and is therefore
probably a product of metamorphism. Specular iron, red hematite, and
earthy limonite, all evidently secondary, are present, and give the red color
to the rock, although the structure is granitic, yet the effect of the strain
which has operated to produce the gneissic arrangement, and probably the
lenticular aggregates of mica, is plainly visible. The cleavage of the feld-
spar is strongly developed, sometimes resultmg in slight faulting. Within
the quartz grains the effect has been to produce fine, straight fractures, which
are intermittent instead of continuous, and the different sets characteristic-
ally form isolated crosses. These fractures are most numerous in the
center of the grain, whence they diminish in frequency toward the edges.
(See fig. 10, p. 229.)

4 GEOLOGY OF ASPEN MINING DISTRICT, COLORADO.

origin—It was formerly assumed that a part at least of the Archean
granite of the Rocky Mountain region was metamorphic in nature, having
been produced by the profound alteration and crystallization of sedimentary
beds. In the Aspen region, however, there is no evidence of any sedimen-
tary origin for the granite; its structure shows only that it has consolidated
from fusion, without hinting whether or not the materials of which it is
composed were ever exposed to atmospheric influences before the present
stage in its history.

CAMBRIAN SEDIMENTS.

Description —In the Aspen district, as elsewhere in Colorado, there rests
directly upon the granite a thin bed of conglomerate, which soon passes
upward into fine white quartzites. The very lowest layer is an arkose or
granitic grit, made up of the materials of the underlying granite, only
slightly rearranged before deposition, so that the exact line of demarcation
between granite and sedimentary rock is often difficult to distinguish within
a foot or two. This difficulty is increased by the fact that the granite is in
many places disintegrated for some little distance below the contact.
Directly above the contact, however, the material begins to be more sys-
tematically arranged, the fragments of granite disappear, and quartz assumes
the most prominent position among the minerals. This mineral occurs in
bluish translucent grains which average about the size of large shot; these
are generally inclosed in a fine paste, of kaolinie nature, derived from the
decomposition of the feldspar in the granite. The size of these grains
diminishes as the distance from the granite increases, so that the rock
becomes fine-grained, compact, and of a bluish color, being made up almost
exclusively of small rounded grains of granitic quartz, which have been
cemented together by secondary quartz since their deposition.

Microscopic structure—Under the microscope the lowest layers of these beds
are seen to be made up mostly of granitic quartz and feldspar, the quartz
being strained and fractured, as is typical in the granites, and the feldspar,
which is often quite fresh, being mostly microcline. Alteration of the feld-
spars has produced aggregations of kaolin and muscovite. Among the
smaller rounded grains which fill the interstices between the larger pebbles
quartz is most common, with kaolin and finely divided and irregularly
packed calcite which has the aspect of lime mud. There is generally some
iron in the section, which from its position is evidently secondary, and is

CAMBRIAN SEDIMENTS. 5

derived from the alteration of the ferruginous minerals of the granite; it is
either in the form of pyrite, in small crystals, or of specular iron or limo-
nite, the former either in hexagonal crystals or in shells around an oxidizing
erystal of pyrite, and the latter in irregular bunches disseminated through-
out the rock. The successive alteration of pyrite to specular iron, or red
hematite, and the hematite to yellow earthy limonite, in concentric shells,
is often well shown; there is also occasionally some iron carbonate devel-
oped as an alteration product. Besides this secondary iron there are occa-
sional grains of magnetite and red hematite, which from their shape and
position are evidently of detrital origin.

Farther up in the beds the structure is essentially the same. With
the diminution in size of the quartz grains the feldspar becomes more rare
and the feldspathic cement almost disappears. The cementing material is
then made up of secondary quartz, which has grown on to the original
grains. ‘Tourmaline is also found among the detrital grains.

Dolomitic quartzite —The upper third of this formation is not so compact and
pure as the rest. In fresh specimens this rock appears pure and homo-
geneous, but where it has been exposed to oxidation, as in all outcrops, it
assumes a different appearance. The alteration is usually most marked
along certain zones which are parallel to the bedding; along these the rock
crumbles and is eroded, while the harder unaltered parts stand out, produ-
cing a striking banding of brown and white. This tendency to oxidation
increases toward the top of the series, so that in places the whole rock is
altered.

The microscope reveals very clearly the reason for this change. In
the white, unaltered rock, there are found in the interstices between the
rounded quartz grains, besides the secondary quartz, many scattered crystals
of a carbonate, which, from its occurrence in isolated crystals of simple
rhombic form and of grayish color, as well as by the analysis of the rock,
is shown to be dolomite. This dolomite seems to have crystallized at
the same time as the secondary quartz. That it was probably derived,
however, from the alteration of original calcareous sediments is shown by
the circumstance that it is much more common in certain zones than in
others, and that these zones correspond to the bedding. In other sections
it is shown that the dissolution of these dolomite crystals is the cause of
the rapid alteration of the rock. By their removal, cavities are produced

6 GEOLOGY OF ASPEN MINING DISTRICT, COLORADO.

which are afterwards enlarged by solution of the quartz. The secondary
quartz cement appears to be more easily dissolved than the detrital grains,
so these grains become partly isolated, and the rock in some degree returns
to its original condition of sandstone. Some of the smaller grains which
are thus isolated are carried out of the rock mechanically, so that the
cavities continually widen, until the rock becomes so cellular as to be
hardly able to hold together, and finally crumbles into soil. The iron
which gives the brown color to the weathered rock does not seem to be
derived from the rock itself, but to be secondary. It is a yellow hydrated
oxide, very small in amount, which is deposited in thin coatings on the
walls of the cavities and in interstices. In places, however, especially
toward the top of the beds, there are many irregular nodules and seams of
hard hematite, which microscopic study shows to have been formed by
actual replacement of the quartzite, the quartz having been gradually dis-
solved to make way for the iron. In this process the quartz cement is first
dissolved, so that the ore contains isolated bits of quartz, which are some-
times fragments consisting of several grains, but usually single grains
which have been stripped of their cement, and the ragged and corroded
outlines of the grains themselves show that they are also undergoing
replacement, although more slowly. The source of the numerous iron
nodules in this horizon is probably the oxidation of glauconite in the beds
immediately above.

Glauconitic grit—A bove the altered dolomitic sandstones comes a thin bed
which presents in the field certain striking characteristics that readily
separate it from the beds above and below. The bed is not more than
15 or 20 feet thick, compact, and of a peculiar reddish color, mottled
with yellow on weathered surfaces. It is of fine grain, but contains many
greenish crystals of calcite, which, though small, have a porphyritic
appearance; there are also greenish fragments of detrital feldspar, so that
the rock resembles in appearance an altered eruptive rather than a sedi-
mentary. It has a granular texture, an irregular fracture, and is distinctly
heavy.

Under the microscope the rock is seen to be made up, in large
measure, of detrital grains of quartz, feldspar, and mica. The feldspar is
sometimes quite fresh, but is oftener altered to a muscovitic aggregate; the
mica is colorless. Apatite and zircon are found in perfect crystals inclosed

CAMBRIAN SEDIMENTS. 7

by the other minerals. The detrital grains are surrounded by a cement
of coarsely crystalline carbonate, probably dolomite. Associated with the
granitic minerals referred to are many rounded bodies which are quite
peculiar. These are made up in varying proportions of specular iron,
dark-brown in color and with metallic luster; red, translucent hematite;
limonite, yellow and earthy; cloudy siderite; quartz; matted actinolite;
and calcite. These are generally confusedly and finely intergrown,
although often they are in alternating zones. The cores of many of the
grains are of siderite, which is oxidized around the edges to red hematite
and limonite. Others have a core of specular iron, which appears to be
very slightly magnetic; this alters, in part, to red micaceous hematite, but
oftener to siderite. The structure of the grains suggests the alteration
of glauconite, such as has been described by the writer from the Mesabi
range in Minnesota.’ The iron is almost entirely confined to these spher-
ical areas, and there appears to be no channel by which it could have
filtered into the rock, nor any definite arrangement suggesting such an
origin. The nature of the rock in which they occur, being. that of a
sediment transitional between the zone of active deposition of eroded
land materials and of the limestone deposition of the quieter seas, accords
with this idea, for it is in such a transition zone that the peculiar conditions
necessary for the formation of glauconite are obtained.

Beds prominently glauconitic occur at this horizon throughout a large
part of the Rocky Mountains. In Colorado they were noted in many
places by Peale? at this horizon, among others on the Eagle River; and
Mr. Eldridge*® has noted them in the Crested Butte district.

Sandy dolomite —A hove this glauconitic grit there is a gradual and perfect
transition to the massive siliceous dolomite of the Silurian. The transition
beds are made up at the bottom of detrital material and of dolomite, with
the former generally in excess; a little farther up the relative amounts of
the two are about equal; and toward the top the detrital material is dis-
placed by the dolomite. The rocks have the appearance of more or less
ferruginous sandstones and shaly, siliceous limestones. In color they vary
ereatly, being sometimes gray like the dolomite above, often reddish, yel-
low, or brown. Under the microscope the detrital grains, besides quartz,

1Bull. Geol. Nat. Hist. Survey Minnesota, No. X, 1894.
2A. C. Peale, Annual Report of the Hayden Survey for 1874, p. 112.
8G. H. Eldridge, Geologic Atlas U.S., folio 9, Anthracite-Crested Butte, Colorado, p. 6.

8 GEOLOGY OF ASPEN MINING DISTRICT, COLORADO.

are found to be of feldspar, mica, and occasional tourmaline; in shape they
are generally subangular, sometimes angular, often rounded. he dolomite
is like that of the pure dolomite beds above—uniform in grain and crys-
tallized in gray interlocking rhombohedra, and often a small detrital grain
of quartz or feldspar is entirely inclosed in a single crystal of dolomite.

Thickness of beds— The thickness of the quartzite and sandy dolomite series
varies greatly in the Aspen district, being greatest in the southern part,
where it is about 350 or 400 feet, and gradually decreasing toward the
north; so that in the northern part it averages 200 feet or less.

age—No fossils were found in these beds, but they are lithologically
identical and are continuous with the well-known series which extends over
a large part of Colorado, lying around the borders of the granite area of the
Sawatch. From fossils found in various places atthis horizon these. beds
have been unanimously referred to the Upper Cambrian. It is not, however,
clearly established at just what place in the beds the top of the Cambrian
and the bottom of the Silurian should be put. Mr. Emmons’ has arbitrarily
drawn this-line at the top of the shaly beds and the commencement of the
more massive dolomite, and the same line is adopted in this report. .

Conditions of deposition—According to Mr. C. D. Walcott,” Colorado, at the
beginning of Cambrian time, formed part of a large island, which had a
north-south extension of about 1,000 miles and a width of about 300
miles. The island consisted of the Archean crystalline rocks and whatever
ancient sediments had accumulated previous to Cambrian time. At about
Middle Cambrian or the middle of Upper Cambrian time there was a subsi-
dence of the land, so that a large part of it was brought beneath the waters
of the ocean, and on this submerged area were deposited the sediments of
the Upper Cambrian which have just been described. The first material
was only slightly rearranged from the granite, which apparently was already
disintegrated from atmospheric corrosion, while that laid down later was
evidently deposited in water which grew continually deeper, as is shown
by the careful sorting, by the small size to which the quartz grains became
reduced, and by the mingling of dolomite with the detrital materials in the
upper beds. When the.dolomitic materials became nearly equal in amount
to the detrital grains, conditions were favorable to the formation of glauco-

1§. F. Emmons, Mon. U.S. Geol. Survey, Vol. XII, 1886, p. 59.
>Bull. U.S. Geol. Survey No. 81, 1891, p. 368.

SILURIAN BEDS. 9

nite; and it is mteresting to note that those conditions were the same as
those under which the mineral is formed at the present day. The continu-
ation of the subsidence of the ocean floor is indicated by the gradual dis-
appearance of the detrital material and the formation of the purer siliceous
dolomite, which belongs to the Silurian age. There is, however, no dis-
cernible break or cessation of deposition between the two periods, but all
indications are that the sediments were deposited continuously.

SILURIAN BEDS.

Description —The pure dolomites above the sandy beds are generally light
gray-blue in color, sometimes stained reddish; they weather yellow-brown,
from the oxidation of the small amount of iron which they contain, and
are hard and compact, with a fine frosty luster which is characteristic of
these, as well as of the Carboniferous dolomites. This luster results from
the structure of the rock, which is made up of small interlocking crystals
of dolomite, nearly uniform in size. There are usually blotches, nodules,
bands, and seams of chert, which is generally light gray in color. The
nodules are often very irregular in shape; when they become elongated
into seams or bands they generally conform to the bedding, although
sometimes they cut across it, at various angles. The only noticeable
difference between the bottom and the top of the formation is that at the
top the dolomite is locally finer grained than at the bottom, the crystals
often becoming so small that the frosty luster coming from their facets is
very faint.

Microscopic structure—In mineral composition this rock is like most dolo-
mites, being made up of small, interlocking, nearly uniform crystals.
Another mineral which is never absent from any thin section is quartz,
generally pretty evenly disseminated in isolated grains of small but
varying size. On casual examination they appear like detrital grains, but
when carefully observed it is found that their outlines, instead of being
rounded, or even regularly angular, are often irregular and sinuous,
presenting reentrant angles and sudden bays, such as would not occur in a
grain which had suffered any friction whatever. ‘The quartz, moreover, is
clear and free from any break or crack, such as characterizes detrital
quartz, especially in that derived from granitic rocks. The grains are
usually smaller than the dolomite crystals, and the crystallization of the

10 GEOLOGY OF ASPEN MINING DISTRICT, COLORADO.

carbonate is not in any way affected by their presence, so that often a
quartz grain is entirely inclosed in a single crystal of dolomite. In certain
areas, however, these quartz grains become more numerous and cluster
together, and irregular portions may be made up mainly of quartz, while
closely adjoining portions are chiefly of dolomite. Where the silica is thus
concentrated into an area of considerable size a chert nodule is the result.
The silica then becomes cryptocrystalline and sometimes chalcedonic, and
it incloses some carbonate in the form of rhombohedra, sometimes scattered
sparingly through the chert, sometimes becoming very numerous. Besides
the small rhombohedra, there are larger irregular areas which have the
typical structure of dolomite, consisting of numerous small interlocking
erystals; these are evidently residual, while the isolated rhombohedra,
which have a marked zonal structure attesting gradual growth by succes-
sive additions, are evidently concentrations of similar smaller residual areas.

When the rock is strained so that oxidizing agents have obtained
entrance along cracks, there is often formed uniformly throughout the rock
a small amount of iron oxide, which occurs along the cracks themselves,
between the crystals of dolomite, and along the cleavage, especially where
this is strongly developed by the strain. he oxide seems from its arrange-
ment to be derived from material already in the rock, rather than that
brought in along the crevices; and analyses of the fresh rock usually dis-
close a small but constant percentage of iron. This iron is probably in the
form of carbonate, and is crystallized with the dolomite. | .

Thickness of beds— This dolomite varies in thickness in the same way as do
the Cambrian beds below it, thickening gradually toward the south and
thinning toward the north of the area mapped; the maximum thickness at
the southern margin of the Tourtelotte Park special area being about 400
feet, while at Lenado the average is probably 250 feet.

age—The age of these beds is fixed as Silurian by fossils which have
been found in the same formation in various parts of Colorado, but no
further subdivision can well be made. This horizon was assigned by
Peale! to the Caleiferous epoch, at the base of the Silurian series, while
Mr. Emmons’ reported not only fossils of the Calciferous epoch but also
some which resembled forms of the Niagara and the Trenton. What

1A. C. Peale, Ann. Rept. Hayden Survey for 1874, p. 112.
2Mon. U.S. Geol. Survey, Vol. XII, 1886, p. 61.

SILURIAN BEDS. IL

evidence there is, therefore, goes to show that the dolomite is of Lower
Silurian age. .

Origin of the dolomite—It is practically agreed upon by geologists that
dolomite as a rock is nearly always formed by the alteration of calca-
reous sediments subsequent to their deposition.' The structure of the
Silurian dolomite at Aspen, as seen under the microscope, is not that of
a sedimentary deposit, since it is made up of interlocking crystals and
of quartz which has evidently formed in place without any important
amount of detrital material. This structure is sufficient evidence that it
has crystallized through the influence of solutions; and the question pre-
sents itself as to whether this rock was deposited as such from oceanic
waters, or whether it is the result of the alteration and recrystallization
of an original simple sedimentary deposit. The theory of a chemical pre-
cipitation of carbonate of magnesia requires the assumption of a shallow
evaporating salt lake or inland sea, in which carbonates of lime and
magnesia derived from solution of rocks were concentrated and finally
thrown down.

Bischof,” however, has shown that owing to the difference in solubility
between the carbonates of lime and of magnesia the lime carbonate will
be nearly all deposited from a saturated solution containing both these
salts before the precipitation of the magnesia carbonate begins; conse-
quently there would result trom a deposit formed in this way a lower
layer of nearly pure carbonate of lime and an upper layer of nearly
pure carbonate: of magnesia. There might be some mingling of the
carbonates in the zone between the two layers, but no important amount
of dolomite could be formed in this way. There are no cases known
where such a process of formation of dolomite is now going on.

On the other hand, there have been many cases described where dolo-
mite has been produced along narrow zones which often cut across the
bedding of the limestone. Such alteration has been described by Hark-
ness*® in the south of Ireland, where narrow bands of dolomite have been
produced along joints, and the conclusion is inevitable that here the dolomite
has been produced by the metamorphosing action of waters which have
penetrated the limestone along these joints at some period subsequent to the

' Dana, Manual of Geology, fourth edition, p. 133.
* Chemical and Physical Geology, Vol. III, p. 170.
*Robert Harkness, Quart. Jour. Geol. Soc. London, Vol. XV, p. 100.

12 GEOLOGY OF ASPEN MINING DISTRICT, COLORADO.

deposition and the jointing. The same phenomenon is observed in the
Carboniferous blue limestone at Aspen, where the limestone is altered along
joints and fault-planes to brown crumbling dolomite, locally known, from
its finely jointed structure, as “short lime.” ‘The microscopic structure of
the dolomite, which evidently arises from the alteration of limestone, is
essentially like that of the dolomite of the more massive and extensive beds,
as Sorby | has noted in the dolomites of Europe, and as the writer has found
by a thorough study of the Aspen rocks. The structure of the Silurian
dolomite, therefore, is one which may arise from the alteration of a calcareous
sediment. The persistence and uniformity of this dolomite, which retains
practically the same composition for hundreds of miles, show, however, that
the cause of its alteration could not have been local, as in the case of the
narrow zones which follow joints and dikes, and which were the result of
transient circulating waters. The alteration of the Silurian dolomite from
an assumed original caleareous sediment demands the action of waters
throughout its whole extent for a considerable period of time. Such a con-
dition would be afforded by the presence of a great lake or inland sea, in
which thé usual amount of magnesia in sea water would be concentrated
by the evaporation of the water. This is actually the condition which is
considered by most geologists to have brought about the formation of
nearly all, if not all, of the persistent and widespread dolomites. Dana’
mentions an interesting case of actually observed dolomization at the coral
island of Metia, north of Tahiti. The rock of this island is a compact
white coral limestone, which has nearly the composition of true dolomite,
showing on analysis 61.39 per cent of calcium carbonate and 38.07 of
magnesium carbonate. The general character of this rock leads to the
inference that it was deposited from the waters of the shallow lagoon of
the coral island in the form of fine coral mud, that the waters of the
lagoon became concentrated by evaporation so as to contain a much
greater proportional amount of the magnesium salts than is normal in sea-
water, and that these solutions brought about the dolomization of the coral
mud. The magnesium salts of the ocean consist chiefly of chloride, and
this is quite capable of accomplishing the change in question.

It is probable, therefore, that the Silurian dolomite of the Aspen
district was originally deposited slowly in quiet seas, and was built up

1 British Assoc. Report, 1856, p. 77. 2Corals and Coral Islands, p. 393.

PARTING QUARTZITE SERIES. 13

from calcareous sediments; that these beds were subsequently altered to
dolomite by the magnesium salts of a great evaporating shallow inland
sea; and that this alteration was accompanied by the production of the
crystalline structure now characteristic of the rock.

PARTING QUARTZITE SERIES.

Above the Silurian dolomite comes a series of thin beds which from
their persistence and peculiar characteristics are extremely valuable in
determining stratigraphical questions, for they form a marked and unmis-
takable dividing zone between the dolomites of the Silurian and the upper
dolomites, which are almost identical in structure and appearance with
those of the Silurian, but which are of Carboniferous age.

Deseription—QOn the top of Hast Aspen Mountain, overlooking the town
of Aspen, a section of the Parting Quartzite, which was here exposed on
the face of a cliff for its full thickness, was carefully observed and meas-
ured. The section is as follows from below upward:

Section of Parting Quartzite exposed on Hast Aspen Mountain.

1. Hard, dark-blue Silurian dolomite, passing upward into very thin bedded or shaly

lisht-eray dolomitess--— =) 2222226222. eee eee a) yee See ee et ee en GRIN GOES:
2. Greenish-gray sandstone, made up of quartz grains of varying size in a dolomitic

MA YHEE e 5 enna gob oaaoe Ses aesos BE Sao ane Seae te esetae Sa ee ence rot as Hes a aemeesee 2 feet.
3. Hard, dark-blue dolomite, like that first mentioned_-_-_-__--....._--..-.-.-------------- 2 feet
4, Hard, white quartzite, weathering reddish _____.__---_-____-___-_. Be eee eee eee 1 foot.
OMe Olommibicysamad stone wlio yN|O sic) sa eres ee eee eg ee me ae en a ae 1 foot.
6. Thin-bedded, gray dolomite shales, like No. 1- I Sone ears en Bf esa eee pt OmMLeO Ls

Above this, in ascending order, one passing pamennat maedineiliy oO ihe ion come—
. Fine-grained limestone or dolomite, very much like No. 2 and No. 5, with many quartz
erains, andioccasional thin)seams of Shales=== 2255.2 5.2 sass 52s oe =n ns eee neo eee 3 feet.
8. Thin-bedded lime or dolomite shales, light green when fagalh. sraniinaniys yellowish-
brown, and, when looked at from a little distance, having a general maroon color.
This color is due to a rich dark-brown staining, which is nearly solid at the bottom
of the bed; near the top, however, it is in bunches, and is made up of curiously

~

CUHUPVAINES, THANE, COMES MTG THOS = 5 oes sessonsas Lal Hetenages Geedsdesesseeulssee 4 feet.
9. Fine-grained, light-brown dolomite, with smooth, conchoidal fracture; contains many
quartz grains, and is a transitional type between No. 8 and No. 10_._______. About 14 feet,

10. Hard and compact dolomite, light gray in color; from its uniform aphanitic struc-
ture and regular conchoidal fracture, as well as from its delicate coloring, this
rock is one of the most characteristic of the series. It has been called in the field
‘lithographic stone,” from its having a very close resemblance to the peculiar
limestone which is used commercially for lithographic purposes____ __.____._..__. 8 feet.
Light-colored, fine-grained dolomites, resembling those of No. 10, but becoming thin-
beddedvandishalyit 3 522 ani cseet eect Se ee ecu see ase e sec ices Senos ceeean Mlesteebs

11

14 GEOLOGY OF ASPEN MINING DISTRICT, COLORADO.

12° Dolomite; essentially like No; W0ys2 fase Ss. e e S eee ee ae ese ee 8 feet.
13. Like No. 12 in structure, but blue or brown in color, and containing occasional sand

PTAINS 2-2. e-\sud Sonh sates SP cas tee Serie eee a oS EEN. tesa tee erie 12 feet.
14. Hard, white quartzite, weathering yellow-brown________-___.___. _--..__-.-_-__-- 2 to 4 feet.

15. Sandy, brown, crystalline dolomite, fine grained, with frosty luster, passing upward
into the dark-blue dolomite of the Carboniferous ._-___--.---...-------------.------ 10 feet.

On the south-facing cliff of Castle Butte, which overlooks Queens ©
Gulch, the beds of the Parting Quartzite series are also exposed in their
full thickness. Here the examination made was not so detailed, but in a
general way the series consists of a basal impure quartzite, a shaly bed
stained a deep-maroon color, a heavy, light-green lithographic dolomite,
and at the top of the series a heavy quartzite. The thickness of the section
in both places is nearly the same, namely, about 60 feet.

The quartzites at the top and the bottom of the series, the gray, light-
green, or light-brown massive lithographic dolomite, and the dark-brown
shaly beds are the characteristic features of this horizon in the Aspen
district, and are nearly always present, although the minor stratigraphy
varies considerably, so that the detailed section of the beds on East Aspen
Mountain is probably only local and might not hold good for any other
part of the district. On account of the prevailing colors of the chief
members of this series, they are known in Aspen as the gray, the green,
the maroon, and the white beds, the gray and the white being chiefly the
quartzites, the green the lithographic dolomites, and the maroon the high-
colored dolomitic shales. The series may be summed up as broadly
characterized by an impure feldspathic quartzite at the base and a heavier
and purer quartzite at the top, with an intermediate series of massive litho-
graphic dolomites and shaly dolomites. The shaly dolomites are richly
colored, chiefly brown and green; the colors are sometimes solid, oftener
banded, mottled, or arranged in rings.

Microscopic structure of the basal quartzite —In appearance the basal ‘quartzite is
quite ordinary, being light gray, light green, or pure white in color. In
texture it is sometimes uniform, but oftener incloses grains of different. sizes,
varying from the minutest dimensions up to an eighth of an inch in diame-
ter. It is also remarkable for carrying bands or blotches of the gray
lithographic’ dolomite into which it passes above. Under the microscope
there are found, besides the quartz, detrital grains of feldspar, chiefly
microline, and subangular or rounded fragments which are made up of
interlocking crystals of carbonate and are evidently detrital fragments of

PARTING QUARTZITE SERIBS. 15

limestone or dolomite. There is also occasional tourmaline. The detrital
grains are inclosed in a cement which is made up partly of finely granu-
lated carbonate, apparently limestone or dolomite detritus, but mainly of
a white opaque substance, which is probably kaolin. In places this matrix
predominates in quantity over the included grains,

In the typical case which has just been described there is no cementa-
tion of the original grains by secondary silica, and therefore the rock is
not a true quartzite, but a feldspathic and dolomitic sandstone. This sand-
stone passes on the one hand into the sandy lithographic dolomite and on
the other into a more siliceous variety which has a true quartzitic structure.
This latter rock has a cement of secondary silica; further evidence of alter-
ation from an original sandstone is the carbonate, which is concentrated
into irregular crystalline patches.

The third variety of the basal quartzite member—the sandy litho-
graphic dolomite—is developed very gradually from the dolomitic sand-
stone by an increase in amount of the dolomitic material and a decrease
in the size and number of the detrital quartz grains. In sections of this
rock the angular, subangular, or rounded grains of quartz are scattered
in a mass of very finely crystalline dolomite, which is homogeneous and
probably represents a lime mud. There are also many areas of crypto-
crystalline dolomite; these have sometimes a rounded, sometimes an
angular or irregular outline. This cryptocrystalline dolomite is the gray
“lithographic limestone” of the field; in the hand specimen it appears as’
small irregular patches, which sometimes unite to form nodules or bands.

The lithographic dolomite member— Where found in fresh condition, as in mine
workings where oxidizing agents have not been very active, the prevailing
color of the lithographic dolomite is a light, delicate gray, with a tinge of
green. On oxidation, however, it turns chocolate-brown, and outcrops
invariably have a brownish tinge. Owing to the fineness and uniformity
of grain and the compactness of structure, weathering causes it to shell
off on exposed surfaces, so that it presents in the outcrop rounded knobs
of comparatively fresh rock, smooth to the touch. Microscopically the
structure is that which has just been indicated. The main mass of the
rock is of carbonate, cryptocrystalline or very finely phenocrystalline;
through this are often disseminated small detrital quartz grains. In speci-
mens which have undergone some slight alteration, apparently from under-

16 GEOLOGY OF ASPEN MINING DISTRICT, COLORADO.

ground waters, there is a secondary growth upon these grains, so that they
often become perfect crystals. Crystals of pyrite are also often found.
Such specimens are usually traversed by a system of fractures, indicating
the nature of the altering agents, and these fractures are filled with fresh
crystalline calcite. The coloring of the rock on oxidation is due to the
formation of very small but uniformly disseminated amounts of iron oxide.
In those rocks which contain pyrite some of this oxide is seen to come
from the alteration of the sulphide; but as the change takes place also in
rocks which have no trace of pyrite, it is probable that there exists a small
amount of iron in the fresh reck, in the form of carbonate. Analyses of
the rock show it to be strongly magnesian, although the amount of magne-
sium is not always quite equal to that in normal dolomite.

The maroon member—Structurally this is simply a variety of the sandy
lithographic dolomite, which is thin bedded and sometimes shaly, and so
has been especially easy of access to altermg agents, which have given it
its brilliant coloring. The more compact dolomite in the vicinity of these
shaly beds often partakes of their peculiarities of tint, showing that the
color does not arise from any original difference.

Three different processes of coloring have been noted—one of reduc-
tion, one of oxidation, and one of leaching by surface waters. The process
of oxidation gives the dark-red or maroon color; that of reduction a dark-
gray, dark-green, or nearly black color; that of leaching a light-yellow
to nearly white color. The coloring matter is probably chiefly iron,
although the brilliancy suggests the presence of some of the other metals.
The various stages of the oxidizing process are well seen in the specimens
taken from mines. The fresh rock is a vivid light green for the most part;
and while this may not have been the original color, it is the earliest
stage which has been observed. This becomes red in places, there being a
variety of transitional tints, which are often symmetrically concentrated into
concentric rings; in others there is a very sharp line between the red and the
green portions of the rock, and as these portions are irregular in shape and
intimately mingled, there results a pronounced mottling. The oxidation is
accompanied by a shrinking of volume, so that while the green rock may be
hard and compact, the red is closely jointed and brittle. When the rock is
mostly altered to the red it still contains small rounded or lenticular resid-
ual areas of the green, often no larger than peas or shot. (See fig. 1.)

PARTING QUARTZITE SERIES. 17

The alteration of the maroon color to banded light and dark green,
by a process of evident reduction, was observed in a specimen kindly
given by Mr. D. W. Brunton, of Aspen. This specimen was from the
Free Silver shaft, about 700 feet below the surface. The color of the rock
is the typical dark red of the oxidized Parting Quartzite series. In the
vicinity of a set of fine, almost microscopic fractures, which, however, have
been brought into promimence by the concentration of the reduced iron
along them, the rock is altered to a light-green color, with bands of darker

Fig. 1.—Oxidized fine-grained dolomite, with residual areas.

green following each of the individual fractures. The width of the largest
band thus altered is about an inch and a half, while smaller bands of
varying width ramity from the main one (see fig. 2). Within these altered
zones there are discernible numerous small grains of pyrite, while in the red
surrounding rock none can be found. The conclusion is that the altera-
tion has been produced by the reduction of the iron oxide in the rock to
sulphide, and that this change has been effected by the percolation of

waters along the fracture crevices. In the locality where this specimen
MON XXXI——2 ;

18 GEOLOGY OF ASPEN MINING DISTRICT, COLORADO.

was found there are waters which carry at the present time sulphu-
reted instead of carbonated waters, as the occurrence of strong sulphur
springs in the Molly Gibson mine shows; other watercourses close by
carry carbonated surface waters. In this case a rock which had been
exposed to surface waters and had become considerably oxidized was by
some slight change of currents made the channel of sulphureted waters,
with the change which has been described.

The bleaching under immediate surface influences is best observed
in actual outcrops, where it is most actively going on. It is especially
well shown on a road on the mountain side to the south of Lenado.
The weathered surfaces are altered to a light greenish yellow; and this

Fic. 2.—Zones of reduction in oxidized fine-grained dolomite.

alteration is also well marked along the joint planes, the alteration having
taken place for an inch or so on both sides of the crack. The process
is one which has been observed in the Maroon formation, also in the
Triassic and in the other red-colored beds of the region; the microscope
shows that it is essentially a withdrawal of the iron from the bleached
rock. Carbonated surface waters, which take the iron into solution, are
the probable agents.

Conditions of depositionThe character of the basal bed of the Parting
Quartzite series indicates deposition in water much shallower than that
in which the dolomite sediments below were laid down, and in a position
nearer the shore. Most of the coarse materials—quartz, feldspar, occasional
mica, and tourmaline—are evidently the product of the erosion of granite,

PARTING QUARTZITE SERIES. 19

while the dolomitic mud in which these fragments are embedded is prob-
ably detrital, and hence must have been derived from the subaerial erosion
of some portion of the beds already formed. These things show that at
the end of the deposition of the calcareous sediments of the Silurian a
widespread but uniform elevation took place, so that those portions of the
sea bottom which were nearest shore emerged from the waters and became
dry land; after which the arenaceous sediments were deposited in the
waters of a shallow sea. Inquiry into the origin of the smooth, delicately
tinted lithographic dolomite which forms the distinguishing feature at this
horizon gives further light as to the character of the sea. This rock is
associated with the quartzite in the most intimate manner, alternating with
it in successive small bands, thus showing that the two were deposited
under very nearly the same conditions. Further, the cryptocrystalline
dolomite often occurs in the quartzite in the form of nodules or masses of
irregular shape, which are inclosed, like the quartz grains, in a cement of
detrital dolomite of entirely different character. These nodules of litho-
graphic dolomite inclose grains of detrital quartz similar to those in the
rest of the rock, showing that either the d lomite was formed later than
the deposition of the quartz or it was in a soft and plastic condition at—
the time of sedimentation. The occurrence, often only a few inches away,
of narrow and continuous bands of the lithographic dolomite containing
very little quartz, which alternate with the typical dolomitic sandstone or
quartzite, proves that the two varieties of rock were contemporaneous in
formation, and so the second alternative must be accepted. The occasional
occurrence of this rock in irregular blotches and lenticular interbedded
nodules, which resemble in form and habit flint nodules (see fig. 3), is
another significant feature; and these things point to the origin of the
rock as a direct chemical precipitate from the waters of the sea. Such a
precipitation of calcite is now going on in many places, such as the Ever-
glades of Florida, where shallow land-locked waters are exposed to evapo-
ration. During such evaporation the carbonate of lime brought into the
lagoons by the streams which enter them is gradually thrown down and
accumulates on the bottom. It is probable that the lithographic dolomite
was thrown down as such a calcareous precipitate, and that its dolomiza-
tion was accomplished later on, under the same conditions as have been
described for the underlying massive blue dolomite, and very likely at

20 GEOLOGY OF ASPEN MINING DISTRICT, COLORADO.

the same time. From what little chemical examination has been made, it
seems that the dolomization has not been so complete in the aphanitic
dolomite as in the crystalline variety, a fact which may be earls by
the closeness of texture of the former.

While the evidence shows that in many parts of this region there
must have been an erosion interval between the deposition of the lower
dolomite and that of the Parting Quartzite series, it is not clear whether
such was actually the case in the Aspen district, although such an interval
is suspected. .

' correlation—At Leadville there occurs at this same horizon a bed of
quartzite separating the dolomite of the Silurian from that of the Carbon-
iferous. Mr. Emmons! states that its thickness averages 40 feet, with a
maximum of 70 feet, and gives
it the name ‘Parting Quartz-
ite.” Since this quartzite,
although differing somewhat
lithologically from the inter-
calated quartzites and litho-
graphic dolomites which are
found at Aspen, is yet evi-
dently their stratigraphical
equivalent, occurring at the
same horizon, being of the
same thickness, and bearing
aillewee of dopositien under closely similar conditions, the term ‘‘ Parting
Quartzite series” has been adopted for the formation at Aspen. Mr.
Eldridge? has described what is also evidently the equivalent of these beds
in the Crested Butte area, thus:

Fic. 3.—Nodule of lithographic dolomite in dolomitic sandstone.

The upper division, 60 to 90 feet thick, consists mainly of green, yellow, red,
and white shales, with more or less arenaceous and calcareous layers, the latter
passing into thin limestones. The persistence of its general lithologic character
renders this horizon easily recognizable.

Age of Parting Quartzite beds—In the absence of fossils this series has been
generally included in the Silurian beds, and the Devonian has been sup-

1 Geology of Leadville: Mon. U. 8. Geol. Survey. Vol. XIT, 1886, p. 61.
2Geologic Atlas U. S., Anthracite-Crested Butte, folio 9, 1894, p. 6.

PARTING QUARTZITE SERIES. |

posed to be lacking. The Devonian beds of the Kanab Valley, however,
as described by Mr. C. D. Walcott,’ correspond closely with the Parting
Quartzite series in nearly every detail, and afford very strong grounds
for correlation. The Kanab Valley lies in southern Utah and northern
Arizona, about 300 miles southwest of the Aspen district. Mr. Walcott
describes the Devonian here as follows:

The Devonian beds are very variable in character,.and of little vertical
range. At their greatest development, when increased by being deposited in a
hollow of the limestone beneath, there is but 100 feet of purple and cream-colored
limestone and sandstone, passing into gray calciferous sandstone above. Over the
knolls of Silurian limestone the upper beds alone extend with a thickness of from
10 to 30 feet. The purple sandstones deposited in the hollows of the Silurian lime-
stone are characterized by the presence of placoganoid fishes of a Devonian type.
The Silurian limestone was extensively eroded antecedent to the deposition of the
superjacent Devonian beds.

With very slight modifications this might be taken as a description of
the Parting Quartzite series at Aspen. The ‘purple and cream-colored
limestone and sandstone, passing into gray calciferous sandstone above”
describes the deep-colored sandstones and shaly dolomites of Aspen, which
pass upward into the heavier upper sandstone and quartzite. The evidence
of the erosion interval between these beds and the underlying dolomites is
also important in the correlation. At one locality in Aspen, on the side of
East Aspen Mountain, overlooking the town, scales and teeth of fishes
were found in the shaly beds directly overlying the dolomites. These fossils.
were examined by Dr. George H. Girty, who made the following report:

The vertebrate fossils are fish remains, and evidently come from a bone bed.
They consist of dissociated and fragmentary plates and bones, together with one
tooth and a cast of another. As far as I have been able to ascertain, the latter
belong to the sauroid fishes, and probably may be referred to the genus Rhizodus,
Owen, or perhaps to the allied genus, EKusthenopteron. Rhizodus itself, in this
country, occurs in the Carboniferous, both Upper and Lower, while Eusthenopteron
is found in the Upper Devonian.

In the Kanab Valley section the sandstones and impure limestones of
the Devonian are underlain by 185 feet of massive mottled limestone, with
50 feet of sandstone at the base, constituting the Silurian series, and are
overlain by 735 feet of massive Carboniferous limestone, with arenaceous
and cherty limestone above, passing upward into friable red Carboniferous

‘Am. Jour. Sci., Sept., 1880, 3d series, Vol. XX, p. 224.

22 GEOLOGY OF ASPEN MINING DISTRICT, COLORADO.

sandstones. Thus the entire sequence of deposition is seen to have been
remarkably like that at Aspen. Mr. Walcott observed evidence of a slight
unconformity by erosion between the Devonian beds and the overlying
limestones. Evidence of such erosion interval was not obtained at Aspen,
but it has been observed by Mr. Emmons?* between the Parting Quartzite
and the overlying Carboniferous limestones on the East Fork of the
Arkansas.

These grounds, therefore, are thought sufficient for placing the age of
the Parting Quartzite series as probable Devonian.’

CARBONIFEROUS FORMATIONS.
LEADVILLE LIMESTONE.

Above the Parting Quartzite series there comes a heavy dolomite sim-
ilar to the Silurian, which is in turn overlain by a massive blue limestone
of quite different structure. This blue limestone is distinctly separated from
the argillaceous and carbonaceous limestones and shales above, which
belong to the Weber formation. The dolomite and the blue limestone are
classified together as the Leadville limestone, the name being taken from
the corresponding dolomitic beds at Leadville. Locally the dolomite and
the limestone are known by the names of ‘‘blue and brown lime,” from the
circumstance that the dolomite contains a small quantity of iron, which,
when oxidized, as in most of the rock near the surface, gives a general
brown tinge, while the pure limestone retains its blue color. The thickness
of the Leadville formation is comparatively uniform throughout the district,
so far as observed, having an average of about 350 feet, of which from 200
to 250 feet are dolomite, and 100 to 150 feet are of blue limestone.

THE DOLOMITE.

origin. —It has been a hotly contested question in Aspen, and one which
has had an important economic bearing, whether the Carboniterous dolomite
was originally deposited as such or became dolomized by subsequent action.
Without going into details, it will simply be stated here that there is abun-
dant evidence of two periods of dolomization, one oe which oceunred before

\Geology of inemyatvailts: Mon. U.S. Geol. Survey, Vol. XX, p. 61.

»Since the above was written, additional fossils have been collected from the bed which has
been mentioned above, by Mr. Tower, in the summer of 1896. These fossils were submitted to
Mr. Charles D. Walcott, who pronounces them to be scattered and broken plates of placoganoid
fishes and to be undoubtedly of Devonian age.

CARBONIFEROUS FORMATIONS. 23

the deposition of the blue limestone, while the other was much later, and
was closely connected with the ore deposition. There are numberless proots
of the latter process all through the Aspen district, especially in the more
highly mineralized localities, where the blue limestone has been altered into
dolomite in zones following faults or fractures which cut across the bedding
of the limestone, or in zones following the bedding planes. It is also proved,
however, that the great body of dolomite which forms the lower part of the
Leadville formation was formed previous to the fractures along which the
waters which effected the later dolomization ascended; for the contact of
the dolomite and the limestone is faulted and broken by these fractures,
exactly as the other sedimentary formations are.

Throughout the district the dolomite and the limestone maintain about
the same relations and have about the same thickness and the same well-
marked plane of separation, although in places this uniformity is obscured
by faults, as is the case on the whole southern part of the district, from the
Roaring Fork to Lenado, over which area the blue limestone is cut off by a
fault which runs nearly parallel to the bedding. In Tourtelotte Park, near
Castle Butte, is a locality where it was at first supposed that the dolomite
was missing and that the blue limestone rested directly upon the Parting
Quartzite series; but subsequently this appearance was found to be due to a
fault. At Leadville the corresponding formation is entirely of dolomite,
but has a thickness of only about 200 feet. In the Crested Butte district
Mr. Eldridge gives a thickness of 400 to 525 feet, of which the upper 75
to 150 feet is a massive bluish limestone, while the rest is grayer and
dolomitic. The lateral extent of this dolomite bed is therefore very great,
and the stratigraphical distinction of the dolomite from the overlying
limestone is persistent, at least throughout the Aspen, Crested Butte, and
Anthracite districts. Such widespread lithological peculiarities can not be
ascribed to any local metamorphism, but to some uniform widespread cause
which acted before the deposition of the blue limestone, since this horizon
shows none of its effects. The microscopic peculiarities of the Carbon-
iferous dolomite are identical with those of the Silurian, and for the same
reasons which have been enumerated in considering the origin of the
Silurian it is probable that the lower 250 or 200 feet of the Leadville
formation was deposited originally as a calcareous sediment, and that these
sediments became dolomized subsequently, but before the deposition of the

94° +GEOLOGY OF ASPEN MINING DISTRICT, COLORADO.

blue limestone, through the action of magnesian salts, which were held in
solution in the waters of a probably evaporating and shallowing sea that
covered the whole district.

Description. —W here the Carboniferous dolomite has not suffered oxidation
it is hard and gray blue in color, compact, and with a rough, conchoidal
fracture. Such fresh rock, however, is found in large quantities only m
the lower levels of some of the mines, such as the Free Silver and the
Smuggler, in which, 700 or 800 feet below the surface, a depth is reached
where the effects of oxidation have been little felt. In these mines the
changes which one observes in the dolomite, going upward toward the sur-
face, explain the whole process of alteration. The‘rock becomes yellowed
by the formation of a small amount of iron oxide, which microscopic study
shows to be probably derived from the oxidation of iron carbonate that
is crystallized with the dolomite. The alteration of the carbonate to the
oxide is accompanied by a decrease of bulk, and some dolomite is also
probably carried away in solution by percolating carbonated waters; these
withdrawals bring about concentration, which results in the formation of
numerous joints. These joints become so close that when the rock is
struck forcibly it often crumbles into many small, angular fragments.
From its color the oxidized dolomite is called by the miners “ brown
lime,” ' while from its close jointing it is called “short lime.” ‘These pecul-
iarities are characteristic of the rock to a greater or less extent all over the
surface and within the zone of active surface alteration.

Microscopic structure—The structure of the Carboniferous dolomite is iden-
tical with that of the Silurian The rock is made up of small, gray
erystals of dolomite, interlocking, and with a constant tendency to rhom-
bohedral form. These erystals are usually uniform im size, but sometimes
they vary slightly in different areas, which change gradually one into the
other. On oxidation they develop iron oxide along their edges and in
cleavage cracks, showing that they contain a small percentage of iron
carbonate. Quartz is always present in the same peculiar grains which
have been noted in the Silurian dolomite, and which are easily taken for
detrital grains, but which on close examination show by their fresh,
unbroken structure and irregular outlines, as well as by the circumstance

limestone or to the blue lime, which has been greatly altered to a brown lime that is not dolomitic,
but is a porous lime carbonate containing much iron. In this paper ‘‘ brown lime, ” «‘ short lime,”
and ‘‘ dolomite” are synonymous.

CARBONIFEROUS FORMATIONS. 25

that they are inclosed in crystals of dolomite, that they have formed subse-
quent to the deposition of the rock. These grains are often clustered in
certain areas, displacing the dolomite and forming chert nodules and bands.

chert—The chert is generally dark gray in color, sometimes light gray.
It is in seams, nodules, or bands, which usually follow the bedding, but
occasionally, as on West Aspen Mountain, the seams follow a set of
fractures which cut across the bedding, and so give a deceptive appearance
of stratification.

Composition of Leadville dolomite —Many analyses of the dolomite have been
made by the mine managers of Aspen, who consider the determination of this
rock an important aid in prospecting for ore; and these analyses have been
supplied to the Survey by the courtesy of these gentlemen. The following
eighteen show the respective proportion of oxide of magnesium and oxide
of calcium in as many different samples. These were selected at random
from the list, but care was taken to include only those which were from
the dolomite stratigraphically below the blue limestone, and to exclude
dolomite which is a local alteration of the limestone. This latter dolomite
shows transitional stages from the limestone which are indicative of its
origin, while the composition of the dolomite which everywhere underlies
the blue limestone is nearly uniform. J ollowing is the table:

Oxides of calevwm and magnesiwm in Leadville dolomite.

CaO MgO
33.4 23.2
30. 46 20.9
Bieey 16.57
32.5 17.72
34.9 15. 62
31.7 15.83 |
31.6 17.80
31.3 19. 20
7 13.29
34.2 12.97
30.2 20.80 |
31 20.60 |
30.4 19.46 |
32.2 17.90
30.9 20.40 |
31.3 17. 83
35.2 16.21
30.9 20. 4
Average_32.3 18.15 |

26 GEOLOGY OF ASPEN MINING DISTRICT, COLORADO.

The average of all these analyses gives 32.3 per cent of calcium oxide
and 18.15 per cent of magnesium oxide. Since they are taken from many
parts of the district, their average may be accepted as the composition of
the dolomite constituting the lower part of the Leadville formation.

Normal dolomite, according to Dana, contains 45.65 per cent of
magnesium carbonate, and 54.35 per cent of calcium carbonate. ‘This is
equivalent to 21.74 per cent of magnesium oxide, and 30.43 per cent of
calcium oxide. The Leadville dolomite of Aspen, therefore, contains some-
what more lime and less magnesium than typical dolomite. There is also
nearly always present a small amount of silica and of iron. Not so many
determinations of these ingredients were available, but from the average of
several analyses of each it is found that the silica constitutes probably

Fiqa. 4.—Sandstone veins in dolomite.

2 or 3 per cent and the iron oxide about the same. The iron oxide deter-
mined by the analysis, it will be remembered, is really in the form of
carbonate in the unaltered rock. There is also often present a small
amount of alumina.

Sandstone veins in dolomite —Mr. Tower observed on Aspen Mountain irreeu-
lar sandstone veins of small size in the dolomite. ‘These veins were often
conformable to the bedding, but were also found cutting vertically across
the bedding and connecting with the horizontal veins, so that it was evident
that they were of later origin than the inclosing rock. The finding of angu-
lar fragments of the dolomite among the material of the vein confirmed
this conclusion.

The largest of the veins observed was only a few inches wide, and from
that they grade downward in size, sometimes filling crevices which measure

CARBONIFEROUS FORMATIONS. 27

only about a tenth of an inch, where a single quartz grain fills up the width
of the vein. (See fig. 4.) These veins become most prominent on the
weathering of the rock, as the sand grains resist corrosion more than does
the dolomite. Under the microscope the large grains in the filling are seen
to be mostly quartz. These quartz fragments are of varying size, rounded
or subangular in shape, and without any assortment or symmetrical arrange-
ment. There are also many grains of feldspar, which is sometimes fairly
fresh, and sometimes is altered to a muscoyitic aggregate. Angular frae-
ments of dolomite identical with the wall rock are common, and vary in
diameter up to an inch. These materials are inclosed in a cement of closely
packed, minute, irregular grains of carbonate, which from its behavior with
acids is probably dolomite. This dolomite, however, has not the structure of
the crystalline dolomite of the wall rock, but is plainly fragmental in nature.

The sandstone vems are not widespread, and were observed only in a
few localities, and there are not sufficient facts to prove their origin. It is
certain, however, that they fill fissures which were formed after the dolomite
was consolidated into its present condition; and since this filling has become
indurated into a hard and compact sandstone, its formation was probably
not extremely recent. The well-rounded quartz grains show that they had
been considerably worn by aqueous action previous to being laid down, and
also that water was the vehicle through which they were introduced into
their present positions. There is, however, no positive trace of stratification
among the materials, nor any sorting such as is often observed in water-laid
sediments, but grains of all sizes are confusedly intermingled and lie in
every position, with no observable parallel arrangement of their longer
axes. It seems, then, that the deposition was not slow, but immediately
succeeded the formation of the fissures, and that the materials were all
introduced at the same time.

Mr. Diller' has described cases of sandstone dikes in California, which
are developed on a remarkable scale in shale beds. These dikes present
peculiar features which indicate that they are not sediments, but that the
material was forced upward, mixed with water, from a lower horizon, and so
filled joint fissures, and that the formation of these fissures and the injection
of the sand were phases of earthquake action. Cases where such injections
have actually been known to occur, as in the earthquake at Charleston,

‘

1Bull. Geol. Soc. Am., Vol. I, p. 411.

28 GEOLOGY OF ASPEN MINING DISTRICT, COLORADO.

are cited by Mr. Diller. Other occurrences of sandstone veins or dikes
have been described by various writers, many of them referring their origin
to sedimentation from aboye, in open fissures. Mr. Cross’! has described
some interesting sandstone dikes in granite in the vicinity of Pikes Peak,
but does not offer any suggestion as to their origm. The sandstone veins
at Aspen resemble some of the grits of the Maroon series, which lie several
hundred feet above the Leadville dolomite, and are separated from it by the
Weber shales and limestones, as well as the blue Leadville limestone; on
the other hand, there underlie this dolomite the various sandstones, quartz-
ites, and dolomites which have been described. While, therefore, there is
not sufficient evidence for any definite proof, the conditions are equally
favorable for the application of Mr. Diller’s theory and for the theory that
they were filled by waters which penetrated downward.

Worm tracks in dolomite —A peculiar phenomenon, which excites much curious
interest among the miners, is the occurrence in mine workings of fragments
of hard blue dolomite riddled by small cylindrical cavities, which are at
once recognized as wormholes. Such specimens are found in the Free
Silver shaft.

In specimens which do not show this perforation a similar structure is
recognized under the microscope. In cross section there appear irregularly
rounded or curved, generally elongated areas, which are perfectly distinet
from the main rock, as if cut out. These are filled with crystalline dolo-
mite, coarser in texture than the rest of the rock. In every way these areas
seem identical with the worm tracks which are not uncommon among the
fossils of limestones and other rocks. They were evidently made at an early
stage in the history of the rock, when it was still plastic, and the cavities
thus produced were filled with vein calcite or dolomite. Where, as im the
Free Silver shaft, the cavities are now found empty, it is probable that the
filling has been dissolved out by circulating waters. On the walls of these
holes there are often very small crystals of pyrite.

THE BLUE LIMESTONE.

Description —I'he limestone which overlies the Leadville dolomite is blue-
gray in color, sometimes dark blue; it occurs in massive beds, and the
outcrop usually weathers light blue, with a smooth surface. The difference

1Bull. Geol. Soc. Am., Vol. V, p. 225.

CARBONIFEROUS FORMATIONS. 29

in weathering makes it ordinarily easy to distinguish the limestone from
the underlying dolomite in the field. The dolomite usually contains tiny
chert areas o1 grains of silica throughout its whole mass; on weathering
these project beyond the plane of the softer inclosing rock. This rough
surface affords lodging tor red, yellow, and brown lichens, while the smooth
surface of the limestone is usually quite clean. The iron of the dolomite,
which oxidizes on weathering, also constitutes another distinguishing
feature in the outcrop

In the fresh rock the distinction is also easily made. The dolomite is
made up of very small crystals of nearly uniform size, which give a frosty
appearance to the rock; while in the blue lime the texture is varied, certain
small areas being lusterless, while others show crystal faces much larger
than those of the dolomite. In the mines the method of distinguishing the
two rocks is to flash a candle on the specimen, when comparatively large
glistening facets determine the limestone and many fine lustrous points the
dolomite.

Microscopic structure— Under the microscope the structure of the blue lime-
stone is peculiar and uniform, except where it has been effaced by altering
processes, such as dolomization, silicification, and ferration. The rock
contains numerous tiny organic forms, chiefly Foraminifera, which are
embedded in crystalline calcite. The tests of these organic bodies are of
calcite, which differs radically from the coarse calcite in which they are
embedded. Under low powers it appears quite amorphous; under high.
powers it becomes a dark translucent mass, with many dimly polarizing
specks, which, however, are not large enough to be positively recognized
as individual crystals. In most of the material no polarization whatever
can be made out. The interior of the shells, however, as disclosed by the
sections, is filled with crystalline calcite like that of the cementing material.
Crystalline calcite thus makes up about three-fourths of the rock, while the
cryptocrystalline or amorphous lime carbonate makes up the remainder.
The tests average about one-fiftieth of an inch in diameter.

Dr. Rk. M. Bagg, of Johns Hopkins University, has kindly examined
some thin sections of this limestone and finds the following types of
Foraminitera:

1. Endothyra sp. 4, Bigenerina sp.

2. Nodosinella sp. 5. Valvulina sp.
3. Textularia sp. 6. Lagena sp.

30 GEOLOGY OF ASPEN MINING DISTRICT, COLORADO.

The Nodosinella is near N. priscilla Dawson; the Lagena forms are
near L. parkerina Brady; Textularia is similar in section to T. gibbosa
D’Orb.; but none of these types admits of positive specific identification
im cross sections alone.

age—In Leadville fossils are reported by Mr. Emmons which place this
horizon in the Lower Carboniferous. At Aspen no further attempt to fix
the age was made, on account of lack of time and because the determina-
tion already made is quite sufficiently established. Various Carboniterous
fossils—brachiopods, crinoids, ete.—as well as the Foraminifera which give |
the peculiar character to the ‘rock, are abundant in the blue limestone.

WEBER FORMATION.

Description—Above the blue limestone, and separated from it by a dis-
tinct plane, comes a series of thin-bedded carbonaceous limestones and
caleareous shales. The typical rock of this series is a black limestone, ”
thin-bedded and aphanitic in texture. It has two mineralogical features
which are secondary in origin, but which are peculiarly characteristic of
this horizon—the occurrence of scattered or segregated pyrite and the pres-
ence of many small irregular veins of white crystalline calcite. The rock
is usually somewhat dolomitic and locally becomes a true dolomite.

Near the lower part of the series the rock is slightly more massive,
becoming often dark blue in color or gray on oxidation. It then somewhat
resembles certain varieties of the altered blue limestone, with which it may
sometimes be confounded in the field. This variety of the Weber limestone
is found throughout a large part of the Hunter Creek and Lenado districts,
where it occurs in contact with the Leadville dolomite. The contact, how-
ever, is along a fault which has removed the blue limestone throughout
this whole area. Above this lower division the limestone becomes black,
shaly, and carbonaceous, with local thin beds of impure coal. These shales
change above to the micaceous, thin-bedded gray limestone which has been
taken as the base of the Maroon formation.

The Weber limestones are easily attacked by altering agents. ‘Thus they
are altered by underground waters along faults and watercourses, becom-
ing silicified and dolomized and changing in color to various shades of red,
brown, and yellow. Where the Weber limestone is completely dolomized,
as along fault planes and often in the vicinity of ore bodies, there may

CARBONIFEROUS FORMATIONS. 31

result a brown dolomite or “short lime” which can not be distinguished
from that formed by the dolomization of blue limestone. There is also a
marked alteration observable throughout the whole zone of oxidation, which
is apparently due to surface influences alone. In this zone the hard, firm,
calcareous shale softens and loses some of its cohesion. In consequence cf
this softening, the bluish-black color of the shale becomes dead black; this
is accompanied by a partial alteration of the calcite in the rock and in the
veins to gypsum. his change is well seen in many deep shafts which go
below the zone of oxidation and penetrate the Weber rocks at some point
where they are not softened in the vicinity of a watercourse. In the
Smuggler and adjoinmg mines these transition steps were especially noted,
the soft black ‘‘shale” of the upper levels becoming, at a depth of 700 or
800 feet, a hard, black, argillaceous dolomite. The zone throughout which
this softening extends is practically the same as that in which the oxidation
of the Carboniferous and Silurian dolomites takes place and in which the
alteration of the sulphides in the ores to sulphates, carbonates, and oxides
begins.

Microscopic structure— Under the microscope the Weber limestone is seen to
be made up largely of cryptocrystalline carbonate, so fine in grain that no
individuals can be distinguished, while some areas are more coarsely crys-
talline. The manner in which these latter areas occur suggests regenera-
tion, or crystallization by the same agents which have produced the veins
of white calcite which are so profuse. Certain forms suggest organic origin;
some of these are marked by the crystalline carbonate above noted, while
others are distinguished by the presence of much opaque, dark, nearly sub-
microscopic matter, which is probably carbonaceous and argillaceous. This
carbonaceous matter is irregularly disseminated in the whole rock, to which
it gives its black color. There are occasional small detrital grains of quartz
and of zircon. ‘The quartz in some of the sections is rounded, while in others
it has assumed the form of long, slender crystals. Since the origin of this
material is apparently detrital, the crystals are probably formed by the
building on of new silica to the original irregular grains. Pyrite is present
in small crystals, sometimes distributed with apparent uniformity through
the rock, but oftener concentrated along some weak and more porous zone.
In sections where the organic forms are found the pyrite is often unmis-

takably clustered in their vicinity.

32 GEOLOGY OF ASPEN MINING DISTRICT, COLORADO.

The beginning of the process of oxidation is seen in these sections to
be marked by the alteration of the pyrite to iron oxide. This oxide stains
the rock, concealing the black color given by the carbonaceous material;
and thus the red, yellow, and brown varieties of the Weber limestone, which
are found outcropping and in mine workings near the surface, are formed.
The more complete alteration, which produces from the firm, hard; thin-
bedded limestone the soft black “‘shale,” seems, judging from both micro-
scopic and chemical examination, to be essentially a process of leaching.
Much of the iron and of the calcite is removed by percolating waters, which,
moreover, generally bring. about complete dolomization of the remaining
carbonate. The withdrawal of this material destroys the cohesion of the
rock and causes it to assume a soft and plastic form; and analysis shows
that the argillaceous materials are greatly concentrated by this removal of
the more soluble constituents.

Conditions of deposition —Hvidence in certain parts of the Rocky Mountain
region’ shows that there was an important break between the deposition of
the lower and the upper Carboniferous, or between the formation repre-
sented in the Aspen district by the Leadville blue limestone and the Weber
carbonaceous shales. The Leadville dolomite was probably deposited in
the waters of a shallowing sea, in accordance with the conclusions already
stated. At the close of its deposition a subsidence took place, so that the
water became purer and ceased to contain any excess of magnesia. The
conditions under which the blue limestone was deposited were uniform.
The locality was sufticiently remote from shore to be entirely unaffected by
land sediments, and the water was comparatively deep. The deposits were
made up mainly of the shells of marme organisms, chiefly Foraminifera.
At the close of this period of quiet deposition a great upheaval took place,
so that what had been sea became dry land. When this land became again
submerged, sediments were evidently deposited in shallow seas near to
land, and at a rapid rate. The carbonaceous material which is character-
istic of the Weber formation, and which sometimes becomes so important
as to form local seams of impure coal, is the remains of plant material which
was brought down from the land and buried in the rapidly accumulating
mud at that period. The first sediments consisted chiefly of materials worn
from the preexisting sedimentary beds, chiefly limestones and dolomites.

1S. F. Emmons, Geologic Atlas U. 8., folio 9, Anthracite-Crested Butte, Colorado, 1894, p. 1.

CARBONIFEROUS FORMATIONS. Bs)

This accounts for the fineness of the mud and the widespread presence of
magnesia. The first indication that the sedimentary beds had been worn
away and the granite exposed on the land is the occurrence of mica scales
and other detrital materials in the gray limestone which overlies the black
carbonaceous limestones, and which has been taken as the base of the
Maroon. The amount of granitic material rapidly increases from this point
upward, till within a hundred feet or so it forms the chief and finally almost
the only constituent in the sediments.

Thickness of the Weber formation —The great Silver fault, which runs through
most of the district, at a slight angle to the bedding, has the Weber lime-
stone generally on its west side. Part of the formation has therefore been
eut out by the faulting, but how much it is not always easy to ascertain,
The most favorable places for measuring the thickness of the formation are
at the southern end of the area of the Tourtelotte Park special sheet, on the
west side of the Castle Creek fault, and from the northern end of the area
of the Hunter Park sheet through that of the Lenado special sheet. In the
former of these places the thickness is made somewhat uncertain by the
existence of an unknown number of small faults consequent upon the Castle
Creek fault, and forming only a small angle with the bedding planes. In
the latter place the presence of the Silver fault renders the measurement
dubious. So far as can be judged from the character of the rocks, however,
we have in both these places a tolerably complete section, and measure-
ments show that the maximum thickness can not be much less than 1,000
feet.

MAROON FORMATION.

Above the Weber formation comes a great thickness of mixed are-
naceous and calcareous sediments, forming impure grits and thin-bedded
shaly limestones. This formation is calcareous and thin bedded at first,
but becomes more massive and arenaceous farther up. The general color
is a peculiar dark red, which has been characterized by different geologists
in various parts of the region as chocolate red, venetian red, purplish red,
and maroon. The formation as existing im various parts of the Rocky
Mountain region has been described by the geologists of the Hayden
Survey;' as found in the Mosquito district it has been described by Mr.

1Ann. Rept. U.S. Geol. and Geog. Surv. Terr., 1873, pp. 18, 105; 18/4, p. 114.
MON XXXI 3

a4 GEOLOGY OF ASPEN MINING DISTRICT, COLORADO.

‘Emmons! under the head of ‘Upper Coal Measures,” while Mr. Eldridge?
has described it under the name of the ‘‘Maroon conglomerate.” Although
the series in the Aspen region is not conglomeratic, yet its lithological
peculiarities show conditions of deposition nearly similar to those of the
corresponding rocks of the Crested. Butte district, and so the name “Maroon
formation” has been adopted. Fossils discovered in these beds in various
parts of Colorado show the whole series to be of Carboniferous age. Plant
remains gathered by Dr. Peale® were referred by Professor Lesquereux to
the Permian, while in the Tenmile district Mr. Emmons reports many fos-
sils of Coal Measures types. In the Crested Butte district Mr. Eldridge
found fossils in the limestone pebbles of the conglomerates which belong
to the Coal Measures types. No fossils were found in this series in the
Aspen district.

The purplish-red beds pass upward into more massive and finer-grained
sandstones, which are more purely siliceous in composition and of a bright
brick-red color. This formation is well marked throughout a large part of
the Rocky Mountain district, and although fossil evidence is very scanty, it
has been referred by most geologists, on broad and general grounds, to the
Triassic. The change to these red beds, however, is not abrupt, and does
not indicate any break in the sedimentation.

Description of the Maroon formation—'The oray calcareous member which has
been taken as the base of the Maroon series is distinguished from the
underlying rocks of the Weber formation chiefly by the absence of car-
bonaceous matter and the greater coarseness of its materials. It is
essentially a very impure limestone, becoming sandy and micaceous in
bands. Its color is m general gray, which becomes yellow, brown, or red
in spots and nonpersistent bands. In some parts there are found inter-
calated green or blue thin-bedded limestones or calcareous shales. This
eray bed is well marked from the vicinity of Smugeler Mountain northward
to the limit of the Lenado special map. Its contact with the Weber shales
is exposed in a knoll not far from the Smuggler shaft. It is shown in
section in the Cowenhoven tunnel, and outcrops through most of the
distance across the Hunter Park special area, near the road running from

1Geology of Leadville: Mon. U.S. Geol. Survey, Vol. XII, 1886, p. 69.
“Geologic Atlas U.S8., folio 9, Anthracite-Crested Butte, Colorado, 1894.
%’ Annual Report of the Hayden Survey, 1873, p. 105.

CARBONIFEROUS FORMATIONS. 35

Aspen to Lenado. Its thickness was measured in the Bimetallic tunnel
at Lenado, where it is not complicated by faults, as in the Cowenhoven
tunnel, and was there found to be approximately 200 feet. It is, however,
variable, for the gray color sometimes extends up into the overlying
calcareous standstones, so that these are included in the formation. This
color is not always, perhaps not usually, original, but is the result of
bleaching in rocks which have once been colored. Cases of this were
noticed in the exposures in Hunter Park, where the brown calcareous
sandstones which immediately overlie the basal gray limestone were
bleached for a short distance on each side of fracture planes to a gray
color. Microscopically this rock is made up of cryptocrystalline calcite,
with considerable crystalline quartz in irregular grains, and crystals of
eypsum and of pyrite. The texture is porous and the pores are irregular
in shape.

Above the basal gray bed the rocks are practically the same
throughout the whole thickness of the formation, except that toward the
bottom there are rather more thin limestone beds than at the top. The
prevailing rock is a dark reddish-brown, impure, micaceous sandstone,
thin-bedded, and often shaly; in the more massive portions cross-bedding
may ordinarily be observed. This sandstone passes by easy transitions,
vertically and also laterally, into various allied but distinct rocks, which
form beds of slight thickness. Most important among these rocks is a

gray grit, which is made up mainly of quartz, mica, and feldspar, all
being evidently derived from the disruption of granite. On the one hand
this passes into a fine conglomerate and on the other into a light-gray,
often reddish, micaceous sandstone or fine grit. Generally associated with
the grits, but sometimes occurring in isolated beds in the brown sand-
stones, are other rocks—shales, generally red, sometimes green, which are
transitional from the sandstones, and various types of green and blue
limestone. These shales and limestones, however, make up a very small
part of the rocks. Probably nine-tenths of the formation consists of thin-
bedded brown sandstones, while four-fifths of the remainder is made up
of gray grits and fine conglomerates. There is no massive light-red
sandstone in the series, so far as observed.

Microscopic structure—Jnder the microscope the gray grits are found to
consist almost wholly of granitic material—quartz, feldspar, and mica,

36 SEOLOGY OF ASPEN MINING DISTRICT, COLORADO.

with the accessory materials. In the coarser varieties of the rock there is
very little indication of water action, the fragments being large and angu-
lar, and the different minerals being present in about the same proportion
as in granite. There is always, however, a parallel arrangement of the
flakes of mica, which shows that they were deposited in water. In the
slightly finer varieties there is a more distinct sedimentary structure, and a
small amount of calcite is present, probably detrital. Zircon and magnet-
ite are present in rounded grains, and crystals of specular iron and of red
hematite, probably secondary, are common. ‘The mica is sometimes green,
sometimes colorless; the green variety becomes colorless by a process of
bleaching. The iron thus removed from the biotite has probably gone to
form the crystals of hematite.

From this rock to the finer dark-red sandstone there are many transi-
tional stages. The red sandstones differ from the gray grits in being of
finer grain, in containing more calcareous and less granitic material, and
in the appearance of certain new minerals. Quartz and feldspar, chiefly
microcline, with mica, are present in about the proportion in which they
are found in granite. The quartz is always fractured and cracked, as in
granite, and the feldspar is sometimes fresh, but usually more or less
altered to muscovite and kaolin. The mica is either green and pleochroic
or colorless and without pleochroism. Much of the colorless mica is
undoubtedly muscovite, but the production of a colorless mica by the
bleaching of biotite is a process which can be observed in all its stages.
The iron which is separated out in this process at first concentrates along
the cleavage of the biotite, and afterwards is leached out and disseminated
in the rest of the rock as earthy hydrated oxide, giving the red color to
the rock in the field. In some areas the beginning of concentration of this
earthy oxide into the crystalline form is seen; this is essentially a bleach-
ing process, so far as the resultant color of the rock is concerned. Among
the minor detrital materials which are derived from the abrasion of granite
are zircon, apatite, tourmaline, and magnetite. In many of the sections
the magnetite is many times more abundant than in the granite, indicating
a concentration of this mineral by wave action, such as at present produces
the magnetic sands on our shores. here are also detrital grains of lime-
stone or dolomite. A widely distributed mineral is glauconite, in small,
irregular grains. This is generally fresh, or shows the beginning of oxida-

TRIASSIC FORMATIONS. oil

tion, a process which is characterized by the formation of small translucent
plates of red hematite somewhat uniformly througbout the mineral. There
is a cement, more or less abundant, of fine, calcareous material, apparently
detrital in nature.

The limestones and lime shales differ again from these sandstones only
in containing a still smaller proportion of granitic materials and a corre-
spondingly increased amount of calcareous material. In nearly every
section almost all the commoner minerals which are ordinarily found in
eranite are present, tourmaline, zircon, and magnetite being especially
persistent. These materials are embedded in a very fine-grained calcareous
cement, which has the appearance of having been deposited as a lime mud.
The green color of the limestones and shales is due to the presence of
glauconite, which is often abundant, in green and brownish-green grains.

TRIASSIC FORMATIONS.
RED SANDSTONES.

Lenado Canyon affords a continuous section of the rocks from Lenado
westward to where the sequence is interrupted by the Castle Creek fault.
The junction of Weber and Maroon occurs at Lenado; the brown sand-
stones begin at the mouth of the Bimetallic tunnel and continue for a long
distance down the stream, which here flows nearly at right angles to the
strike, thereby affording a complete cross section. At a point about half-
way from Lenado to the Castle Creek fault there is a marked though not
abrupt change in the appearance of the beds. The sandstones become more
massive, though they are still often thin bedded; and the prevailing color
changes from dull reddish brown to ight red. There are still occasionally
thin limestone bands; but the red sandstones predominate, and the aspect
of the outcrops is distinctly changed. There is a similar change in the beds
in the more southern part of the district examined, although here it is not
so distinct, and the upper red series appears to be thmner bedded. This
upper series of more massive and lighter-red sandstones has been provi-
sionally assigned to the Triassic period. It extends from the rather indefinite
plane described above up to a series of thin-bedded sandstones and shales
which correspond to the Gunnison formation of Mr. Eldridge’ and which
have been by him assigned to late Juratrias time. No fossils have been found
in this red sandstone formation, for the conditions of deposition were not

'Geologic Atlas U. S., folio 9, Anthracite-Crested Butte, Colorado, 1894.

38 GEOLOGY OF ASPEN MINING DISTRICT, COLORADO.

favorable to the preservation of animal remains; and as the same conditions
prevailed throughout a great part of the Rocky Mountain region, the entire
fossil evidence at this horizon is extremely scanty. It has been hitherto
believed, however, that these beds belong to the Triassic. The Triassic
was recognized in the vicinity of Aspen by the geologists of the Hayden
Survey, although the sandstones on Woody Creek, mentioned above, were
included in their maps with the Carboniferous. In the Crested Butte dis-
trict the Triassic appears to be wanting, though it may be so altered as to
be unrecognizable.

Microscopically these rocks are essentially fine-gramed, impure sand-
stones with much ferruginous material. The thickness of the Maroon and
the Triassic together can not easily be ascertained, on account of the dis-
turbances which have taken place, and especially on account of the Castle
Creek fault, which prevents the obtainment of any continuous section. It
is therefore difficult to say how much the thickness varies in different parts
of the limited area mapped; but from various sections a mean thickness
for both formations of about 6,600 feet was obtained, of which the Maroon
beds take up 4,000 and the Triassic 2,600 feet. These are the thicknesses
which have been shown on all the sections.

Conditions of deposition of the Maroon and Triassic beds —The lithological characters of
the entire Maroon series show that it is derived almost wholly from the
disintegration and rapid erosion of a granitic land mass. The rocks are
made up in large part of this granitic material—quartz, feldspar, and mica
chiefly, with some material derived from the limestones and dolomites
which had previously been deposited. Mingled with this detrital material
is some that is probably organic; of this class is some of the cryptocrys-
talline calcite. A mineral which is also of organic origin, and which is
significant of the conditions of deposition, is glauconite. This mineral is
found rather in the finer-grained and more calcareous beds than in the
purely granitic strata, showing that its formation was in water slightly
deeper than that in which the rest of the beds were deposited. The zone
at which this mineral is ususally formed is that of the outer edge of the
land-derived sediments. On the other hand, some of the grits are of nearly
pure granitic material, very little worked over by water action; these were
evidently deposited close to the shore.

In the Crested Butte area the corresponding Maroon beds are typically

TRIASSIC FORMATIONS. a9

conglomeratic, thus showing a still closer relation to the main land mass.
The similarity of the beds at the top and the bottom of the Maroon series
indicates the duration of similar conditions of deposition for a long period
of time, although the prevailmg coarseness of the sediments indicates rapid
erosion and sedimentation. To account for such prolonged rapidity of
erosion and such similarity of deposital conditions, we may suppose a land
area which was very mountainous and a gradually sinking shore line, the
subsidence of which kept pace with the building up of the beds. The
change from the coarse and varied Maroon beds to the more uniform red
sandstones of the Triassic shows a slight though well-marked change. As
in the Maroon beds, however, the continued uniformity of the Triassic
sandstones, which are similar from top to bottom, shows the continuation
of the gradual subsidence which has been noted for the underlying beds.
The greater fineness of grain in the detrital material, however, and
the greater purity (for the Triassic sandstones consist mostly of quartz
sorted by wave action), indicate a less but still noteworthy amount of
erosion, a change which may be explained by the gradual degradation
of the land. The encroachment of the sea upon the land, which has been
inferred from the lithological composition, is proved by the overlapping of
the red Triassic sandstones upon the granite in a large part of Colorado.'

GUNNISON FORMATION.

Above the deep-red sandstones comes another series of beds with dis-
tinct and persistent lithological characters. This series consists of a gray
or yellow basal sandstone, often calcareous, overlain by reddish, grayish, or

_variegated shaly sandstones. The thickness of the sandstone is about 50
to 75 feet, and that of the shales above averages perhaps 225 or 250 feet.
These beds are well exposed on the side of Red Butte, where they are
inverted; and also on the west side of Maroon Creek, where they are in
their normal position.

On Red Butte much of the variegated appearance of the beds has been
found to be due to a bleaching process analogous to that which has already
been mentioned. The normal color of the beds appears to be a red brown,
a little lighter than the typical color of the Maroon formation. There are

‘Hayden, Ann. Rept. U. 8. Geol. and Geog. Sury. Terr., 1874, p. 44; A. R. Marvine, Ann.
Rept. U. 8S. Geol. and Geog. Sury. Terr., 1873, p. 142.

4() GEOLOGY OF ASPEN MINING DISTRICT, COLORADO.

occasional interstratified limy beds. The formation is broken up by pro-
fuse, irregular jointing in many places, so that the outcrop is very friable.
In these places the red rock becomes mottled with gray, although there is
no apparent difference between the gray and the red portions except the
color. Often these gray spots mottle the rock thickly; often they are
arranged in bands parallel to the stratification; and often they unite so as
to form a continuous seam. At one locality there was observed a system
of fractures at right angles to the stratification, and the gray bands follow
these fractures to the exclusion of other parts of the rock; the gray color
penetrates for varying but always slight distances from the crevice. By a
combination of these phenomena an irregular patch of gray 4 or 5 feet in
diameter is formed in places in the red rock. These occurrences show that
the gray is derived from the red by the removal of iron; the probable agent
is carbonated surface waters, which penetrate along fractures and porous
areas, dissolve the iron, and carry it away.

Under the microscope this red shaly sandstone is seen to be very fine
erained and to be made up mostly of very small grains of detrital quartz,
with altered ferruginous materials, apparently detrital, which can not be
exactly determined. These minerals are inclosed in a plentiful cement of
calcite, which is in places finely granular and in other places without recog-
nizable crystallization. There are also flakes of gypsum. The red rock is
colored by earthy iron oxide disseminated throughout the rock; and the
gray part differs from the red only in the absence of most of this oxide, so
that only slight yellow stains are left. The transition from red to gray is
gradual, as seen under the microscope, but takes place within a short
distance.

This formation, consisting of the basal sandstone and the overlying
shales or shaly sandstones described, and having an aggregate thickness of
approximately 400 feet, is the stratigraphical and lithological equivalent
of the Gunnison formation of Eldridge,’ as described in the Crested Butte
area. Mr. Eldridge assigns this formation to late Juratrias age, basing his
correlation on its stratigraphical and lithological equivalence to the Atlanto-
saurus beds of the eastern side of the Rockies and the similarity of the
molluscan fauna found in the two localities. The fossils described by Mr.
Eldridge in the Crested Butte district were fresh-water forms, showing that

1Geologic Atlas U. 8., folio 9, Anthracite-Crested Butte, Colorado, 1894.

CRETACEOUS SERIES. : 41

the beds were deposited in fresh-water lakes; and this conclusion probably
holds good of the formation in the Aspen district.

CRETACEOUS SERIES.

DAKOTA FORMATION.

Lying above the Gunnison formation, as exposed on Red Butte and on
Maroon Creek, is a massive white sandstone which has been recognized in
this same stratigraphical position in many parts of the Rocky Mountains,
and which has been found from its fossil remains to belong to the Creta-
ceous. To this has been given the name Dakota formation. The sandstone
varies in color from white to grayish and pinkish; often it becomes fine
grained, and in bands is gritty and conglomeratic, and not only quartz, but
feldspar and other granitic detritus can be observed in the coarser parts.
In the upper part of the formation the rock is finer grained and contains
abundant plant remains, which, however, on account of the porous nature
of the rock, are not well preserved. Locally the rock becomes a quartzite,
the secondary cementing silica being often distributed in irregular bands
and lenticular areas in the sandstone; frequently it is found only in
irrecular bunches, so that there are nodules of quartzite in the sandstone.

These nodules become conspicuous on weathering

2, since they resist erosion

better than the sandstone.
The average thickness of this sandstone, taken from various measure-
ments, is about 250 feet.
COLORADO FORMATION.

The two divisions of the Colorado formation—the Fort Benton shales
and the Niobrara limestone

are both recognizable in the Aspen district.

Benton shales —A hove the Dakota sandstone comes an estimated thickness
of 350 feet of black calcareous shales, with some thin-bedded and shaly
limestones. These shales are best exposed on the west side of Red Butte,
where they are inverted. From some thin-bedded limestones in the upper
part of the formation fossils were collected which were identified by Mr.
T. W. Stanton as Gryphea newberryi and Ostrea lugubris.

Niobrara limestone — A hove the Benton shales comes a bed of dense gray or
blue limestone with a close texture and conchoidal fracture, which is per-
sistent throughout the district. This formation is well exposed in the bed
of Maroon Creek at two points, one at Red Butte, near the junction of

42 GEOLOGY OF ASPEN MINING DISTRICT, COLORADO.

Maroon Creek with Roaring Fork, and another half a mile or so up the
creek from the butte. This limestone is from 50 to 75 feet thick, and is
overlain by thin-bedded shaly limestones, which pass upward into the soft
eray or black shales of the Montana formation. On Red Butte the dense
limestone itself is somewhat fissile, which doubtless arises from the squeez-
ing to which it has been subjected in the formation of the overturned told
that is exhibited here; but in the outcrop farther up Maroon Creek it is
more massive. This limestone is a close lithological as well as stratigraph-
ical equivalent of the Niobrara limestone of the Crested Butte area, and
its correlation is based chiefly on this equivalency. In the Crested Butte
area Mr. Eldridge found fossils which indicated its Niobrara age, and the
occurrence at this horizon of a limestone similar to the one described is
widespread in this region.

The average thickness of the Niobrara in the Aspen district may be taken
at about 100 feet. The line of division between the upper shaly beds of
the Niobrara and the overlying Montana shales is not distinct.

MONTANA FORMATION.

Above the Niobrara comes a very great thickness of gray or black shales,
generally carrying thin bands or lenticular masses of impure black lime-
stone. Some of the limestone beds and lenticular bodies are partly silici-
fied. The main outcrops extend down Roaring Fork from Red Butte to the
border of the area mapped, a practically continuous exposure being afforded
along the banks of the stream and in the cut which has been made for the
railroad, and also up Maroon Creek from Red Butte for half a mile, passing

across the overturned syncline to the underlying Niobrara limestone. The

upper part of the formation, which occupies the greater part of the space
between the Roaring Fork below Red Butte and Woody Creek, is mostly
concealed by glacial detritus, so that no close examination could be made.
From the nature of the drift, however, and from occasional doubtful out-
crops, it seems probable that the upper part of the series becomes slightly
more arenaceous. The two subdivisions which the term Montana covers—
namely, the Fort Pierre and the Fox Hills—ean not, however, be well dis-
tinguished in this area In thin limestone layers ranging from below the
middle to near the top of the formation were found great numbers of fossils,
identified by Mr. T. W. Stanton as Inoceramus barabim.

CRETACEOUS SERIES. 43

The thickness of this formation, as nearly as could be estimated under
the unfavorable conditions, is approximately 4,000 feet.

LARAMIE FORMATION.

On the comparatively low ridge on the left side of Woody Creek, near
the point where the stream emerges from the canyon, a heavy bed of pure
white sandstone outcrops on the west side of the Castle Creek fault, becoming
yellowish or reddish in places, and forming a bench about 100 feet high.
This has been taken as being about the base of the Laramie formation.’
Below it, on the hillside, a shaft which has been sunk for prospecting
purposes shows a few feet of solid blue limestone of very fine texture.
Above this white sandstone come beds of impure brown and green sand-
stones, thin-bedded and friable, often micaceous and shaly. These carry
abundant plant remains, which, however, are not sufficiently preserved to
admit of identification. The series is lithologically like that of the coal-
bearing Laramie in the Crested Butte and Anthracite regions, but no coal
seams were noticed in the Aspen district, although some of the layers in
the impure sandstones above described carry such a quantity of plant
remains as to become very black and carbonaceous.

These basal beds of the Laramie form a synclinal basin against the
Castle Creek fault; outside the rim of this basin the outcrops of the
Laramie sandstones give place to the underlying Montana rocks. The
Laramie, therefore, occupies but a limited area, and only the lower portion
of the beds is exposed, the whole upper part having been removed by
erosion The actual thickness of the formation as shown here is probably
-about 500 or 600 feet

The Laramie beds are the youngest rock formations exposed in this
district, with the exception of the Glacial and post-Glacial formations,
which will be considered separately.

PRE-CRETACKOUS UNCONFORMITY.

At the close of the formation of the red Triassic sandstones a marked
break in sedimentation occurred in this and the adjacent districts. This
break was probably accompanied by a considerable uplift, for the succeed-
ing beds of the Gunnison formation, which are of late Juratrias age, are

1Annual Report of the Hayden Survey, 1874, p. 35.

44 GEOLOGY OF ASPEN MINING DISTRICT, COLORADO.

probably of fresh-water origin. In the interval between the deposition of
the red sandstones and the Gunnison sandstones and shales there was
probably some folding and perhaps a great amount of erosion. The red
sandstones appear to be missing in part or wholly in certain areas which
closely adjoin the Aspen district.

This uplift was followed by a depression, so that the Cretaceous beds
above the Dakota are of marine formation, through the Fort Benton, Nio-
brara, Montana, and a large part of the Laramie. The greater part of these
marine sediments, as illustrated by the thick Montana shales, were depos-
ited in comparatively quiet waters, and were derived from a land surface
which was being actively, but not enormously eroded. At the top of the
Cretaceous section there recur beds of sandstone, at first intercalated at
wide intervals in the shales, but finally forming beds of greater purity and
thickness. These indicate an elevation corresponding to the preceding
depression. This elevation, further carried on, is shown by the fresh-water
deposits of the late Cretaceous, and culminated in the violent uplift and
voleanic disturbance toward the close of the Cretaceous and the beginning
of the Tertiary.

CRETACEOUS-TERTIARY UNCONFORMITY.

Near the close of the Cretaceous, in the Laramie, there began a series
of disturbances which has probably lasted up to the present day, although
the amount of disturbance has varied considerably at different times. This
disturbance toward the close of the Cretaceous was manifested by the lifting
above the sea of the whole mass of the Rocky Mountains im Colorado; and
as if this uplifting were accompanied by the accumulation of molten rock
beneath the earth’s crust, at intervals great masses of lava were thrust upward
into the sedimentary rocks, or were poured out on the surface. The dynamic
strains which arose in this disturbance were relieved partly by folding of the
rocks and partly by faulting. The main uplift of the Rocky Mountains,
producing the lofty structures which excite our admiration at the present
day, began at this time. The greatest disturbance seems to have been about
at the end of the Cretaceous and the beginning of the Tertiary; the existing
Tertiary beds were deposited after this maximum disturbance, and therefore
lie unconformably upon the folded Cretaceous strata. Such Tertiary beds
are not found in the Aspen district; but to understand the history of the

INTRUSIVE ROCKS. AND

important disturbances which are manifested in the rocks of this district it
is necessary that this episode should be understood.

INTRUSIVE ROCKS.

There are two distinct varieties of intrusive rocks in the Aspen district,

a quartz-porphyry and a diorite-porphyry, both usually much altered.
DIORITE-PORPHYRY.

Habitus —This porphyry is a dark-green, fine-grained rock, showing
much decomposition, even to the naked eye. It occurs chiefly, so far as
the limits of the Aspen region go, in the form of a single sheet, which has
the usual characteristics of interbedded sheets in the Rocky Mountains.
It is in a general way parallel to the bedding of the sedimentary rocks
im which it has intruded itself, so that in any very limited area it appears
as a simple interbedded sheet; when followed along the strike, however, it
is found to cut across the beds at intervals, usually at a slight angle, so that
it is only by its position relative to the various sedimentary beds that any
change is noticeable. This single sheet of porphyry is found on the
southern border of the Tourtelotte Park special area (which was the southern
limit of the present examination), at about the horizon of the Parting Quartzite
series. Here it has a maximum thickness cf about 150 feet; it frequently
cuts across the Parting Quartzite, or surrounds it so as to conceal its out-
crop. This sheet can be traced from here toward the north nearly contin-
uously on the bare hilltop; it takes a position permanently below the
Parting Quartzite series, and gradually cuts lower down into the Silurian
dolomite. Just before reaching the area included in the special map of the
Tourtelotte Park mining district, it cuts down across the formation a little
more sharply, and near the southern end of this map it enters the Cambrian
quartzite From here its outcrop shows that it still cuts downward toward
the north, till on Aspen Mountain it lies at the very base of the Cambrian.
On West Aspen Mountain, the most northerly point at which it has been
found, there is only 5 or 10 feet of conglomeratic quartzite between the
porphyry and the granite, and on Kast Aspen Mountain it is found in
contact with the granite Ina lateral extent of 34 miles this sheet therefore
cuts across the formation 500 or 600 feet, always downward to the north.

There is also a gradual thinning of the sheet toward the north. Its
maximum thickness of 150 feet at the southern limit becomes 30 to 40

46 GEOLOGY OF ASPEN MINING DISTRICT, COLORADO.

feet at the northern limit of the Tourtelotte Park special area, and this is
reduced to 15 or 20 feet at the northern end of Aspen Mountain. This
thinning ends in the ultimate disappearance of the rock, for it is not found
or. the other side of the valley, north of Aspen.

There is also a noticeable thinning of the sheet from the east toward
the west. While the outcrop of the bed seems to be practically continuous
on the east side of the mountain spur which lies between Roarmg Fork
and Castle Creek, so far as can be determined in view of the subsequent
complicating faults, there are on the west side places where it not only
thins out but entirely disappears for a short distance, only to reappear farther
along on the same horizon. It has thus on this western slope the character
of an intermittent sheet.

Description —Very little of the internal structure of the rock can be made
out with the naked eye. It is always fine grained, dark green in color,
and uniform in appearance. Occasionally phenocrysts of darker green
than the groundmass, and having the habit of hornblende, are present.
There are also occasional feldspar phenocrysts, small and profoundly
altered around the edges, so as to present an irregular shape; and crystals
of pyrite are sometimes present. In texture the rock is granular and
slightly porous.

Microscopic structure—Under the microscope it is seen that the rock has
always a porphyritic structure, although the phenocrysts are of small size,
and the structure might easily change to granular. The phenocrysts are
always much altered, often so much so that none of the original mineral
remains. The most common form is a collection of alteration products
which form pseudomorphs after hornblende. These pseudomorphs are
primarily of chlorite; further alteration has brought about the formation
of secondary quartz, epidote, carbonates, and limonite. No unaltered
hornblende was found in any of the sections examined. Biotite is also
common among the phenocrysts, often completely altered like the horn-
blende, chiefly to chlorite, but often having residual areas of green or
brown mica, which frays out along the edges to chlorite. Feldspar erys-
tals are common, usually more or less completely altered to muscovite and
calcite; these seem to be mainly orthoclase, although some show the
moultiple twinning of plagioclase. Ina peculiar phase of the rock found
in contact with the granite on Aspen Mountain there occurs a feldspar

INTRUSIVE ROCKS. AQ

which is entirely altered to epidote, with some associated quartz. As
there are in the same section feldspars having the more usual alteration
above described, this must be a different variety, probably a plagioclase

very rich in lime—anorthite (?). Quartz is common as a decomposition
product of the phenocrysts, and occasionally becomes so prominent as to
make up the larger portion of the pseudomorph. In one section, however,
a quartz crystal, which appeared to be original, was found among the
pseudomorphs. A constant and striking mineral, apparently original, is
ilmenite, which in the sections examined is always present in remarkable
profusion. This has crystal form and shows cleavage. It alters occasion-
ally in a limited degree to a blood-red, translucent oxide—red hematite (?)—
but usually to the milky opaque alteration product known as leucoxene.
Magnetite also occurs in crystals as an original constituent; pyrite occurs
sporadically, and is probably secondary. The groundmass in which these
minerals are set is moderately fine grained and granular; its constituent
minerals are chiefly feldspar, both orthoclase and plagioclase, and quartz.

Porphyry dikes —In two localities in the district examined small dikes of
greatly decomposed rock, which, however, appeared to be the same as the
rock of the more persistent sheet, were found. One of these localities is in
the Tourtelotte Park special area, where a small dike was noticed in the
Silurian dolomite, above the main sheet; the other is on Maroon Creek,
where a dike a few feet wide was seen cutting the Triassic sandstones.

Source —The marked thickening of the sheet of porphyry toward the
south and its disappearance toward the north point out the direction from
which the intruding rock was propelled. From the southern edge of the
district in which detailed mapping was carried on the sheet was not continu-
ously followed southward, but at several points toward the south it was
observed, always thickening, and it undoubtedly runs into the great diorite
mass of Castle Peak, some 10 miles away. Castle Peak is made up mostly
_ of complex dikes and intercalated sheets of eruptive rocks in the Maroon
Carboniferous beds. To the south this complex soon changes to the solid
diorite, as shown in the adjacent White Rock Mountain, which is a part of
the great cross-cutting body of diorite found all along the axis of the Elk
Mountains, and whose advent was one of the chief phenomena connected
with the formation of that range.’

'Whitman Cross, Fourteenth Ann. Rept. U. S. Geol. Survey, Part IT, 1894, p. 179.

48 GEOLOGY OF ASPEN MINING DISTRICT, COLORADO.

The diorite of Castle Peak and White Rock Mountain differs only
slightly from the rock which on the map of the Aspen district has been
named a diorite-porphyry. The Elk Mountain diorite, of which Castle
and White Rock peaks furnish examples, is, according to Cross, a fine and
even grained rock, characterized by a nearly equal development of horn-
blende and biotite, with some quartz and local augite. The Aspen diorite-
porphyry differs from this granular rock chiefly in structure, being finer
grained and possessing a weakly developed porphyritic structure. These
peculiarities of crystallization, which in some of the sections examined show
a tendency to disappear and to merge into the nonporphyritic or granular
structure, are amply accounted for by the conditions under which it crys-
tallized—in a thin sheet at some distance from any large mass of heated
rock. Miners and others who have frequent occasion to mention the rock
in everyday life will do well to call it ‘‘diorite,” and thus avoid confusion
with the quartz-porphyry which occurs in the same district and which
belongs to a quite distinct type. This rock has been intruded into the
Aspen district from the south, the intrusive flow cutting down slightly
across the bedding, and it is undoubtedly an offshoot of the great diorite
mass of the Elk Mountains.

QUARTZ-PORPHYRY.

The quartz-porphyry of the Aspen district is easily distinguished from
the diorite-porphyry in the field by its nearly white color, which may
be changed to brown or yellow. It shows very few phenocrysts, and has
a groundmass which is aphanitic to the naked eye. It has a close
resemblance, both in the field and under the microscope, to the White
Porphyry of Leadville.

Habitus——The porphyry occurs chiefly as a sheet which is approxi-
mately conformable to the bedding of the sedimentary rocks in which i
occurs, but which locally cuts across the bedding. This sheet is always,
in the Aspen district, at a higher horizon than that of the diorite-porphyry,
being usually near the base of the Weber shales, so that the two rocks
do not come in contact. A great number of faults have occurred since
its intrusion, which, with the after-effects of erosion, have operated to
remove portions of the sheet, so that its original distribution can not
always be closely observed. Its thickness on Aspen Mountain, however,

INTRUSIVE ROCKS. AY

probably reaches 400 feet or more. Toward the south, in Tourtelotte
Park, it seems to be somewhat thinner, the average thickness being about
250 feet. Near the south end of the park the sheet cuts upward across the
shales and is not found at the lower shale horizon farther south. The
northerly pitch of the formation, combined with faulting, brings lower beds
to the surface immediately south of this point, so that neither shale nor
porphyry is exposed on the east side of the Castle Creek fault, from here
to the southern end of the district. On the west side of the Castle Creek
fault, however, the same porphyry appears in Ophir Gulch, and from there
runs nearly continuously to the southern edge of the area mapped,
occupying the same geological position as on Aspen Mountain and in
Tourtelotte Park—near the bottom of the Weber shales. Its thickness
has been estimated and mapped in this region as varying from about
300 to 450 feet, but, on account of the numerous parallel faults which
belong to the Castle Creek system, it is by no means certain that this
estimated thickness is correct. From here to the south it has not been
traced, but has been noticed at various points; it seems to thin out and
disappear, however, somewhere near and to the west of Ashcroft, after
crossing Castle Creek about 2 miles below that village.

Northward from Aspen Mountain the extent of the porphyry is con-
cealed by a fault which traverses the country, with a trend that diverges
but little from the strike of the beds, and which cuts off more and more of °*
the sheet toward the north. In this way the porphyry becomes very thin
im the Smuggler mine, and is last found as a permanent sheet in the southern
part of the Della 8. mine, where it thins out between the fault below and
the shales above; northward from this there are bowlders and fragments of
porphyry in the fault breccia, but the continuous sheet does not reappear.
What the original extent of the sheet previous to faulting may have been is
therefore hard to determine. In Hunter Park, however, it has been inferred
from the minor lithological features of the Weber rocks, and from their
thickness, that nearly the whole series came to the surface on the west side
of the fault; and since throughout this district there is no porphyry, it is
possible that the original sheet came to an end in the neighborhood of
Smuggler Mountain.

Description. —The porphyry is found freshest in exposures on the west side

of the Castle Creek fault, at the southern margin of the Tourtelotte Park
MON XXXI——4

50 GEOLOGY OF ASPEN MINING DISTRICT, COLORADO.

area. Here, where shafts have gone deep enough to obtain portions of the
rock removed from immediate surface alteration, the color is light gray, with
a greenish tinge. Small phenocrysts of quartz and dark mica are rather
sparingly disseminated, with bunches of pyrite, in a groundmass of fine and
compact texture. Feldspar phenocrysts are very small and scarcely notice-
able. Under the microscope the outlines of the quartz phenocrysts are
somewhat rounded, and there are little bays which are occupied by the
groundmass, showing corrosion by the magma previous to the consolidation
of the groundmass. The mica is nearly colorless, with brilliant polariza-
tion colors; therefore it is probably muscovite, instead of biotite, as it seems
in the hand specimen. Small, stout crystals of orthoclase are frequent, often
showing Carlsbad twinning; these are often replaced, sometimes to a large
extent, by crystalline calcite, which penetrates the feldspar along the edges
and the cleavage cracks. This calcite is evidently an infiltration; it is
coarsely erystalline and effervesces freely in the hand specimen. Pyrite
occurs in small grains; almost invariably it is found embedded in calcite,
when the latter is present, thus showing its secondary origin. Rarely there
are small, slender crystals of plagioclase feldspar. The groundmass is
finely microcrystalline, sometimes showing a tendency to micrographic
structure. Zircon is found in small grains, as well as apatite; these are
ordinarily inclusions in the mica.

In most of the district where active mining is carried on it is not possi-
ble to find any rock which is nearly so fresh as that described. ‘The same
tendency to alteration and change which has brought about the deposition
of the ores is shown in the decomposition of the associated rock. On Aspen
and Smuggler mountains and in Tourtelotte Park the porphyry is very light
in color, with a gray or green tinge, which locally becomes brown from
staining with iron oxide from the surface and along joints. It is porous and
usually contains an abundance of pyrite. ‘The circumstance that this pyrite
is more abundant in the altered than in the fresh rock shows that its forma-
tion was comparatively late and probably a feature of the alteration itself.
No mica phenocrysts remain in the altered rock, and the small altered
phenoerysts of orthoclase, and rarely quartz, are barely distinguishable to
the naked eye. Surface oxidation produces a phase speckled with brown,
the spots being of iron oxide derived from the alteration of the sulphide;
microscopic examination usually shows a kernel of residual pyrite in these

INTRUSIVE ROCKS. 51

spots. Under the microscope the frequent small feldspar phenocrysts are
seen to be sometimes kaolinized, but mostly altered to fibrous muscovite.
The groundmass is holocrystalline, being made up of quartz and musco-
vite, which is derived from the alteration of the feldspars in the ground-
mass of the fresh rock. Calcite in small grains is common. Actinolite in
sheaflike clusters and spherulitic forms is also found, clustered in certain
areas and intergrown with quartz, which appears secondary.

Both megasecopically and microscopically this rock is almost exactly
like the White Porphyry at Leadville.

Source—Besides the main sheet, which has been described, there were
found in several places in the vicinity of Aspen cross-cutting dikes, vertical
or nearly so, which may connect the bedded sheet with some concealed
body of porphyry below. One of these localities is on Aspen Mountain, at
the Bonnybel mine; the others are on Smuggler Mountain, at the Bush-
whacker and Park-Regent mines and in the Smuggler. In both these
places the dikes cut the Leadville dolomite, and they are undoubtedly con-
tinuous downward. It is also shown in the Bonnybel mine that a few small
sheets were sent out from the dike, along the bedding, altering the dolomite
to marble along their contact. In the dolomite these sheets are small and
of limited extent, not extending outside of this mine; but on reaching the
shales above the dolomite the dike merges into the main thick sheet. The
actual junction of the dike with the sheet is not observable, having been
removed by faulting.

Along the fissures represented by these dikes much molten material
must have ascended. It has been shown by various geologists that the
ereat sheets, and even the laccolithic bodies, of intrusive rocks, which are
so common in the Rocky Mountain region, have ascended along narrow
fissures; and the whole body of porphyry at Aspen may well have come
up through a few such dikes as have been observed. It therefore seems
probable that most of the porphyry which is found in the immediate vicinity
of Aspen ascended along vertical or steeply inclined fissures from some
point nearly or directly below There was apparently little obstruction
offered to the upward movement of the intrusive material until the horizon
of the Weber shales was reached. At this point the resistance offered by
the overlying rocks was so great that the accumulating material lifted the
strata bodily, instead of forcing its way through, and spread out as a thick

52 GEOLOGY OF ASPEN MINING DISTRICT, COLORADO.

sheet, becoming thinner in regions remote from the vent or vents. The
corresponding White Porphyry of Leadville is also very largely developed
as sheets at this same horizon the main sheet in Leadville overlying the
Leadville limestone, as in Aspen. This general rock type is characteristic
of the Mosquito Range, and is foreign to the Elk Mountain type, of which
the diorite-porphyry is a representative. It is quite probable, therefore,
that the White Porphyry of Leadville, and perhaps the other porphyries,
ascended from the same source as the porphyry of Aspen; and when the
intervening Sawatch Range is carefully mapped it is likely that dikes of
porphyry will be found between the two districts. The intrusive rock, as
already noted, would be represented in the granite or other very rigid rock
only in the form of narrow dikes, although the amount of material forced
up may have been as great as in the sedimentary rocks. These latter, on
account of their plasticity, offer resistance to upward movement, and invite
lateral movement along the channels naturally afforded by their stratifica-
tion planes. Thus the intrusive rock accumulated in subterranean reser-
voirs, which deformation and erosion have now brought to the surface; but
where the rocks have been planed down to the underlying granite only
narrow and oceasional dikes appear. The situation of Aspen is, therefore,
intermediate between two great axes of eruptive activity, each of which
has certain distinguishing features, one lying in the Elk Mountains and
the other in the Mosquito Range or the Arkansas Valley; and the district
evidently is, in spite of its geographical position, most closely associated
with the latter axis.

Mr. Cross! has come to the conclusion that in the case of the huge
laccolithic: bodies of intrusive rock which are common in the Rocky Moun-
tains, the narrow fissures along which the molten rock ascended, now
occupied by dikes of the same material, must have ceased to exist as
channels at the horizon of the laccolith, and suggests that the formation of
such nonpersistent channels was due to some gradually exerted force, and
not to any sudden violent rupture, such as might arise from earthquake
action. A gradually exerted force would more easily be deflected by
various causes, and the fissure might easily pass into some marked bedding
plane. In the case at Aspen, however, any slight vertical fissure, however
produced, would tend to disappear on reaching the shales. Through the

1Pourteenth Ann. Rept. U. S. Geol. Survey, Part IT, 1894, p. 240.

INTRUSIVE ROCKS. 53

granite, quartzites, hard dolomites, and brittle limestones any movement
would produce a well-marked shearing zone or set of closely grouped
fractures; in the more plastic shales, however, any slight movement would
be taken up by the uniform yielding of the entire mass, until the disturb-
ance was adjusted, and the motion would thus entirely die out near the
bottom of these plastic beds. Cases of the disappearance of faults in soft
and shaly beds have been noted by the writer in this district, it having
sometimes been possible to observe in a single exposure the whole process
of diminution and disappearance without noticeable deflection.

AGE OF THE INTRUSIVE ROCKS.

The relative age of the diorite-porphyry and the quartz-porphyry
in Aspen can not be stated, for they were not found in any place in
juxtaposition. The diorite-porphyry sheet ranges in horizon* from the
top of the granite to the bottom of the Leadville dolomite; the quartz-
porphyry sheet lies uniformly at the bottom of the Weber, and cross-
cutting dikes are rare. Both these rocks have participated in all that the
region has undergone in the way of folding and faulting. These disturb-
ances began in late Cretaceous time, according to information furnished
by neighboring districts, and Mr. Emmons’ has assigned to this general
period both the eruptive activity of the Elk Mountains and that of the
Mosquito Range. The rocks are therefore in a general way contempo-
raneous, having been injected toward the beginning of the great mountain-
making disturbance, and before the folding and faulting which followed.
The movements in the rocks, however, must have begun very soon after
these volcanic intrusions. It seems possible that the two processes may
have begun simultaneously, and that the injection of the molten rock
occupied only a comparatively brief period of time, while the strains

folding and faulting. In the Aspen district there is abundant evidence that

which were generated at the same time found relief very slowly in the

the movement along most of the fault planes is still actively going on, and
some important faults have originated in post-Glacial time.

'Geologic Atlas U.S., folio 9, Anthracite-Crested Butte, Colorado; Geology of Leadville, p. 31.

Ca AGE aes 2 ial:
GENERAL DESCRIPTIVE GEOLOGY.

ASPEN SPECIAL MAP.

This map incloses an area which has been the most productive of the
whole district. For this reason it- has been made the subject of more
detailed investigation than the other areas, and two special maps have been
constructed on the 300-foot scale—one of Aspen Mountain and one of
Smuggler Mountain (Sheets XXV and XXVII of the accompanying atlas).
These detailed maps embrace the most complicated parts of the district,
and it is in describing them that most of the strneture will be brought out.

Through the whole central part of the area, ranning from southeast to
northwest, lies the broad, drift-filled valley of the Roaring Fork. This
offers a barrier to close investigation, since the valley drift is so thick that
the underlying bed rock is nowhere shown. Judging from the attitude
and position of the strata on the north and south sides of the valley, how-
ever, there is no great complication beneath the valley itself, and the
actual structure may be inferred with comparative accuracy. It is prob-
able that the drift is not of exceedingly great depth, and that the actual
bed-rock valley bottom is a shallow, basin-shaped depression, having a
broad, curved surface, resulting from glacial erosion. This opinion is based
on an examination of mine workings which run underneath the valley.
Parts of these workings have traversed nearly the whole of the distance
between Smuggler and Aspen mountains, and the comparatively slight
depth at which they lie shows that there can not be any canyon-shaped
indentation in the bed rock. The present outline of the valley, therefore,
has been determined by glacial erosion.

The whole northern part of the area mapped is made up of red
Maroon sandstones, which have a uniform westerly dip, forming a simple

monocline, and which therefore offer no structural difficulties to the investi-
54

ASPEN SPECIAL MAP. 5D

gator. Through the western part of the area there runs in a nearly north-
south line the great Castle Creek fault, which brings the Triassic beds on
the west against the Maroon on the east, on the extremity of West Aspen
Mountain; and farther south, as the throw of the fault increases, the Archean
granite comes finally to lie against the Triassic. The narrow strip which
lies between the Castle Creek fault and the west side of the area mapped
consists chiefly of red beds of the Maroon and Triassic. The latter pre-
dominates, but in Keno Gulch is the contact of Maroon and Triassic,
which here, as elsewhere, is marked by a change from thin-bedded, shaly,
and caleareous brown sandstones to the bright-colored, more massive, and
purer Triassic sandstones. Throughout the whole of this strip the beds
are overturned, so that the Maroon beds overlie the Triassic at their pomt
of contact. All of these overturned beds form part of the closely com-
pressed, easterly dipping, and northerly pitching syneline, which lies
immediately west of the Castle Creek fault.

Plate I (opposite p. 1) gives a general view of the area shown on the
Aspen special map. The view is taken from a point down the Roaring
Fork Valley at some little distance beyond the western edge of the map.
In the foreground of this picture is the broad, flat, sage-covered valley
bottom, made up of morainal material, which has been worked over by
water action. Through this plain the Roaring Fork and its tributary
streams flow, having carved out gorges of comparatively slight depth m the
drift. At the right of the picture is Aspen Mountain, with its two prominent
ridges separated by the broad, northerly facing depression. The nearest
of these ridges is West Aspen Mountain; the farthest is Hast Aspen Moun-
tain. The flat depression between the two occupies practically the same
area as does an underlying synclinal fold in the rocks. The productive por-
tion of Aspen Mountain lies almost wholly in this broad depression, although
recently considerable ore has been discovered on the very pomt of West
Aspen Mountain. In the central part of the picture the hills on both sides
of Roaring Fork Valley appear to come together, and there is actually a
great narrowing in the valley, caused by change of formation. West of this
narrow point there lie sedimentary rocks, which, as in the case of the Weber
and the Maroon formations, are often soft, and here a broader valley has
been eroded: at the point of narrowing, however, granite comes in on both
sides. It is probable that the broad valley below this granite gateway was

56 GEOLOGY OF ASPEN MINING DISTRICT, COLORADO.

the bed of a lake subsequent to the greatest activity of the Glacial period,
and that on the bottom of the lake the morainal material was sorted and
leveled so as to form the flat plain which exists at present. In the back-
ground, looking up Roaring Fork Valley, are seen the peaks of the Sawatch.
On the left hand, or northerly side of the picture, most of the hillside is
granite, with the sedimentary formations of Smuggler Mountain coming in
above; these sedimentary formations are continuous with those in the
hollow of Aspen Mountain. In the extreme left is the east side of Red
Mountain, which is separated from Smuggler by the valley of Hunter Creek.
The name Smuggler Mountain is applied especially to the small, flat-topped
hill with heavy side gulches which lies to the west and below the mountain,
whose outline stands out against the sky. The top of this hill is not far
above the level of Hunter Creek Valley, and is heavily covered with glacial
drift. The main mountain back of Smuggler Mountain proper is of granite,
and this rock extends from here to the gateway in the Roaring Fork Valley.
In the left foreground, on the spur of Red Mountain, come in the red Maroon
beds.

ASPEN MOUNTAIN.
FOLDING.

In the northeast part of the area shown on the Aspen special map
(Atlas Sheet IX) the only feature in the plication of the beds is the usual
simple westerly dip, which extends from the granite through the Cambrian,
Silurian, Devonian and various Carboniferous formations. In the extreme
northwestern corner of the area the steep westerly dip grows shallower,
showing the approaching synclinal structure which is exhibited near Red
Butte, where the beds abut against the Castle Creek fault.

In the area shown on the southern part of the map, however, on Aspen
Mountain, there is a sudden and remarkable change in the position of the
beds. Here is developed a new folding in two directions, one parallel to
the strike and another one at right angles to it. The longitudinal section
(see Section G, Aspen district map, Atlas Sheet VII) shows a sudden
bending-up of the beds along the strike at this point. This doming-up, as
measured in the section referred to, amounts to 5,000 feet or more in the
distance between the Roaring Fork and the top of Aspen Mountain. This
amount is partly due to intervening faults, which likewise tend to raise the
beds toward the south. These faults, however, are intimately connected

o_O EEE EE EE EEE EE EE a

ASPEN SPECIAL MAP. 57

with the doming-up, and probably both have originated in a single cause;
so that in a general way the amount of uplift as measured is correct.

The uplifting of the beds along the strike seems to have reached its
maximum in the north half of the area shown on the Tourtelotte Park
special map, but its effects are seen to less extent farther south. All the
rocks between the Roaring Fork and the southern end of the district show
this remarkable uplifting, accompanied by minor folding and by intense
faulting; so that the district is entirely different from that adjoiming it along
the strike to the north. On account of its peculiar deformation this region
becomes isolated and conspicuous, and its difference from the adjoining
areas becomes even more important when it is considered that the center
of greatest uplift and disturbance has also been the chief center of ore
deposition.

Parallel with the main axis of this domelike uplift, which is also par-
allel with the general strike of the beds and with the Castle Creek fault,
are the axes of minor folds which corrugate the dome. The chief of these
minor folds is a syncline lying on the eastern side of the uplifted area.
This syneline, which has been much broken by later faults, many of which
are important, is most strongly developed just south of Aspen, where it
occurs in the depression between West Aspen and Kast Aspen mountains.
It has a general pitch to the north, so that the beds im its center strike east
and west, while those on its western side have a northwest strike, and on
its eastern side there is a southwest strike, which approaches and merges
into the normal strike of the beds throughout the whole district. This
syncline is continuous up into Tourtelotte Park, but grows constantly
shallower toward the south, and finally dies out; so that in the southern
half of the area shown on the Tourtelotte Park special map it can not be
distinguished. North of Aspen Mountain it also becomes greatly dimin-
ished in importance, but it can be traced along the eastern side of the
Castle Creek fault for a considerable distance. In the beds on Red Moun-
tain, a short distance northeast of Red Butte, there is an easterly dip which
proves the synclinal structure. This structure, as well as that of the over-
turned beds to the west of the Castle Creek fault, is shown on Section C of
the Aspen district map (P!. VII).

East of this deep, broken syncline on Aspen Mountain the dip of the
beds flattens, so that on the ridge of Kast Aspen Mountain an approaching

58 GEOLOGY OF ASPEN MINING DISTRICT, COLORADO.

anticlinal structure is indicated; but erosion on this mountain has removed
all traces of the eastern part of this anticline. Farther south along this
same axis of folding, however, a distinct anticline is traceable through a
large part of the area shown on the Tourtelotte Park special map (Atlas
Sheet XII), and in this area there is even another flattening of the beds
to the east of the anticline, which indicates the existence of a slight final
syncline resting immediately agaist the granite.

The deformation due to folding in the southern part of the area shown
on the Aspen special map may therefore be summed up as a local uplift,
which had its maximum movement in Tourtelotte Park and died away
from this point very rapidly toward the north, so that its effects are not at
all seen on the opposite side of the Roaring Fork Valley, while on the
south it also dies away, but much more slowly. This uplifting was
accompanied by minor corrugations or foldings, whose axes are roughly
parallel to the main axis of the uplift and to the Castle Creek fault.

Most of the upward movement has actually taken place along fault
planes, but these faults are confined to the disturbed areas and die out
toward the north. The main series runs north and south, parallel with the
minor foldings and with the axis of main uplift. It appears from this
parallelism between the faulting and the uplifting that the uplifting itself
was not due, primarily, to faulting, since the blocks of strata included
between these north-south faults have actually undergone much bending
previous to breaking, but that the upliftmg and the faulting are both the
results of a single disturbing influence, and that the faulting probably took
place mainly after the initiation of the upthrust movement. The upward
tension evidently found relief more easily in motion along certain north-
south vertical planes of fracture which had been developed at the same
time as the Castle Creek fault, than in the actual bending of the rocks;
thus it happens that the main uplifting has taken place along these
parallel faults.

FAULTING.

Castle Creek fault—The Castle Creek fault outcrops in the southwestern
corner of the district mapped, in Keno Gulch, where it is exposed im
several short tunnels which run from the intercalated sandstones and shales
of the upper Maroon formation eastward into the granite on the other

ASPEN SPECIAL MAP. 59

side of the fault. In these tunnels the fault seems to be dipping to the
east, as well as can be judged from the limited exposures. A little distance
westward down the gulch from the outcrop of the fault there come in the
bright-red, more massive sandstones, which probably form the lower part
of the Triassic beds. From this pomt northward along the west side of
the fault the northerly pitch of the Triassic beds brings in successively
higher and higher strata. In this way nearly the whole Triassic comes to
the surface along the narrow strip shown on the Aspen special map, for the
Maroon formation is found in the southwestern corner, and a short distance
beyond the limits of the map, at Red Butte, the Gunnison formation
comes in.

Where the Castle Creek fault outcrops in Keno Gulch it has nearly
its maximum displacement, which is indicated, as shown by sections of the
Aspen district map, by an upthrow on the east side of about 9,000 feet.
From this pot the fault is traceable northward to the northern end of
Aspen Mountain, where it passes under the drift of the Roaring Fork
Valley, and does not outcrop until it reaches Red Butte, on the opposite
side of the valley. Near the northern extremity of West Aspen Mountain
the fault is cut by a tunnel which runs from near the bed of Castle Creek
eastward through the Triassic sandstones into black Weber shales. The
amount of displacement indicated by the passage from the Triassic into the
Weber is very much less than that shown by the contact of upper Maroon
and granite in Keno Gulch, although the distance between the two points
‘is very slight. his great diminution in throw is explained by the presence
of a cross fault with a northeast trend, which has been discovered running
diagonally across the northern end of West Aspen Mountain at this point.
This fault is called the Mary B., and although short, has a heavy throw,
bringing the lower Maroon and upper Weber formations against the
Silurian, Cambrian, and Archean rocks, which southward from here lie on
the east side of the Castle Creek fault. The throw of the Castle Greek
fault, as measured at Red Butte, which is not far from the northern termi-
nation of the fault on the Aspen special map, is only about 2,600 feet, a
great decrease from the 9,000 feet at the southern end of the map. This
decrease in throw is partly owing to the difference in the dip of the beds
on the east side and on the west side of the fault; for while both have
a northerly pitch, those on the east side are, on West Aspen Mountain,

60 GEOLOGY OF ASPEN MINING DISTRICT, COLORADO.

considerably steeper. Most of the decrease, however, is due to the cross
faulting which has been noted. West Aspen Mountain is really an isolated
block, included between the Pride fault, Castle Creek fault, and Mary B.
fault. The northern end of West Aspen Mountain is also the northern end
of this upthrust block, which comes to an end suddenly at the meeting of
the Mary B. and the Pride faults. The whole of this block is enormously
elevated above the surrounding formations, but the elevation is much
greater at the southern end than at the northern, which is due to the steep
northern pitch of the beds on the northern point of West Aspen Mountain.
In this latter locality dragging of the beds has produced a series of east-
west faults, which run across from the Pride fault to the Mary B. or the
Jastle Creek fault.

Pride fault. —This fault receives its name from its occurrence in the Pride
of Aspen mine, the most northern point at which it has been located. Here
the fault has a downthrow to the east of about 2,000 feet, thus bringing down
on the east side the basal micaceous limestone of the Maroon, while on the
west side is the Silurian dolomite. From this point the fault runs straight
south through the Igneous tunnel, then through the Sixty-six shaft and just
west of the Broadway tunnel, and so to the very summit of the hill, where
it passes into granite on both sides and can not be traced farther. In the
Igneous tunnel the fault brings the Weber shale on the east against the
eranite on the west. Near the Broadway tunnel there is blue limestone
belonging to the Leadville formation on the east side of the fault, with
eranite on the west side. A short distance north of the Broadway the main
Pride fault splits into two. The course of the more westerly of these two
is nearly continuous with that of the main fault previous to dividing. This
branch may, therefore, be still called the Pride fault, while the eastern
branch, which deviates from the main fault a little in trend at the poimt of
parting, but immediately swings round and runs parallel with it out of the
area mapped and for a long distance across the Tourtelotte Park area, may
be called the Saddle Rock fault, from its passing close by the Saddle Rock
shatt in Tourtelotte Park. The effect of this division is to apportion the dis-
placement of the single fault between the two derived faults. In Section A,
where there is only a single fault, its throw is shown to be about 2,000 feet.
In Section B, however, it is considerably less, while the Saddle Rock fault,
which here comes in to the east of the Pride fault proper, has a throw of

ASPEN SPECIAL MAP. 61

1,000 feet or more. The combined throw of these two faults is probably
not far distant from the entire throw of the Pride fault north of the point of
junction.

Going south from the northern extremity of West Aspen Mountain,
where the Pride fault is first located in the Pride of Aspen mine, one passes
successively to lower and lower formations, since the dip of the beds is
steeply to the north. The Silurian dolomite, which is found on the west
side of the fault in the Pride of Aspen mine, continues for some little distance
to the south, the outcrop being made broader by the general parallelism
between the bedding and the slope of the surface, and also by the general
downfaulting of the end of the mountain to the south in parallel blocks.
In one of these blocks, however, the position of the beds is so altered that
the dolomite and limestone of the Leadville formation outcrop on the east
side of the hill and lie against the Pride fault. This block is sandwiched
between two others where only Silurian strata outerop. (See Section B,
Aspen special map, Atlas Sheet X.) Going still farther south, one crosses
over the steeply dipping Cambrian beds, with a thin included sheet of
diorite-porphyry at the bottom, and so on to the basal granite. This
eranite continues outcropping on the west side of the fault quite to the
southern limit of the mapped area.

On the east side of the fault there exists, in the Pride of Aspen mime
and neighboring localities, the basal member of the Maroon formation,
which is immediately overlain by the Weber formation a little to the south.
From this place to the point where the Saddle Rock fault splits off from
the Pride fault there is continuous shale in outcrop on the east side. ‘he
point of division is in the vicinity of the Pioneer tunnel. Farther south
one comes successively upon lower and lower formations in the block
between the two faults; thus the Parting Quartzite and the Silurian dolo-
mite are successively passed over, and at the very summit of the hill the
Cambrian quartzite outcrops and has been cut by tunnels. Just south of
this there comes in granite underlying the quartzite; there is here, there-
fore, granite on both sides of the Pride fault, and its course can not be
followed farther, nor can the amount of its displacement be known. It is
represented on the Tourtelotte Park special map (Atlas Sheet XII) as run-
ning a short distance farther south, and then as dying out or stopping in the
vicinity ef an east-west fracture; this, however, is purely arbitrary. It is

62 GEOLOGY OF ASPEN MINING DISTRICT, COLORADO.

a fact which has been noticed in the parallel faults which belong to the
same system as the Pride that the throw diminishes toward the south, and
that there is, consequently, a gradual dying out; but this disappearance of
fault movement is not so rapid in these cases as is shown for the Pride,
so that it is probable that this fault continues much farther ito the granite
toward the south. Its dip is nearly vertical, but it often, and perhaps
usually, has a steep easterly dip, as shown in the cross sections.

Along the Pride fault there has been extensive mineralization, which
is shown in many places. The ore im the Pride of Aspen mine is found
near this fault, as well as that in other workings. There is even a marked
mineralization at the contact of quartzite on the east side of the fault with
granite on the west side, at the very top of the hill, before the fault passes
finally into the granite. This mineralization is shown in tunnels, where the
quartzite is much altered and impregnated with iron and copper. Although
the ore at this point has not proved to be of any great value, it is interest-
ing as showing that the fault itself has been the chief channel for the ore
solutions, and one of the chief things in determining the final location of
WO@ ORE

Saddle Rock faut. This fault, like the Pride, is well located and defined
along most of its course by explorations which have been made in the
search for ore. Its point of junction with the Pride fault is probably a
short distance north of the breast of the Pioneer tunnel. ‘This tunnel runs
across the fault from shale into blue Leadville limestone. Opposite and
just west of this locality the Pride fault is shown cropping between the
Broadway tunnel and the Sixty-six shaft. The belt between these faults
at this point is very narrow, being but 150 or 200 feet, showing a marked
convergence of the two toward the north; they probably unite not far north
of this point, for only one fault is indicated by the- lgneous tunnel. Just
south of the point where the Saddle Rock fault is cut by the Pioneer tunnel
the fault describes a curve toward the east for a distance of 300 or 400 feet.
This curving is sufficiently well indicated by various tunnels and outcrops
along the line on which it is drawn on the map. From this extreme east-
erly point of outcrop the line of faulting on the surface swings back a little
to the west, and then continues nearly parallel with the main Pride fault,
but apparently slightly approaching it. This curving of the fault outcrop
is probably due to a local flattening, so that its dip here must be compara-

ee EEO

ASPEN SPECIAL MAP. 63

tively slight. Where the fault becomes again straight and its outcrop
parallel with that of other faults of the same system, its plane has probably
again become vertical, or is perhaps very steeply inclined toward the east.

Cutting across this curved line of fault outcrop, like the string of a
bow, is a slight fault which is in more direct continuation with the main
Saddle Rock fault than is the fault with the curved outline. The main
displacement, however, has taken place along the most easterly plane, and
the movement along this straighter fault is very slight, being a downthrow
on the east side.

The Saddle Rock fault is well shown in the Great Western, New
York, and Monarch tunnels; also, nearer the surface, in the Late Acquisition
incline and the Iron tunnel. From here it runs into the area of the Tourte-
lotte Park special map (Atlas Sheet XII), where it may be traced to the
south for a long distance. Its displacement on Aspen Mountain is seen, in
Section C, to entail as much as 1,000 or 1,200 feet downthrow to the east.
Toward the south the throw diminishes rapidly. This is due to the fact that
the beds on the west side of the fault have a flatter northerly pitch than
those on the east side, so that the formations on opposite sides of the fault
tend to converge ‘This convergence ends in the final dying out of the fault,

Along its whole course this fault is more or less mineralized, and the
nature of the ore shows that it was formed in place; there is some evidence,
however, of slight movement which has taken place subsequent to the ore
deposition. This fault, then, like the Pride, must be considered as having
developed almost entirely previous to the period when the ore-bearing
solutions circulated through the rocks.

Sarah Jane fault—'The next important fault on Aspen Mountain to the east
of the Saddle Rock fault is one which belongs to the same system, having
a nearly vertical dip and a north-south trend corresponding with that of the
faults which have already been described The outcrop of this fault is to
a great extent concealed by a covering of talus or slide material and glacial
drift; but in a general way the line of faulting is well marked, running
down the middle of the drift-filled basin which lies between the prominent
ridges of Kast Aspen and West Aspen mountains, very nearly as drawn on
the map. Its presence is indicated by the fact that the upper contact of
porphyry and Weber shales lies at a considerable distance farther north on
the west side of the fault than it does on the east. The syncline of Aspen

64 GEOLOGY OF ASPEN MINING DISTRICT, COLORADO.

Mountain has a northerly pitch, steeper than the slope of the mountain; so
that successively higher and higher beds outcrop toward the north along
each of these faulted blocks. The shifting in position of the upper contact
of porphyry and shale is shown by the fact that the Great Western and
New York tunnels run in porphyry on the west side of the fault, while on
the east side there are only Weber shale and limestone developed by the
explorations; and on the latter side the porphyry is found only near the
top of the hill.

The displacement of the Sarah Jane fault is chiefly a dewnthrow on
the east side, never very great. In the northernmost of the 300-foot sec-
tions on the Aspen Mountain map it is shown to be about 300 feet. (See-
tion A, Atlas Sheet XXVI.) In Section B it is drawn as having about
200 feet downthrow, and in Section C, which is the southernmost, about
350 feet downthrow. ‘These measurements are, however, based on very
few data, and ave, therefore, not necessarily accurate; doubtless the actual
throw of the fault may be more uniform than has been represented.

To the south the Sarah Jane runs into Tourtelotte Park, where there
are many outcrops and mine workings which afford abundant opportunity
to trace its course. ‘These explorations show that while the throw is always
downward to the east, yet it continues to decrease slightly toward the south;
so that in the middle of the area shown on the Tourtelotte Park special map
it dies out and is not farther traceable. This fault has not been prospected
to any extent on Aspen Mountain, but in Tourtelotte Park it shows evidence
of belonging to the same general class as the Saddle Rock, Pride, and Cas-
tle Creek faults, since it is mineralized to a greater or less extent along its
whole course, and since there is no evidence of any great movement subse-
quent to the ore deposition.

Schiller fault—The Schiller fault may be traced on the surface, but is best
shown underground, in the Durant, Schiller, and Aspen mines. This fault
has a north-south trend and is nearly vertical. It belongs to the same
general system as the faults which have already been described, but it has
a greater difference of throw at different places than the others, as shown
in sections taken at various points. In the southern part of the Durant
mine, which is almost exactly below the southern edge of the district
mapped, at the point where the outcrop of the Schiller fault passes mto
the area of the Tourtelotte Park special map, the fault seems to have very

ASPEN SPECIAL MAP. 65

little throw, although there is a marked zone of fracture. From this null
point southward the throw is very slight and has no constant direction.
The tendency appears to be toward a slight downthrow to the east, as seen
in the extreme southern part of the Durant mine, and as represented on
Section G of the Tourtelotte Park mining map (Atlas Sheet XXIV). It
is probable that this fault dies out entirely a short distance south of the
null point mentioned, and is not found except in the extreme northern
end of the area of the Tourtelotte Park special map (Atlas Sheet XIT).
That part of the fault, however, which lies north of this null point has
a steadily increasing downthrow on the west side. In Section C of the
Aspen Mountain map (Atlas Sheet X XVI) this downthrow is shown to be
only about 50 or 60 feet, while in Sections B and A, which are based on
rough estimates, it is represented as about 400 feet. This increase in throw
is due to the fact that the rocks on opposite sides of the fault differ in dip.
those on the west side having a steeper northerly dip than those on the east,
so that the formations tend to converge toward the south.

Parallel with the main Schiller fault are several smaller breaks, which
evidently belong to the same system, and which vary in throw in the same
general way as does the main fault. These are distinguished in mine work-
ings, where there are also numerous slight cross faults and fractures, but
they can not be described in detail here.

In mine workings it is found that ore occurs along the Schiller fault,
apparently in place; so that this fault, like the others, originated previous
to the period of ore deposition.

Aspen fault— The Aspen fault is a slight break, but is important on account
of the peculiar position which it occupies. At the junction between the
areas of the Aspen and the Tourtelotte Park special maps the uplifting on
Aspen Mountain reaches its maximum, and the beds begin to assume the
flatter position and less folded structure characteristic of Tourtelotte Park;
and the line which separates the two maps also separates two districts which
differ materially. South of this line, in Tourtelotte Park, the Aspen Moun-
tain syncline becomes continually shallower and finally dies out. Just to
the north of it, however, the syncline is more pronounced than at any other
point. Here the rocks have been so greatly folded that the eastern limb of
the syncline becomes nearly vertical, and is locally, as shown in the Durant
and Aspen mines, slightly overturned, so that the beds dip steeply to the

MON XXXI 5

66 GEOLOGY OF ASPEN MINING DISTRICT, COLORADO.

east. A short distance below this point of overturning the beds resume their
normal succession very suddenly, and the steep easterly dip changes to a
comparatively flat westerly one. The beds having this flatter dip form
the eastern part of the bottom of the syneline.

At the point where the steep dip of the overturned beds changes to the
normal westerly dip there is a slight fault, as if the change in position had
been too abrupt for flexure without breaking. This breaking is not marked
by any single plane, but by several parallel ones; the chief plane of move-
ment has been called the Aspen fault. On the east side of this fault the
beds are vertical or have a very steep dip, which may be either normal or
reversed, while to the west of the fault the beds have a comparatively flat
dip, and appear in east-west sections as nearly horizontal. The dip of the
fault, as shown in the sections, is, as a rule, nearly vertical, becoming in
depth often a little easterly, and on approaching the surface flattening out
and acquiring a dip to the west, which upward grows progressively less.
Where, therefore, the Aspen fault is encountered in the lower workings of
the mines, it is, with reference to the beds lying east of it, which are vertical
or nearly so, somewhat in the nature of a bedding fault, while it cuts across
the flat-lyimg beds on its west side at nearly right angles. Higher up m
these mines and near the surface, however, the beds on opposite sides of the
fault become more nearly alike in their attitude, both acquirmg a decided
but generally not an extreme westerly dip. In passing upward into these
rocks the Aspen fault seems also to change and to approach more and more
nearly coincidence with the bedding. In this way much of its throw, which,
even in the deepest parts of the mine, is not found to be very great, is lost,
the movement being taken up along the bedding planes of the strata. It
therefore becomes progressively more difficult to trace, and it very likely
passes into the Silver fault, as is represented in the 300-foot sections on the
Aspen Mountain map. The actual nature of this curving fault is hard to
summarize; it has in general a slight downthrow to the east, which is
very small, but increases with the difference in dip of the beds on its two
sides. The greatest actual throw, as measured between two stratigraphical
planes on opposite sides of the fault, is probably not more than 150 feet,
and the amount of this throw decreases toward the surface, and also in
depth, for in depth the rocks again tend to assume more uniform dips on
both sides of the fault.

ASPEN SPECIAL MAP. 67

Since the dip of this fault is mainly toward the west, this movement
is indicative of a reversed or thrust fault; and in a general way this seems
to be its nature, although, as already stated, in the lower part of this fault,
as exposed in mine workings, the downthrow on the east side is the
direction of the dip, and so constitutes a normal fault.

The Aspen fault is probably restricted in extent, both to the north
and to the south. Its maximum development probably coincides with the
maximum amount of folding in the Aspen Mountain syncline, and this
maximum folding apparently occurs in the southern part of that portion
of Aspen Mountain which is shown on the Aspen special map. This fault
can not be traced any distance southward in the area of the Tourtelotte
Park special map. In Section A of the Tourtelotte Park mining map
(Atlas Sheet XXII) it is represented as being present, but with a very
slight throw; and it seems quite certain that it does not exist far south
of the plane of this section. On the northern end of Aspen Mountain
there also appears to be a marked dimmution in the mtensity of the
folding and in the amount of displacement by the Aspen fault. Section C
of the Aspen Mountain map (Atlas Sheet X XVI) probably traverses the
point near which this fault has its greatest development. In Sections A
and B of the same map it is represented as bemg present but having much
less importance. It probably dies out to the north under the Roaring Fork
Valley, and is therefore more restricted than any of the other north-south
faults which have been described, being present only on Aspen Mountain.

In the process of mining large and valuable bodies of ore have been
discovered along this fault, so that it belongs to the same general class as
the faults which have already been mentioned, namely, the premineral faults.

Bonnybel and Chloride faults—These faults are shown on the map as having
only a limited extent. They are approximately parallel, having a general
northwest trend and a southwest dip. They are well shown in the Bon-
nybel and Durant mines, where their existence and the amount of disloca-
tion have been well determined in the course of extensive lawsuits. - Like
many other faults, these are not simple; but, strictly considered, the
disturbance has consisted in the breaking up into thin slices of a wedge
of rock, which has a northwest trend and a southwest dip. Within this
wedge there are many faults parallel to its sides, all of which have some
throw. For purposes of discussion, however, the displacement may be

68 GEOLOGY OF ASPEN MINING DISTRICT, COLORADO.

considered as taking place along the two planes which form the opposite
boundaries of the wedge, and to these planes the names Bonnybel and
Chloride faults have been given. These two faults may be described as
slightly converging both to the northwest in their trend and downward
in their dip, hence they may soon come together in either direction and
form a single plane, or, more properly speaking, a narrow zone of fracture,
which finally runs into the Silver fault and there terminates, so far as can
be traced. The general movement of these two faults is to thrust down
the block between them relatively to the surrounding beds. This move-
ment is best seen by the position of the Parting Quartzite, which between
the faults outcrops farther down the Iill than it does on either side of
this downfaulted block. The maximum amount of this throw may be put
at about 150 feet.

These faults, and indeed the whole of the highly fractured wedge
between them, have been intensely mineralized, and therefore the move-
ment was premineral. The faults are not traced very far to the southeast
from the point where they leave the area of the Aspen special map. The
Bonnybel fault is represented on the Tourtelotte Park special map (Atlas
Sheet XII) as terminating at a minor intersecting fault, while the Chloride
fault is represented as running into the Justice near the pomt where that
fault unites with the Copper fault. Both the Justice and the Copper faults,
however, have a somewhat different trend, which is north, instead of north-
west, and both of these faults belong to a distinct system from those
which have been described on Aspen Mountain. This system is character-
ized by having its greatest development in Tourtelotte Park, while the
Aspen Mountain system has its greatest development on Aspen Mountain,
and by the fact that the greatest displacement took place subsequent to
the period of ore deposition, while in those of the Aspen system it took
place previous to this period.

Vhe Chloride and Bonnybel faults are therefore quite distinct in point
of age from the Justice and Copper faults, and if the Chloride fault
actually runs into the Justice, as it seems to do, they still must be considered
as belonging to separate systems. It is probable, however, that the
original fracture, which was formed at a very early date, was actually
continuous along the planes now occupied by the Chloride and Justice
faults, and that in the case of the Chloride fault the maximum displace-

ASPEN SPECIAL MAP. 69

ment took place at an early period before the ore deposition, while the rest
of the fracture was undisturbed, and that the later movement, which was
centralized in Tourtelotte Park, produced the Justice fault along the
southern part of this fracture in postmineral times.

East Aspen Mountain faults——Q)n the east side of Hast Aspen Mountain there
comes in a series of nearly parallel faults, which extend continuously into
the Tourtelotte Park district, where they are much more important than on
Aspen Mountain, since they belong to the Tourtelotte Park system, which
has its greatest development at a point farther south than the Aspen
Mountain system, to which most of the faults on Aspen Mountain belong.
These faults, as shown on Hast Aspen Mountain, have a general northwest
trend, which is a slight variation from the normal north-south trend of the
same faults, or of faults belonging to the same system, in the Tourtelotte
Park district. With the change in trend on Aspen Mountain there is also
a convergence, so that the various faults tend to unite, and after uniting, to
die away. The amount of dislocation decreases steadily from the south
toward the north, and on the north side of Kast Aspen Mountain, as is
shown by the displacement of the Parting Quartzite, which is found to be
nearly continuous in outcrop, the system comprises only two planes of
shght faulting. Judging from these indications, it is likely that these faults
die out very soon after leaving East Aspen Mountain, and it is probable
that, like the Chloride and Bonnybel faults, they stop on reaching the
Silver fault. No ore has been found along them on East Aspen Mountain,
and in the Tourtelotte Park district it has been shown that they were
developed subsequent to the period when the ores were deposited, and
are, therefore, not at all mineralized.

At the extreme southern end of the map, on Hast Aspen Mountain,
there is shown one of the cross faults that are so common in the Tourtelotte
Park district, which belongs to the general system of east-west postmineral
faults that is there so conspicuously developed. In this case the fault has
apparently brought the Silurian dolomite on the south side into contact
with the Archean granite on the north side.

Mary B. fault—'T‘he Mary B. fault is so named from its being cut in the
Mary B. workings, which pass through the lower arenaceous limestone of
the Maroon formation into the dolomite of the Silurian. In a tunnel which
starts from near the bed of Castle Creek in Triassic sandstones and runs

70 GEOLOGY OF ASPEN MINING DISTRICT, COLORADO.

east across the Castle Creek fault, black Weber shales are found on the
east side of the fault. It seems very probable that in this case the shales
lie on the northwest side of the Mary B. fault, as represented on the map,
and that the contact of basal Maroon limestone and of Weber rocks lies
between the two tunnels mentioned. The displacement of the fault is
indicated by the change from the base of the Maroon to the Silurian, which
shows a downthrow on the northwest side of about 2,000 feet. The fault
probably splits off from the Castle Creek fault near the northern end of
West Aspen Mountain, and, assuming a northeasterly trend, and thus
diverging from the Castle Creek fault, which has a northwesterly trend,
it soon runs into the Pride fault.

At the extreme northern point of West Aspen Mountain the throw
of the Pride fault is almost identical in direction and amount with that of
the Mary B. fault, so that the contact of Maroon and Weber is seen on
the opposite sides of the mountain, separated only by the wedge-shaped
upthrust block of Silurian, Cambrian, and Archean. Where these two faults
come together, therefore, as they evidently do at the very end of the
mountain, the effect must be to neutralize each other, so that while the
Pride fault may be continuous farther northwest into the Castle Creek fault,
its throw has become very slight. Along the Mary B. fault there has been
discovered in the Mary B. tunnel a body of ore, in part at least high grade,
which has evidently been formed in place; therefore this fault is, so far as
can be ascertained, identical in age with the faults already described, bemg
antecedent to the ore deposition.

Cross faults —Qn the map near the northern end of West Aspen Mountain
are shown three parallel east-west faults, which have a northerly dip some-
what steeper than the slope of the mountain. (See Section B, Aspen special
map; Atlas Sheet X.) These faults divide the point of the ridge into par-
allel slices, which have moved one upon the other. The general movement
appears to be a downthrow to the south, and since the faults have a northerly
dip, they come under the head of reversed faults. This movement is indi-
cated by the outcropping blocks of quartzite on the west side of the moun-
tain. In one of the blocks, however, there outcrops, as shown on the map,
a narrow belt of Parting Quartzite. The rocks in this block seem to differ
from those in the adjoining blocks, in that there has been a change in the
position of the beds, giving a more easterly dip. In this way the Parting

“NIVLNMNOW NSdSV LSAM

Id =1XXxX HdVHYSONOW ASAYNS 1VOISOIOSS “S “nN

ASPEN SPECIAL MAP. all

Quartzite is exposed on the top of the hill, and as the rocks dip more
steeply on the east side of the hill than does the slope of the hill itself,
there are found below the Parting Quartzite outcrop the dolomite and blue
limestone of the Leadville formation On both sides of these Leadville
rocks, and separated from them by the cross faults, is the Silurian dolomite.
At this point the block presents in cross sections the aspect of being down-
faulted relatively to the blocks on both sides, as is shown in Section B,
although on the west side of the hill, as shown by the outcropping Cam-
brian quartzite, the block has the same general movement as its neighbors,
being downthrust from the block next north, and upthrust relatively to the
block next south.

In one of the parallel east-west faults of West Aspen Mountain, which
is cut by the Falco tunnel, some ore is found. These minor faults, there-
fore, are also probably older than the ore deposition.

Pl. II is a view of the end of West Aspen Mountain, taken from the
valley near the Roarmg Fork and looking southwesterly up Maroon Creek.
The outcropping rocks, as best seen in the case of the Silurian dolomite on
the extreme north face of the mountain, have the same angle of dip as
does the mountain itself, while the somewhat steeper faults run up the
mountain in the shallow gulches or depressions lying between the out-
cropping, nearly parallel ridges, which are seen in the picture. In the
foreground of this plate is the Roaring Fork, while in the distance, on
the west side of Maroon Creek, are seen the upper Triassic beds and the
rocks of the Gunnison formation, with the Dakota sandstones forming
the top of the ridge as it slopes away gently to the west.

Silver fault —The Silver fault is developed continuously by mine workings
through the whole of its course across the area of the Aspen special map.
It is marked by a thin zone of brecciated material, whose composition often
shows that some of it has been dragged from a distance, and by polished
and striated walls of hard rock. On Aspen Mountain there lies always to
the east of the fault the blue Leadville limestone, and to the west the sonata
thick sheet of porphyry. Between the porphyry itself and the fault there
is usually a zone of crushed and broken shale, often mixed with porphyry,
which is never very thick and sometimes is almost entirely absent. On
Aspen Mountain the Silver fault is not exactly parallel with the bedding,
for in the northern part of the mountain it cuts deeper into the beds, so

O24 GEOLOGY OF ASPEN MINING DISTRICT, COLORADO.

that the blue limestone becomes continually thinner. Under the Roaring
Fork Valley the Silver fault cuts out the blue limestone altogether, as may
be observed in the Mollie Gibson workings; and from this point north
through Smuggler Mountain to the edge of the area mapped the Leadville
dolomite lies on the east side of the fault.

Uxtending a short distance into Smuggler Mountain, north of the point
where the blue limestone is cut out, is a narrow band of porphyry lying
“next the fault on the west side, but this, too, is only a wedge left by the
encroaching fault, and dies out completely: in Smugeler Mountain, so that
it is not found at all m the northern part. Throughout the northern part
of the area shown on the Aspen special map (Atlas Sheet IX), therefore,
the amount of displacement appears to have been greater than im the south-
ern, for in the southern part it has removed only a part of the Weber shale,
which lies underneath the main sheet of porphyry, while in the northern
part it has removed the whole of this shale, together with the porphyry
sheet and the blue Leadville limestone, with part of the Leadville dolo-
mite. Just beyond the northern limits of the Aspen special map the fault
cuts still farther down, so as to remove the whole of the Leadville dolomite,
the Parting Quartzite, and a part of the Silurian.

The Silver fault everywhere shows evidence of great mineralization,
and along it most of the ore thus far taken out has been discovered. It
therefore belongs to the premineral set. All the other faults of Aspen
Mountain, however, displace the Silver fault, when they cut it, in exactly
the same proportion as they do the rock formations, so that they must have
been developed at a distinctly later time than the Silver fault.

RESUME OF STRUCTURE ON ASPEN MOUNTAIN.

In the eastern part of the area the beds have the nearly uniform westerly
dip which is persistent throughout a large part of this belt of ore-bearing
rocks, while in its southwest part the rocks are uplifted toward the south
so as to form a sort of dome, whose northern termination pitches steeply
toward Roaring Fork Valley. The north face of this dome, as seen on
Aspen Mountain, is bent into minor folds parallel with the longest axis
of uplift, of which the chief is a shallow northerly pitching syncline, which
occupies the space between Hast Aspen and West Aspen mountains. Hast
of this syneline the beds flatten somewhat and tend to assume an

ASPEN SPECIAL MAP. 73

anticlinal structure; but if this anticline was ever developed in the area
shown on the Aspen special map, it has been removed by the erosion on
East Aspen Mountain.

The faulting has occurred almost entirely subsequent to the folding, and
is conspicuously best developed in the region where this folding had been
oreatest, namely, on Aspen Mountain. The Silver fault, which runs through
the whole mineral-bearing district from northeast to southwest, was proba-
bly developed at about the time of the folding The other faults of Aspen
Mountain are more limited in extent, although they are very important.
Chief among them are certain nearly vertical north-south faults, which are
parallel to the Castle Creek fault and have an intimate connection with it.

The Castle Creek fault has its maximum development near the south-
west corner of the area, in Keno Gulch, its throw being greater there than
anywhere else in the district. From this point it diminishes both to the
north and to the south. The heaviest of the north-south faults of Aspen
Mountain lie nearest to the Castle Creek fault, and as the distance from the
Castle Creek increases the throw of the parallel faults becomes generally
less and the persistence north and south diminishes. These Aspen Moun-
tain faults are apparently of the same age as the Castle Creek fault, all
having the same trend and all having been formed previous to the ore depo-
sition; and, like the Castle Creek fault, they have their maximum develop-
ment on Aspen Mountain. The Castle Creek, the Pride, the Sarah Jane,
and the Saddle Rock are continuously traced into the Tourtelotte Park dis-
trict, all of them growing less toward the south and the smaller ones com-
pletely dying out. In the Schiller fault the diminution toward the south is
much more rapid, for here the null point is reached at the southern end of
the Aspen area, and the fault has not been traced into Tourtelotte Park.
The Aspen fault, which is the slightest and the most easterly of the series,
apparently dies out more suddenly in both directions, since it has not been
traced into Tourtelotte Park and does not appear to be important in the
north end of Aspen Mountain. All these faults disappear under the drift of
the Roaring Fork Valley to the north, where they have not been explored;
but they can not be traced on the other side of the valley in Red Mountain,
and it is probable that they die out in the Maroon sandstones. The throw
of these north-south faults varies, the Pride and Sarah Jane having a down-
throw to the east, while the Castle Creek and the Schiller have a downthrow

74 GEOLOGY OF ASPEN MINING DISTRICT, COLORADO.

to the west. There is, therefore, no uniform displacement, but the blocks
formed between the faults have simply moved up or down to accommodate
some lateral stress.

There is no definite system of east-west faults on Aspen Mountain.
A few faults which have this trend are apparently local cross fractures,
which have no great persistence, and whose characteristics show that they
were probably developed at the same time as the north-south faults, This
includes the faults on the point of West Aspen Mountain and those of the
Bonnybel and Chloride group.

On East Aspen Mountain there is a system of north-south faults which
is quite different in age and nature from the Aspen Mountain system. This
system has its greatest development in Tourtelotte Park and is later than
the ore deposition.

SMUGGLER MOUNTAIN.

In Smuggler Mountain there is no sign of any continuation of the
Aspen Mountain syncline, but the beds all dip uniformly and steeply to
the northwest. The amount of faulting is also greatly diminished, and the
important north-south faults of the Aspen Mountain system are not found.
There are, however, several minor systems of faults, which, on account of
their difference in age, their great variation in attitude and in direction of
throw, and because they have often all acted im the same area, are very
puzzling.

Silver fault——The Silver fault is present throughout the whole of Smuggler
Mountain. In the Mollie Gibson mine, at a locality beneath the Roarmeg
Fork Valley, it cuts out the blue limestone, and therefore obliterates the
Contact fault? from this point north. The mines follow the Silver fault as
the chief ore-bearing locality, and find all along it more or less mineraliza-
tion. It is marked by a heavily brecciated zone, with solid shale and
sometimes a thin band of porphyry on the west or upper side, and Leadville
dolomite on the east side. It cuts down into this dolomite and nears the
Parting Quartzite just before leaving the area to the northeast.

Detla fault——The Della fault has an east-west trend and a southerly dip
of about 30 degrees from the horizontal. The beds on the under side
of tae pleite are faulted to the west, and the striz show that the actual

: The Contact fault runs coarse 0 in bedding and separates the blue limestone from the
dolomite of the Leadville formation throughout a large part of the district.

ASPEN SPECIAL MAP. (5

movement has been to the southeast on the south side, the direction havy-
ing been at an angle of 45 degrees to the horizontal on the fault plane.
The perpendicular separation of corresponding beds is about 150 or 200
feet, and this separation is traceable in mine workings from top to bottom
of the hill, for the dip of the fault is only slightly greater than the slope of
the hill. Its outcrop can not be actually observed on the ground, for at
this point there is a very thick covering of morainal material. The line
represented on the map (Atlas Sheet XXVII) is calculated from the
underground workings. The fault is represented on the map as dying
out in the red Maroon sandstones, and this it probably does sooner or
later. There are several slips parallel to the Della fault and having the
same sort of motion, but in none of these is any great displacement
observable. The Smuggler fault, however, which lies a short distance
south of the Della, appears to become quite important in the lower part
of the Smuggler and in the Mollie Gibson mine.

The age of the Della fault, and of the smaller faults which are
parallel with it, is indicated by the phenomenon of ore deposition. The
chief ore shoots throughout the mountain are found at the intersection of
the Silver fault with the Della fault and other faults of this system, where
the Silver fault is cut off by the flatter fault above. This persistent and
conspicuous influence of the Della system of faults upon the distribution
of the ore shows that these faults existed prior to the ore deposition. On
the fault planes, however, as has been especially well observed in the case
of the Deila fault, there is often found crushed and broken ore, while most
of the rock along these planes is entirely barren and shows no evidence
that any ore has been formed there in place. The mine managers find,
moreover, that the motion along the Della system of faults is still going
on, as shown by the deformation of mine workings. The combination of
these facts leads to the inference that while the Della system of faults
existed previous to the ore deposition, the motion went on after the forma-
tion of the ores; so that in the case of the Della fault probably a large,
if not the larger, part of its motion was postmineral.

Clark fautt—In the Mollie Gibson and Smuggler mines there is evidence
that the ore bodies, together with the inclosing rocks and all previously
formed features, have been extensively faulted by a comparatively recent
movement. The evidence of this faulting is fairly conspicuous in these

76 GEOLOGY OF ASPEN MINING DISTRICT, COLORADO.

mines, consisting of many nearly vertical polished and striated surfaces,
which indicate a general zone of movement. The general effects of this
movement were to upthrow the rocks on the east side, for in this neigh-
borhood the dip of the Silver fault becomes much steeper than usual, on
account of its continual upthrust. It seems probable that there are several,
if not many, parallel slips which here diverge and there merge into one
another, but they may be conveniently considered as a single fault, and
in the Mollie Gibson mine, where this fault has been recognized, it has been
called the Clark fault. The fact that the Clark fault is only slightly steeper
than the Silver fault, which it runs very close to, and the further fact that
the uplifting of the rocks on the east side of the Silver fault by the Clark
fault and its dependent slips gives a slightly steeper apparent inelination to
the Silver fault, make it difficult to follow and trace out in detail all of this
movement. In the Gibson mine, however, it has been found that one of
the main slips belonging to the Clark fault runs very close to the Silver
fault, but has dolomite on both sides, thus showing that the two are not
strictly parallel. The evidence of displacement is chiefly in the faulting
of certain of the ore shoots inthe Mollie Gibson and in the Smuggler. These
ore shoots have peculiar characteristics, and hence are traceable without
ereat difficulty. The displacement of these shoots shows that there has
been a movement toward the north on the west side of the fault of 500 or
600 feet, combined with a vertical movement downward on the west side
of 300 or 400 feet. Thus the actual movement was toward the north on

the west side of the fault at an angle of 30 degrees or so with the horizontal, —

this angle being taken on the nearly vertical plane of the fault, and the
total displacement was 600 or 700 feet.

North from the Smuggler mine this fault becomes still harder to trace,
but near the Johnson tunnel the outcrops of Weber shales and of Archean
granite seem to come suddenly very close together, so that there is no
room, apparently, for the Parting Quartzite between the granite and the
Silver fault. This apparent thinning of the strata at the surface, which is
not found underground along the Silver fault, is probably due to the action
of the Clark fault, as shown in Section A (Atlas Sheet XXVIID). Its
throw is, however, represented as already diminished, and it probably
grows still less toward the north. Along the top of the mountain this fault
is hardly distinguishable from the Silver fault. In the Regent mine,

ASPEN SPECIAL MAP. A

however, there is found along this line a marked north-south fault, nearly
vertical, which has an upthrow on the east side of about 30 feet. This
probably is the representative of the Clark fault. In the mapping, how-
ever, it is represented that the Clark fault, owing to its difference in dip
from the Silver fault, passes into this latter fault and is lost, so that at the
surface only a single fault outcrops, as indicated. The Clark fault along
its entire course may be regarded as a movement which has taken place
mainly along the Silver fault; locally, however, the plane of movement
deviated slightly from the preexisting fault plane.

In the Mollie Gibson and Smuggler mines, where the Clark fault has
operated, there is present an apparently new set of faults belonging to the
Della system, along which ore has been deposited. The ore shoots were,
therefore, formed subsequently to these faults (which are called, in the
Mollie Gibson mine, the Gibson and the Emma), as they were formed
subsequently to the Della and Smugeler faults in Smuggler Mountain
proper. The movement along the Clark fault which displaced the ore
shoots must, therefore, have displaced the faults belonging to the Della
system, and the amount of movement, as shown by the ore bodies, is very
nearly or exactly that by which the Della and Smugeler faults are
separated from the Gibson and Emma. The facts seem to indicate that
the Gibson and Emma faults were originally identical with the Smuggler
and the Della, and that they have been separated by the cross-cutting Clark
fault at the same time as were the ore bodies. Along the Clark fault in
the Mollie Gibson mine the breccia contains many fragments of ore.

RESUME OF STRUCTURE ON SMUGGLER MOUNTAIN.

The beds on Smuggler Mountain dip uniformly and steeply to the
west, and’have been broken by three distinct sets of faults. The first set
is represented by the Silver fault, which is nearly parallel to the bedding,
and which was formed previous to the period of ore deposition and also
previous to any of the other faults. The second set is represented by the
Della fault, which is later than the Silver fault, as is shown by the fact that
it faults this fault wherever it intersects it, and which originated previous to
the ore deposition, but continued developing subsequent to that period, and
is probably still growing slightly. The third set arose from movement
along the plane of the Silver fault, which took place locally in planes

78 GEOLOGY OF ASPEN MINING DISTRICT, COLORADO.

varying in position from that of the Silver fault. ‘This movement, repre-
sented by the Clark fault, is therefore very nearly parallel to the bedding,
and is also very close to the Silver fault, into which it probably merges
both to the north and to the south. This third faulting was entirely sub-
sequent to the ore deposition and to the Silver and Della systems of faults,
both of which it faults wherever it intersects them.

RED MOUNTAIN.

This mountain, which lies immediately northwest of Smuggler Moun-
tain and on the other side of Hunter Creek, is made up almost entirely of
uniformly west-dipping sandstones and grits of the Maroon formation It
offers, so far as known, no complications in geological structures ‘There is
no folding, and what faulting may exist is obscured by the uniformity of
the beds. No mineral deposits have been discovered on Red Mountain, and
there is no great probability of any ever being found. There is a popular
notion, however, that this mountain lies in the same belt as West Aspen
Mountain, on which large deposits of ore have recently been found. This
idea arises from the fact that Red Mountain is situated directly opposite
West Aspen Mountain on the north side of the Roaring Fork; thus it has
been supposed to have the same relation to West Aspen Mountain as has
Smuggler Mountain to the eastern part of Aspen Mountain. Across
Smuggler Mountain and East Aspen Mountain there is a continuous belt of
mineral-bearing rocks, and the same has been thought to be true of West
Aspen and Red mountains. It is clear, however, that West Aspen and Red
mountains are in totally distinct geological formations, and that the corre-
spondence in position is due to the domelike uplifting and synclinal folding
of Aspen Mountain, which does not extend across Roaring Fork to the
north. There has been a small amount of exploration for ore on Red
Mountain, and some of the workings have cut belts which show a slight
amount of mineralization, but the character of the rock is not favorable to
such extensive mineralization as has occurred in the limestone and dolomites
of the underlying formations.

Pl. II is from a photograph of Red Mountain taken from the foot
of Aspen Mountain. The rounded or flattened summit is due to glacial
action, for on top there is considerable morainal material, consisting mostly
of granite and quartzite which is derived from the other side of Hunter

"NIVLNMOW NadSV WOYS 'NIVLNMOW Gay

La _____

Ill “Td IXXX HdVYSONOW ABAYNS 1¥9ID01039 *s "nN

ASPEN SPECIAL MAP. 719

Creek Valley, some distance to the east. The sides of the mountain,
however, are in large part bare and afford practically continuous outcrops.
Near the base of the mountain there are seen strongly marked, broad,
successive terraces, which are continuous from this point down the valley
for several miles. These terraces are carved out of the bed rock, but are
covered and often disfigured by morainal material; it appears probable
that they mark the shore lines of a lake which existed in the Roaring
Fork Valley just where the town of Aspen is located. The plate also
shows a typical portion of the town itself, with the Hunter Creek Valley
in the right background.

DESCRIPTION OF SECTIONS.

Section A—Section A (Atlas Sheet X) traverses Smuggler Mountain,
passing through the mouth of the Johnson tunnel, and runs along the top
of the uppermost and most strongly marked terrace at the base of Red
Mountain. This section presents no complications in the way of folding,
since all the beds have a uniform steep northwesterly dip. This dip is
apparently greatest close to the granite on the east side of the section, and
least in the Maroon beds on the west side. The Silver fault is seen in this
section separating the dolomite of the Leadville formation from the Weber
shales. There is also a thin sheet of porphyry lying at a variable but
always short distance above the fault, which represents very nearly the
northern termination of the main porphyry sheet. This sheet, although
represented in the section as continuous, is actually crushed, broken, and
intermittent, showing that it has been profoundly influenced by the effects
of the fault. There is in this section none of the blue Leadville lime-
stone, but the dolomite always lies immediately below the fault.

The Della fault is actually developed in that part of the section west
of the Johnson tunnel, as is here represented, having a perpendicular sepa-
ration to the west, on the north or under side, of about 200 feet. This fault
displaces the Silver fault. The uplifted portion of the Della fault which
appears on the east side of the Johnson tunnel is not shown underground,
since there are no workings in this vicinity, but it is put in on theoretical
grounds. The nearly vertical fault which displaces the Della fault is the
Clark. This, also, is not actually proved, as shown in the section, but,
judging from its effect in the workings of the Mollie and the Smuggler, it

80 GEOLOGY OF ASPEN MINING DISTRICT, COLORADO.

must be present. In the outcrops there is along the line of this section a
decided diminution in the thickness of the formations, so that the distance
between the granite and the Weber shales becomes abnormally small, and
there appears to be no room for the Parting Quartzite or for the Leadville
formation above it. In the underground workings, however, not only the
Parting Quartzite but the Leadville dolomite ‘above is present, showing that
it is not the Silver fault which has thus cut out the Parting Quarzite in
outcrop. The way in which the Clark fault has probably produced this
local narrowing of the outcrop is shown in the section, and the explanation
is based on its actual movement as displayed in the Mollie Gibson and
Smugeler workings. The downthrow of this fault on the west is shown in
the sections as about 300 feet, but it will be remembered that the actual
displacement is downward to the north on the west side of the steep, slip-
ping plane, at an angle of about 30 degrees to the horizontal. Westward
from the Silver fault to the end of the section there is nothing, besides the
porphyry already described, but Weber shales and the sandstones, lime-
stones, and erits of the Maroon formation.

Section B—Section B, Atlas Sheet X, runs northwest from the summit
of East Aspen Mountain across to the ridge at the northern termination
of West Aspen Mountain, and so across Castle Creek into the Roaring
Fork Valley and out of the area.

At the eastern end of the section the beds are seen to have a shallower
dip than at a little distance farther west. This shallowing of the dip is
indicative of the approach to the anticlinal structure which has already
been noted as sometimes occurring to the east of the main syncline. From
the top of East Aspen Mountain the dip steepens steadily toward the west
for a while, then suddenly flattens on approaching the bottom of the Aspen
Mountain syncline. At the point where this steep dip of the eastern limb
of the syncline changes to the flat dip at the bottom of the fold there are
several slight slippings and faultings developed, of which the Aspen fault is
the most important, and is the only one represented in the section. This
fault has a slight downthrow to the east, not noticeable in this section; it
probably runs into the Silver fault, and therefore its upper part is lost.
The Silver fault is shown separating the porphyry from the Leadville
formation, with a thin, variable band of broken shale between; the actual
contact is between shale on the west side and the blue Leadville limestone

ASPEN SPECIAL MAP. 81

e

on the east. ‘This blue limestone makes its first appearance in the space
between Section A and Section B, under the Roaring Fork Valley, as
shown in the Mollie Gibson workings. South of this point it always lies
below the Silver fault, while to the north it is as uniformly absent. The
Silver fault is downfaulted beyond the scope of the section by the Schiller
fault, and continues below the plane of the section as far as the Pride fault,
when it is upfaulted so far that it has been entirely removed by erosion
on West Aspen Mountain. The Mary B. fault throws down the rocks on
its west side so that the Silver fault is again brought far below the plane of
the section, and the Castle Creek fault thrusts it down still farther. It is
visible, therefore, only in a narrow strip between its outcrop in Vallejo
Gulch and its termination against the Schiller fault.

In this section the Schiller fault has a heavy downthrow on the west
side of about 600 feet, while the Sarah Jane fault, lying next west, has its
usual slight downthrow on the east of about 200 feet. The Pride fault has
a throw of about 2,000 feet, so that on the east side of the fault at its out-
crop are Weber shales, and on the west is granite. ‘The section next passes
diagonally through the point of West Aspen Mountain. The obliquity of
the section makes it appear as if the beds on West Aspen Mountain were
dipping away from the Aspen Mountain syncline, while in reality they have
a general dip toward it, although the actual dip is more to the north than
to the east.

The east-west northerly dipping faults of West Aspen Mountain are
also shown in the section, and the Mary B. fault is cut not far from its
junction with the Castle Creek fault, a little distance to the south. Here
the basal limestone of the Maroon comes in just above the contact with the ~
Weber. At the Castle Creek fault the easterly dipping reversed red sand-
stones of the Triassic come in and are continuous to the end of the section,
except where covered with wash. As shown in the section, the Mary B.
fault has a downthrow on the northwest side of about 2,000 feet, while the
throw of the Castle Creek fault, as roughly estimated by the distance from
the middle of the Triassic to the bottom of the Maroon, is 5,300 feet or more.

Section c—Section C (Atlas Sheet X) cuts across the southwest corner of
the Aspen special map, parallel with and only a short distance from Section
B. Asin Section B, the plane crosses the Aspen Mountain syneline at an
angle, so that the northerly pitch of the syncline causes the general inclination

MON XXKI——6

82 GEOLOGY OF ASPEN MINING DISTRICT, COLORADO.

of the beds to the northwest, as seen in the section. ‘The features of the
section are nearly like those of Section B. The northerly pitch of the Sil-
ver fault carries it, with the associated beds, into the section for the whole
distance from its point of outcrop on the east side of Vallejo Gulch to the
granite on the west side of the section. It is upfaulted on the west side
by the Saddle Rock fault, so that it outcrops in the plane of the section,
and is again upfaulted to the west by the Pride fault so as to be carried up
into the air and lost. The Aspen fault is shown with its slight, peculiar
downthrust on the east side. The Schiller fault, which is here nearer its
termination than in Section B, is shown with a throw of less than 200 feet.
The Sarah Jane fault has about its usual downthrow of 250 feet to the
east. The section cuts the Saddle Rock and Pride faults just south of
their point of junction, at a point where they are very close together. The
throw of the Saddle Rock fault is shown as about 1,100 feet down to the
east, while that of the Pride fault can not be actually measured, since
the granite on its west side does not afford a definite horizon, but it is
1,200 feet at least. From the Pride fault to the Castle Creek fault there is
nothing but granite, for the northerly dip of the beds at the northern
termination of West Aspen Mountain carries them up into the air, so that
only granite outcrops over the whole southern part of the ridge. At the
Castle Creek fault, as in Section B, the overturned Triassic sandstones
come in aud continue to the end of the section.

RESUME OF STRUCTURE SHOWN ON THE ASPEN SPECIAL MAP.

First. The first deformation in the rocks, changing them from their
original structure, was folding, which is partly illustrated by the mono-
clinal, steeply dipping strata of Section A (Atlas Sheet X).

Second. Probably contemporaneous with this folding there occurred a
slipping of different layers one upon the other, producing a system of
faults nearly or quite parallel with the bedding, of which the Silver fault
is the most important representative. These faults follow in a general
way the folding in the rocks, and are faulted by all the other fault systems.

Third. At some early stage in this deformation there took place a
local uplifting of the rocks, cluding the sedimentary formations and the
underlying granite, which produced a marked and abrupt domelike struc-
ture. There is reason to believe that this took place at a somewhat later

ASPEN SPECIAL MAP. 83

date than the regional foldmg. This uplift was due to local disturbing
forces, and seems to have been contemporaneous with the initiation of the
first fault systems.

Fourth. There originated a system of faults having a general north-
south trend and in general a nearly vertical dip. The greatest of these
is the Castle Creek fault, and from this toward the east the parallel faults
grow successively less in importance till the system dies out before
reaching East Aspen Mountain. All of these faults are characterized by
having their greatest development on Aspen Mountain, from which point
they diminish in throw to the north and to the south. Several of them
have very great displacement, and they all were almost entirely devel-
oped previous to the deposition of ores, for it is along them that much of
the ore has been found. ‘This system is, however, of younger age than the
Silver system of faults, since it faults this latter system in the same way
that it does the inclosing rocks. To the Aspen Mountain system, also,
belong certain nonpersistent cross faults, which, however, have often
considerable throw. Such are the faults at the north end of West Aspen
Mountain, and those of the Bonnybel and Chloride system. Their prob-
able identity in age with the main north-south faults is shown by the fact
that they also are highly mineralized. It appears probable that this
system of mainly north-south premineral faults was developed at about
the same time that the doming-up of the rocks on Aspen Mountain
occurred, and that the phenomena of faulting and folding are both
manifestations of the same upthrusting power.

Fifth. The faulting which has thus been described apparently con-
tinued during and after the period of ore deposition. The Della system of
faults on Smuggler Mountain evidently existed previous to the period of ore
deposition, for it is along these faults, at their junction with the Silver, that
much if not most of the ore on Smuggler Mountain has been deposited.
The barrenness of. much of the slipping planes, however, and the fact that
along these barren planes there are often fragments of hard ore found in
the breccia, show that much of the movement has gone on subsequent to
the ore deposition; and, indeed, it is probable that the faults in some cases
have had their main development since that period. There is also evidence
that the movement along these faults is still going on, this evidence being
derived from the deformation of mine workings. These faults, which have

84 GEOLOGY OF ASPEN MINING DISTRICT, COLORADO.

an east-west trend and a flat southerly dip, therefore belong to a somewhat
later period than the Aspen Mountain system.

Sixth. On East Aspen Mountain there are found the representatives of
a system of north-south and in general vertical faults, which has its maim
development in Tourtelotte Park. From this point of maximum develop-
ment the system dies out to the north and to the south. So far as can be
judged it is entirely later than the ore deposition, and therefore later than
the Della system. The Clark fault on Smuggler Mountain may be included
in this last system.

TOURTELOTTE PARK SPECIAL MAP.

The general attitude of the formations on Aspen Mountain undergoes
a marked change to the southward, so that the strike changes from east to
northeast and finally swings round and becomes permanently north. This
change is evidently antecedent to the faulting which forms such a conspicu-
ous part of the geology in this region. The main features of-folding are
the same in the Tourtelotte Park district as in Aspen Mountain, but they
are less accentuated. The deep broken syncline of Aspen Mountain is
continuous into the north end of the Tourtelotte Park special area, but
becomes continually shallower toward the south, until at about the
southern end of the Tourtelotte Park mining district it has virtually
disappeared. The flattening of the beds on East Aspen Mountain is also
continuous into the Tourtelotte Park district, where it is developed into
an anticline, which is in many places obscured by subsequent faulting.
There also appears in the Tourtelotte Park area a second syncline to the
east of the anticline, which lies next the granite; but in many places this
syncline has been uplifted by faulting and removed by erosion. These
gentle folds become less marked toward the south, and finally die out. The
line of the Castle Creek fault is not strictly parallel with that of the contact
of granite and sedimentary rocks, but the two lmes converge toward the
south, so that the width of the belt occupied by the lower stratified rocks
becomes continually less. The rocks to the west of the Castle Creek fault
have an entirely independent structure, so that the gentle anticline and
syncline referred to are gradually cut out by the encroachment of the
Castle Creek fault. The main anticline, whose axis practically coincides
with the divide between Roaring Fork and Castle Creek throughout the

OE EL EE EE EEE EE Ee ee ee

a

TOURTELOTTE PARK SPECIAL MAP. 8&5

whole extent of the Tourtelotte Park special area, becomes in its turn a
gentle monocline, dipping into the Castle Creek fault, and in the southern-
most part of the area the remnant of this anticline is united with the
easternmost syncline to form a single simple monoclinal structure.

Within this district, bounded on the west by the Castle Creek fault
and on the east by the granite, there is an excessively complicated system
of faulting. The faults may be separated imto various distinct systems,
but all have apparently an interdependence. A very conspicuous system
runs nearly parallel to the Castle Creek fault and to the contact of granite
and sedimentaries, and therefore nearly parallel to the longest axis of the
wedge-shaped area included between these two boundaries. Another,
weaker, but not less conspicuous, system runs at right angles to the first,
parallel to the shortest axis of the area. Wherever these faults intersect
the Castle Creek fault, as is often the case with the east-west system, they
usually seem to disappear. Occasionally, however, an east-west fault
seems to displace the Castle Creek fault, thus showing its later age; but
even in this case the cross-cutting fault probably disappears a_ short
distance away from the Castle Creek fault to the west.

On the western side of the main Castle Creek break there is no
evidence of any such complicated system of intersecting faults as is found
on the east. There is, however, a system of faults which are nearly par-
allel with the main Castle Creek break and which are evidently dependent
upon it; but these faults are quite distinct in nature from the Tourtelotte Park
types. In the great mass of Maroon and Triassic sandstones immediately
west of the Castle Creek fault, and also in the Weber shales and limestones
which occur on the west side of the fault im the southern part of the Tour-
telotte Park special area, it is hard to distinguish slight faulting, owing to
the similarity in lithological composition of the beds through great thick-
nesses; but from all the data that can be obtained it seems that the
Tourtelotte Park type of faults is either absent in these beds or has become
so unimportant as not to be easily recognized.

On the eastern side of the Tourtelotte Park special area the contact
of the granite with the overlying beds constitutes an effectual barrier to
further investigation of structure. It is probable that many of the faults
are continuous into the granite for indefinite distances, for the faulting

D

along the contact of granite and Cambrian quartzite is often very strong

86 GEOLOGY OF ASPEN MINING DISTRICT, COLORADO.

and complicated. Once past the line of contact, however, we have no
method of ascertaining the number, system, or amount of throw of these
faults, or any positive proof of their existence, so that the faulted area to
be studied must be considered as essentially comprised between the Castle
Creek fault and the granite-quartzite contact .

The amount of disturbance which has taken place in this area, as
indicated by the occurrence of these numerous intersecting faults, is appar-
ently greater in the northern part of the Tourtelotte Park special tract, or
in about the area occupied by the Tourtelotte Park mining map (Atlas
Sheet XX1), than in any other part of the entire district examined in the
course of the survey. The southern part of the Tourtelotte Park special
tract has a similar but somewhat less complicated system of faulting, and
the two halves of the tract may be conveniently considered as representing
slightly differmg areas. These two areas may be separated at the line of
the Butte fault, which traverses the whole district from east to west.

The faults of the northern half show a continuation of the characteris-
tics of those of Aspen Mountain, together with the development of new
features. The most characteristic of the Aspen Mountain faults gradually die
out in the Tourtelotte Park district, while faults which are unimportant on
Aspen Mountain, or which are even totally absent, become well marked and
important in Tourtelotte Park. Thus the great north-south break called
the Pride fault, which on Aspen Mountain splits into two branches, dimin-
ishes in importance gradually toward the south, so that the throw becomes
comparatively slight in the Tourtelotte Park district. On the other hand,
there is another system of north-south faults, which is parallel with the
system of the Pride and the Saddle Rock, but which has its greatest devel-
opment in Tourtelotte Park and becomes continually less important toward
the north, finally dying out or merging into the Silver fault. To this class
belong the Justice and Copper faults, also the Ontario and other parallel
breaks which are exhibited to the east of the Copper fault. This second
system is apparently younger than the system represented by the Pride,
Sarah Jane, and allied faults. It is evident that the former system has
developed mainly subsequent to the period of mineral deposition, while
the Pride or Aspen Mountain system must have been nearly completed
before the deposition of the ores, since it is along these faults that the ores
are most conspicuously formed. The younger system, however, which is

TOURTELOTTE PARK SPECIAL MAP. 87

represented by the Justice, is not mineralized; but the faults belonging to
this system fault the ore bodies as well as the inclosing rocks. The faults
belonging to the Justice system have apparently a maximum throw close
to the topographical basim which was originally denominated Tourtelotte
Park; from this point they disappear gradually toward the south, and more
rapidly toward the north, so that they are comparatively unimportant or
wanting in the Aspen special area, and diminish in importance in the south
half of the Tourtelotte Park special area. A common accompaniment of
such diminution toward the north is a change in trend, which veers from
north to northwest, so that the faults of this system approach the Silver
fault.

Running directly across the north-south faults is a system of east-west
faults, which are of much less persistence. Sometimes they traverse only
the space between two adjacent north-south faults; sometimes, however,
such a fault traverses two or three north-south faults; and the Butte fault,
which is a member of this system, cuts through the entire district, even
across the Castle Creek fault. The intersection of the east-west faults with
the north-south faults produces a system of blocks; and these blocks have
been moved one upon the other, so that the resultant structure becomes
very complicated. Such blocks may have an independent movement which
is not partaken of by any of the adjoining blocks; again, two or three
blocks, or even more, may have moved together, having a uniform amount
and direction of movement with reference to the adjacent mass. The study
of these faults has made it appear, moreover, that the movement, instead of
taking place at one time, went on gradually for a very long period, so that
at a certain stage a block has apparently moved independently with relation
to the surrounding blocks and at a different time has united with the sur-
rounding blocks in some more extensive movement. The result of this
continual up-and-down shifting of the minor blocks is that the throw of any
persistent north-south fault which traverses these blocks varies considerably
from place to place, although the general movement of this larger fault
remains ordinarily the same under all conditions.

The more important faults will now be described separately, in order
that the peculiarities of each may be understood as they appear upon pub-
lished maps, and in order that the general structure of the district may be
more thoroughly presented.

88 GEOLOGY OF ASPEN MINING DISTRICT, COLORADO,

Silver fault system —''9 this system belong a number of faults which are
nearly or quite parallel to the bedding of the strata in which they occur.
There are many of these found in nearly all of the formations in the district,
but certain ones are so persistent and continuous that they can be easily
traced for considerable distances. One of these faults, called the Contact
fault, occurs between the blue Leadville limestone and the underlying
dolomite. As far as can be seen, it does not cut across the beds, but runs
strictly parallel to them, thus nearly always forming a true division between
the two members of the Leadville formation. This fault has not been shown
on the 800-foot map or in the 800-foot sections, but is found always at
about 250 feet above the bottom of the Leadville formation. In the 300-
foot sections made across the Tourtelotte Park mining map the Contact fault
is shown, as determined by outcrops and mine workings.

A still more important fault may be called the Silver fault. This
oceurs at a horizon only about 150 feet, or often not more than 100 feet,
above the Contact fault, and usually has, in this district, the blue Leadville
limestone on one side and the soft shales of the Weber formation on the
other. Developments in the mines show that there has been an immense
amount of movement along this fault, resulting in the formation of a breccia
made up of the limestone, shale, and porphyry, which is often as much as
50 feet thick. It seems that the effect of this fault in the Tourtelotte Park
district has been to reduce the thickness of the shale below the porphyry.
From sections in other places it appears probable that there was an original
thickness of about 250 feet of shale between the porphyry and the lime-
stone, while in the Tourtelotte Park district there lies between the two only
about 50 feet of shale, generally crushed and broken, and even this is
sometimes wanting, so that the porphyry rests directly against the limestone.

The Silver fault is shown in the 800-foot map and sections. It crops
continuously on both sides of the main ridge to the west of Spar Gulch in
TYourtelotte Park, dipping slightly into the hill east and west on either side
with the strata which form the continuation of the Aspen Mountain syncline.
Inasmuch, however, as this syncline retains its northerly pitch, which is
steeper than the surface slope, the outcrop of the Silver fault becomes higher
and higher, so that it finally passes above the surface, and is not found at all
in the southern part of the district. The Contact fault, since it lies a short dis-
tance stratigraphically below the Silver fault, persists a little farther to the

TOURTELOTTE PARK SPECIAL MAP. 89

south, but this also passes above the surface a short distance south of the
central part of the district, and, like the Silver fault, is not found farther
south. Since these two faults are among the most important factors in
determining ore deposition, it may be understood why the southern part of
the Tourtelotte Park special district to the east of the Castle Creek fault is
practically barren.

The fact that the Silver system of faults has been more than anything |
else the locus of ore deposition, shows conclusively that the faults originated
before the mineralization. The fact that all the other systems of faults,
both postmineral and premineral, have displaced the Silver system in pre-
cisely the same degree as they have the adjacent strata, indicates that the
Silver system was formed at an earlier period than the others, and it may be
supposed that it was contemporaneous with the folding of the strata, being
the result of the slipping of one bed over the other in the course of plication.

Castle Creek fault — The Castle Creek fault is definitely traceable throughout
the whole length of the Tourtelotte Park special district. Beginning at the
north and following its outcrop south, it may be found separating the red
Maroon sandstones from the Archean granite on the mountain side between
Keno and Ophir gulches; southward it is distinctly shown in Ophir Gulch;
from there it is traceable across the intervening ridge into Queens Gulch.
It then runs southeast in the very bottom of this gulch for some distance
until the gulch curves abruptly east, as shown on the topographical maps.
At this point the fault does not turn with the gulch, but continues on, finally
leaving the district close to the Surprise shaft. Through the whole distance
the fault is shown on the surface by outcrops and underground by tunnels.

At the point where the Castle Creek fault crosses Ophir Gulch there
are red Maroon sandstones on its west side, with granite on the east. In
the bottom of the gulch, however, come in narrow wedges of porphyry and
Weber shale, rocks which underlie the Maroon sandstones on Red Moun-
tain and the rest of the district. These wedges of porphyry and shale
widen toward the south, until at the southern limit of the district nearly
the entire normal thickness of Weber and of porphyry outcrops. Although
these formations are very nearly in their normal position, their thinness at
the northern end of their exposure and their contact phenomena show that
they are brought into position by faults which are nearly parallel to the
Castle Creek fault and are dependent upon it. Since the general dip of

90 GEOLOGY OF ASPEN MINING DISTRICT, COLORADO.

the beds of the west side of the Castle Creek fault is nearly parallel with
the dip of the fault itself, it follows that these slips are nearly parallel
with the beds which they traverse. Their action is to bring up wedges of
the different formations against the Castle Creek fault sooner than these
formations would come up with the normal structure. The dip of the
faults, however, is not exactly coincident with the dip of the beds; the
blocks brought up, therefore, are wedge shaped, and in cutting across such a
series of slips the various formations are encountered in their normal order,
but usually very much reduced from their normal thickness, and are locally
sometimes entirely absent. This structure is shown in the Dubuque tunnel
in Queens Gulch, which cuts across the steeply dipping beds on the west side
of the fault and finally crosses the fault itself into the granite. . In passing
through this tunnel, which is over 800 feet long, the first solid rock encoun-
tered is the gray micaceous limestone, which is recognizable throughout the
district as lying at the base of the Maroon formation. Beyond this is a
considerable thickness of black Weber shales; then comes a large mass of
porphyry, which in turn gives way to another body of shale. Near the
end of the tunnel, just before reaching the granite, there is a highly altered
and mineralized zone, which has apparently all the characteristics of
altered blue limestone of the Leadville formation. This succession is that
normally found going downward from the base of the Maroon to the top of
the Leadville formation, although in this place the beds are dipping steeply
to the east and are therefore locally overturned and in the reverse of their
usual position. Although the succession is normal, the thickness of the
various formations is much less in this section than usual, as is shown by
comparison with the beds on Red Mountain and on the ridge south of
Queens Gulch. The Weber shale, for example, which lies between the
porphyry and the Maroon gray limestone, and which normally has a thick-
ness of not far from 1,000 feet, is here only about 200 feet thick. The
porphyry, of which there should be normally 300 or 400 feet, is here only
about 200 feet thick, while the shale underlying the porphyry, which is
normally 250 feet thick, is here 100 feet or less. The mineralized zone
which has been taken as altered blue limestone is a narrow strip along the —
fault, averaging 50 or 60 feet, while the normal thickness of the Leadville
blue limestone is about 150 feet. The contacts of these various formations,
as exposed in tunnels, are always greatly brecciated, showing that they are

TOURTELOTTE PARK SPECIAL MAP. oi

true fault contacts. These dependent faults, however, are active only in
the immediate vicinity of the Castle Creek fault, so that when the normal
dip of the beds brings the porphyry and the Weber shales to the surface,
and the divergence between the strike of the beds and the trend of the
Castle Creek fault causes a separation of these beds from the fault, their
thickness seems to be normal, and not increased or diminished by any
dependent faulting.

Since the elevation of the hills is greater at the southern end of the
Castle Creek fault as exposed on the Tourtelotte Park special map than it
is on the north end, and since in spite of this fact the beds which are
exposed on the western side of this fault belong to horizons growing succes-
sively lower southward, it follows that there has been a marked elevation
of the beds in the southern part compared with those farther north. On
the east side of the Castle Creek fault, however, the reverse is true; for
southward are successively higher and higher formations. In the northern
part of the area mapped, for example, there lies on the east side of the
Castle Creek fault a great body of granite. On going south along the
fault, one passes in the neighborhood of Ophir Gulch from granite into
the overlying quartzite, which here comes into contact at the surface with
an uplifted wedge of Weber shales; farther south one passes from quartzite
into Silurian dolomite, which in the neighborhood of the Dubuque tunnel
outcrops on the eastern side of the fault, abutting against shale or quartz-
porphyry on the western side. The more recent Butte fault has so operated
that south of hero the Cambrian quartzite again outcrops along the east
side of the fault for some distance. During most of the distance that the
Castle Creek fault runs in Queens Gulch it has this quartzite on the east,
with the Weber shale becoming very thick on the west. Near the head
of Queens Gulch the rocks on the eastern side of the fault change from
Cambrian quartzite back into Silurian dolomite; farther up the dolomite
gives way to diorite-porphyry, which in turn is replaced by the dolomite
belonging to the Leadville formation, so that at the limit of the mapped
area on the south the fault separates Leadville dolomite from quartz-
porphyry. This succession of beds on the east side of the fault» shows that
there has been no such tilting as occurred on the west side. If any tilting
has oceurred it has been exactly the reverse, and the southern part of the dis-
trict has undergone a slight depression as compared with the northern part.

92 GEOLOGY OF ASPEN MINING DISTRICT, COLORADO.

In the southern part of the area of the Tourtelotte Park special map
the effect of this elevation of the beds on the west side of the fault and
the corresponding depression of the beds on the east side is to diminish the
throw very rapidly toward the south. Thus the amount of displacement
near the southern end of the area appears to be about 2,600 feet (see Sec-
tion F, Aspen district map, Atlas Sheet VII); in Queens Gulch the dis-
placement is about 6,300 feet; while at the northern end of the area it is
probably as high as 8,000 feet (see Section D, Aspen district map).

The diminishing of the Castle Creek fault is accompanied by a corre-
sponding dying out in intensity of the associated folding. The close
overthrown fold which is shown at Castle Butte and at the western base of
Aspen Mountain becomes progressively more open toward the south, and
the easterly dip of the overturned beds becomes progressively steeper. In
Keno Gulch the red sandstones dip toward the east at an angle of 45
or 50 degrees; in Ophir Gulch, however, the beds dip east at an angle of
about 70 degrees. At about the point where the fault enters Queens
Gulch the beds become actually perpendicular; southward from this point
they assume a westerly dip, thus marking the end of the overthrown fold;
and from this point on the beds lie in their normal succession, always
dipping to the west at an angle which grows less toward the south. The
close overthrown fold of Aspen Mountain is thus replaced by an extensive
open fold, several miles in width. The fact that the fold shows sions of
dying out in the lower formations and becoming more complicated in the
upper ones, being very much less in the lower Maroon and Weber beds of
Queens Gulch and vicinity than in the Cretaceous beds of Red Butte, may
indicate that in the original fold the amount of deformation was greater in
the upper beds than in the lower throughout the whole of the district, and
that if erosion in the vicinity of Red Butte should reveal the underlying
formations corresponding to those exposed in the vicinity of Queens Gulch
there would appear in these formations a much simpler foldmg than occurs
in the beds actually exposed. From this point of view the beds west of
the Castle Creek fault form an overthrown fold, whose axis pitches north-
ward. Erosion, acting more vigorously on the uplifted portion, has stripped
the fold fault down to near its roots in the southern part of the district
mapped, and quite down to its roots where the fold and fault merge into
the granite at a point not far south of the limits of the map.

TOURTELOTTE PARK SPECIAL MAP. 93

Corresponding with the steepening toward the south of the easterly
dipping beds on the western side of the fault is a steepening of the fault
plane itself’ While in Keno Gulch it appears to be 45 or 50 degrees to the
east, as shown in tunnels, in Queens Gulch it is as much as 80 or 90
degrees to the east. At the extreme southern end of the district it has
become nearly vertical, with still an easterly tendency. If we consider, as
has been suggested, that at the southern end of the district are the roots of
an original overthrown fold, which culminated in the faulting, then the
gradual steepening of the fault plane toward the south shows that the main
fault has a curved form, becoming steep and possibly overturning in depth,
while in the higher formations it has a dip approximately corresponding
with the main axis of the overthrust fold, and consequently with the dip of
the strata.

Saddle Rock fault— This name is given to the eastern of the two branches
into which the Pride fault splits on West Aspen Mountain. The Pride
fault itself, as has been stated, has a downthrow to the east of about 2,000
feet, and is thus, since it has a very steep dip to the east, a normal fault.
After it splits into two branches its throw is divided. The Saddle Rock
fault is continuously traceable from the area of the Aspen special map into
that of the Tourtelotte Park special map.

In Section A, Tourtelotte Park special map (Atlas Sheet XIII), the
throw of the Saddle Rock fault is shown to be about 500 feet; in Section
B, farther south, it is about 300 feet; in Section C it is about 200 feet; in
Section D about 100 feet, and in Section EK about the same. These figures
show a constant diminution in throw, and it is probable that the fault dies
out in the southern part of the area mapped or merges into the Castle
Creek fault. The explanation of this diminution of throw in the Saddle
Rock fault is the same as for the Castle Creek fault, namely, a differential
movement consisting of a slight elevation of the southern end of the district
on the east of the fault, and a marked depression on the west side. Thus,
im going along the western side of the fault from the northern edge of the
district toward the southern, we pass from the Archean granite up into
the Cambrian quartzite, and from this into the Silurian dolomite. This
dolomite outcrops in the neighborhood of the Saddle Rock shaft. On the
eastern side of the fault, however, there is no change in formation in going
this distance, so that while at the northern edge of the district the fault

94 GEOLOGY OF ASPEN MINING DISTRICT, COLORADO.

separates the blue Leadville limestone from the granite, near the Saddle
Rock shaft it separates the same limestone from the Silurian dolomite.
Still farther south this differential movement causes the faulting to become
so slight that on the mountain side above Queens Gulch there appears to
be Silurian dolomite on both sides of the fault.

Along this fault, both in Aspen Mountain and in Tourtelotte Park,
there has been considerable mineralization, showing that the fault is older
than the ore deposition.

Sarah Janefautt——The Sarah Jane fault runs close and parallel to the
Saddle Rock fault; it is apparently of the same age, and has the same
characteristics. Like the Saddle Rock, it has formed an important locus
for the deposition of ores, and like the Saddle Rock, its movement becomes
progressively less toward the south, while on Aspen Mountain, as above
noted, it has its maximum throw. This throw, however, diminishes much
more rapidly southward than does that of the Saddle Rock fault. In
Section A of the Tourtelotte Park special map (Atlas Sheet XIII) the throw
seems to be only about 150 feet; in Section B it is only about 100 feet.
In Section C it appears from the map to have increased to about 300 feet,
but this apparent increase is due to a local downthrust of the rocks east of
the fault, in the wedge between the Sarah Jane and Justice faults. Just
south of Section C, however, the Sarah Jane and Justice faults finally
come together, and the wedge between them disappears; these faults, after

uniting, seem to have only a very trifling amount of disturbance, and are

g;
not definitely traceable any great distance to the south.

Justice fault—The Justice fault is so called because of its chief develop-
ment in the Justice mine in Tourtelotte Park. This is the first north-south
fault of any consequence to the east of the Sarah Jane. It does not,
however, belong to the same general series as do the Saddle Rock and Sarah
Jane faults, and presents certain marked characteristics which put it into a
different class. Instead of having its greatest development on Aspen
Mountain and a diminishing throw to the south, it has its greatest develop-
ment in Tourtelotte Park itself, whence its throw diminishes both to the
north and to the south.

In the park its maximum movement seems to be a downthrow of about
400 feet to the east (Section B, Tourtelotte Park special map). South of
this the throw diminishes rapidly, so that the null point is apparently

TOURTELOTTE PARK SPECIAL MAP. 95

reached in the southern part of the topographical basin known as Tourte-
lotte Park. In Section C, Tourtelotte Park special map, the Justice fault
appears to have an upthrow to the east of about 100 feet, but this is only
local and is owing to the downfaulting of a narrow wedge-shaped block
included between the Justice and Sarah Jane faults, near the pomt where
they converge and meet. The effect of the downfaulting in this block is to
reverse the throw of the Justice fault, and to give the Sarah Jane an
increased downthrow of 100 feet or so. Beyond the point where the Sarah
Jane and Justice faults meet, neither can be traced any great distance to
the south, and it is probable that both die out soon after uniting.

To the north of the point of greatest development of the Justice fault
there is a more gradual dying out of the throw, and the fault runs in the
bottom of Spar Gulch to Copper Gulch, where it unites with the Copper
fault and with what is known on Aspen Mountain as the Chloride fault.
The Chloride fault, as exhibited in the Bonnybel mine, has a northwest
trend and a southwest dip, and a downthrow to the northeast of 100 feet
or more. Both the Justice and the Copper faults, but especially the latter,
have diminished materially in throw by the time they come together.

The displacement of the Justice fault in Spar Gulch is always a
normal downthrow to the east, except where the movement has been
complicated by east-west faults of later origin. On account, also, of these
complicated east-west faults the average movement of the Justice is hard
to determine, but it seems to be about 250 feet in Spar Gulch.

The Justice fault belongs to a different system from the Saddle Rock,
Sarah Jane, and other faults belonging to the Aspen Mountain series.
While the faults of the Aspen Mountain series have been important loci of
mineral deposition, the series represented by the Justice fault has undoubt-
edly developed since the ore deposition. Apparently no ores have formed
in place in connection with this latter system, but the faults have displaced
the preexisting ore bodies, together with the inclosing formations.

Copper fault—T he Copper fault has been given its name from Copper
Hill, on the east side of which it runs. Copper Hill, in turn, has obtained
its name from the Copper King shaft, which is situated on the top of the
hill; but the name in either case does not imply any great abundance of
the metal. This fault is one of the north-south series, and runs very nearly
parallel to those already described. It has the characteristics which have

96 GEOLOGY OF ASPEN MINING DISTRICT, COLORADO.

been referred to in the case of the Justice fault, and therefore belongs
to the Tourtelotte Park or postmineral system rather than to the Aspen
Mountain or premineral system. Its greatest displacement is very close
to the corresponding displacement in the Justice, being on the edge of
the Tourtelotte basin.

In this place it has an upthrow to the east of about 400 feet; but
northward the throw diminishes with comparative rapidity. It is normally
an upthrow to the east, but locally (see Section A, Tourtelotte special map,
Atlas Sheet XIII) there is a downthrow to the east in consequence of
faulting produced by the later east-west faults. Toward the north, also,
the dip of the fault, which at the point of its maximum throw is appar-
ently quite steep to the west, becomes progressively flatter, causing the
approach of its outcrop toward that of the Justice fault, until, at the june-
tion of Copper and Spar gulches, the two faults unite. It may be observed
that for a considerable distance above the line of the junction of these two
eulches the faults lie directly in the beds of the gulches and that the
eulches themselves have been determined by the faults. As the Copper
fault nears the point of junction with the Justice fault, the flattening of
the dip of the fault combines with the decrease of the throw to cause the
apparent displacement to become comparatively insignificant, so that at
the point of junction with the Justice fault it has already nearly died out.

South of the point where the fault has its maximum throw in Tourte-
lotte Park there is the same phenomenon of swift diminution as in the case
of the Justice. The Copper fault was not traced beyond the Butte fault,
and probably does not continue very far beyond this point.

Ontario fault The Ontario fault is so called because it hes at a point on
the hillside a short distance above the Ontario tunnel, although it does not
actually cut it. This fault has the same general characteristics as the Jus-
tice and Copper faults, so that it has been classified with the Tourtelotte
Park system rather than with the Aspen Mountain system. Like the Justice
and Copper faults, it has a maximum throw in Tourtelotte Park, from which
maximum it diminishes rapidly in both directions. Like these faults, also,
its prevailing movement is a downthrow to the east; and like them it is
younger in age than the ore deposition, and is therefore a postmineral fault.

Tts maximum throw occurs about the middle of the area of the Tourtelotte -

Park special map, bemg a downthrow to the east of about 1,00 ) feet (see

TOURTELOTTE PARK SPECIAL MAP. 97

Section D, Atlas Sheet XIII). On Section B to the north and Section E
to the south an equal apparent displacement is exhibited, the downthrow
measuring about 800 feet. Between Sections B and D there is appar-
ently a block in which the Ontario fault is not developed. This block
lies between the Buite fault and the next east-west fault to the north. This
east-west fault is apparently a continuation of the Good Thunder fault of
Tourtelotte Park, but has a much greater throw. On the south side of this
block, however, the outcrop of the Ontario fault reappears in exactly the
same line, with the same amount and direction of throw as on the north
side. There can, therefore, be no doubt that it is the same fault. The reason
why the fault does not outcrop in the block above referred to is not quite
evident. Exposures are not very abundant in this intervening space, but
so far as they are present they seem to consist entirely of granite, which
shows that the Ontario fault is probably absent. It is possible, however,
that the fault may actually exist with a diminished or locally altered dis-
placement. 'To the north of Section B the fault may be continuously traced
out of the area of the Tourtelotte Park special map into that of the Aspen
special map, where it is found running nearly along the crest of Hast Aspen
Mountain. Between Sections B and A, however, the single fault seems to
split into several parallel faults, which divide up the total throw between
them, so that in Section A the displacement of that fault which is apparently
the continuation of the main Ontario fault entails only about 100 feet down-
throw to the east. In the same sections, however, there appears a second
parallel fault, farther to the east, which is evidently closely associated with
the main fault. This second fault has a downthrow to the east of about 500
feet, so that the two together make up a downthrow of about 600 feet, which
is the displacement that might naturally be expected. Farther to the north
there appear (still in the area shown on the Tourtelotte Park special map)
three such faults, which are continuous into the area of the Aspen special
map. In that area these faults rapidly die out, and their displacement is
additionally complicated by east-west cross faults. In the blocks produced
by the intersection of these cross faults with the main north-south faults the
disturbance has often brought about tilting, reduction of the amount of dis-
placement, or even reversal of the normal movement. These disturbances
“tend to counteract each other, so that on the north edge of the crest of East
Aspen Mountain the aggregate displacement has become comparatively
MON XXXI-——7

98 GEOLOGY OF ASPEN MINING DISTRICT, COLORADO.

slight, and probably nearly dies out on the northwestern slope of the moun-
tain. At this point the north-south faults of the Ontario system swerve to
the northwest from the north and approach the Silver fault.

Owing to the diminution in throw of the Ontario fault toward the
south, at the southern edge of the Tourtelotte Park special map (Atlas Sheet
XI) the downward throw to the east is only about 250 feet, as shown in
Section F. Ifthe throw continues diminishing at this same rate the fault
must entirely die out in a short distance.

Butte fault system——The Butte fault is in some respects the most important
and persistent of a numerous class of parallel faults which are well devel-
oped in the area represented by this map. It has already been remarked
that in some respects the area may be divided into a northern and a south-
ern district, separated by the Butte fault. Keeping this arbitrary division
in mind, it may be observed that the east-west faults of the Butte system
are considerably more numerous and important in the northern part than
in the southern. In the southern part there seems to be a comparative
uniformity in the displacement, which is mostly a successive downthrust
of the blocks between them to the south. In the northern half, however,
there is no great uniformity in the displacement. The faults are more
numerous and heavier than in the southern part, and the blocks melosed
between them have been irregularly shifted up and down. The Butte
fault, which has been taken as the dividing line between these two slightly
differing districts, partakes of the peculiarities of the southern part, having
a maximum upthrust to the north of about 400 feet. As is shown by the
north-south sections, the throw of the Butte fault is diminished on the main
ridge directly south of the Tourtelotte Park basin (see Section H, Atlas
Sheet XV) to 50 feet; but this diminution is due to independent movement
of neighboring blocks in this much agitated area, and the throw as meas-
ured in Sections G and I is rather to be taken as the normal one.

In this northern part of the Tourtelotte Park area the east-west faults
are much more numerous and important than anywhere else in the whole
district. Their intersection with the several north-south faults has produced
many separate blocks. In the movement which has apparently gone on
since the formation of these blocks each one seems often to have had an
independent action, sliding up or down without any great dependence on
the motion of the adjacent masses. Since in this district the strata do not

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TOURTELOTTE PARK SPECIAL MAP. 99

have steep dip, but are flat when compared with the dip of the beds on Aspen
and Smuggler mountains, the resultant surface geology as now exposed by
erosion is rather more complicated than anywhere else, and in many places
presents a confused checkering. Were it not for the fact that the erosion
of the glaciers has usually stripped these surface rocks and left them com-
paratively bare, it would be often impossible to decipher the structure; but
fortunately the outcrops are very numerous in some of the most compli-
cated places. A good example of this is the geology of the hill just east of
Copper Gulch, near the extreme northern edge of the area mapped. Pl. IV
is a view of this hill from across Spar Gulch, and at that distance shows
how the complicated geology is sketched out on the side of the hill as on
a map. The hill referred to les in the foreground of the picture. The
reader, on viewing the plate, is looking toward the east, and the left-
hand side of the picture corresponds very nearly to the northern end of
the Tourtelotte Park special map. By comparing the map with the plate
the geology of the hill as shown in the picture may be understood. At the
left-hand end of the picture there is found a normal contact of Silurian
dolomite and Cambrian quartzite, which here strikes east and west and dips
north. This contact is not visible on the plate, but is shown on the map.
A short distance south of this an east-west fault brings down the dolomite,
so that it outcrops to the south of the quartzite again. This dolomite
occupies a portion of the left-hand side of the picture, immediately under
the pronounced sag in the outline of the hill) A short distance south of
this another cross fault brings up the Cambrian quartzite again. This
quartzite 1s seen outcropping in a white streak running down the hill just
north of the central part of the picture. Southward again there appear
successive faults, belonging to the same east-west system; the first brings
up the dolomite shown in the dark area in the very center of the picture;
the next fault south brings up the quartzite, and still another has restored
the dolomite. This last outcrop of dolomite is seen in the right-hand side
of the picture, its lower end being obscured by the intervening spur of
Copper Hill. To complicate this numerous system of east-west cross
faults, there is a flat, easterly dipping fault, which apparently has a north-
east trend, and is a sort of splinter between the Copper and Ontario faults.
This flat fault may be noticed in the plate, running nearly horizontal, not far
from the top of the hill. It operates so that the middle belt of dolomite is

100 GEOLOGY OF ASPEN MINING DISTRICT, COLORADO.

widened in outcrop, and the belts of quartzites which bound it on each
side are thrust away to the right and to the left. There are also numerous
minor complications in the structure of this hill, some of which are shown
on the map. This is but one illustration of the complicated and puzzling
structure found in this district.

Many of the east-west faults are continuous across only one interval
between neighboring north-south faults. Others traverse two or three such
intervals, while some, as the Butte fault, cross the whole district. This
Butte system, therefore, is less persistent than either of the north-south
systems which have been described, and the faults belonging to it have
usually much less throw than the faults belonging to those systems. Of
the faults whose throw can be measured with a degree of- certainty, the
Butte appears to be the largest, having a downthrow to the north of about
400 feet. The Grand Duke fault, in Tourtelotte Park, near the Butte
fault, is estimated to have a downthrow to the north of 200 feet; the Burro
fault has a downthrow to the south of about 150 feet; but there are many
faults in which the displacement averages less than 100 feet, which may
be a downthrow either to the north or to the south.

Age of east-west faults—he existence of ore in Tourtelotte Park along frac-
tures and small faults belonging to the east-west systems shows that this
set of fractures was originated before the ore deposition, probably about
the same time as the West Aspen Mountain north-south faults and as the
Castle Oreek fault itself. Ags examples of such mineralization, the Good
Thunder fault, which carries an important ore shoot, and the “canyon”
_ or shoot in the Justice mine, as well as similar shoots in neighboring mines,
may be mentioned. But nearly all the faults of this system which have
any important throw are barren, and apparently cut and dispose the ore
bodies and the inclosing rocks in the same manner, showing that the chief
movement was post mineral. This is also shown by the faulting of the
premineral faults, such as the Saddle Rock and the Sarah Jane, as shown
on the map; also by the faulting of the Castle Creek fault by the Butte
fault. . .

As to the relative age of the Justice system of north-south faults and
the Butte system of east-west faults, it may be noted that the fact that the
Butte system does not seem to fault the Justice system would indicate
that they are of nearly the same age. It must be borne in mind, however,

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IXxXX HdVHYSONOW

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TOURTELOTTE PARK SPECIAL MAP. 101

that the movement along these faults was not accomplished suddenly, but

has been a gradual process extending over long periods. The evidence is
conclusive that this has been the case with many, if not all, of the faults
of the Aspen district, and that many of them are even now in process of
formation. It is, however, also evident that the maximum amount of
movement in some was accomplished at a different time from that in
others, and the difference in time of this maximum movement in two
systems is taken as their relative age. So, while in the Justice system
the movement has occurred mostly since the maximum development of
the West Aspen system, yet there is no conclusive evidence of great
movement in very recent times. In some of the faults of the Butte
system, on the other hand, nearly all of the dislocation has been brought
about in very recent times, and there is good evidence to show that in
some cases these faults have developed entirely since the Glacial period.
The whole of the Aspen district, so far as examined, shows many proofs of
extensive glacial erosion, in the accumulation of morainal drift, the trans-
portation of bowlders, and the carving of the bed rock into rounded,
fluted, or drumlinoid forms. This glaciation occurred in such relatively
recent times that the forms resulting from it are still comparatively
unaltered by subaerial erosion. It is this fact which indicates the recent
age of the faults.

Perhaps the best example of these post-Glacial faults is the Butte
fault, the chief one of the east-west system. On going south on the west
side of the Tourtelotte Park basin, alone the divide between the basin and
the gulches on the west side of the hill, one passes from Weber shales
across the Sarah Jane fault to blue limestone, which outcrops on a flat-
topped hill. Proceeding along this flat-topped hill, one comes suddenly to
an abrupt escarpment or cliff, which is in large part nearly vertical, and
has a total height of about 400 feet. This striking topographical form has
received the name of Castle Butte.

Pl. V is from a photograph of this cliff, taken from a point across
Queens Gulch, at a distance of about a mile, and shows well the bold,
abrupt break, and the castellated structure produced by erosion. In detail
the butte presents several distinct variations. At the bottom there exists,
where not obscured by talus, a strikingly peculiar cliff, probably 150 feet
in height, which, in the plate, is shown just to the left of the highest point

102 GEOLOGY OF ASPEN MINING DISTRICT, COLORADO.

of the butte. This cliff is made up entirely of Silurian dolomite. Above
it come the sandy and shaly beds of the Parting Quartzite, which have
been eroded back so as to forma terrace. Next above is the Leadville
dolomite, reaching nearly to the top of the butte, which is of the blue
Leadville limestone. As may be seen in the plate, the Carboniferous
dolomite shows some evidence of subaerial erosion, presenting a steeply
sloping hill which carries some vegetation. The upper rocks are soft and
crumbling, and are often weathered into tall pinnacles. This castellated
structure is better shown in Pl. VI, which is a view of the butte taken from
a point on the scarp a little east of the main development of the cliff. In
the foreground the scarp is visible, although somewhat obscured by talus,
while in the center of the picture are some of the bold pinnacles and cliffs
which have been described. These structures are, of course, due to post-
Glacial subaerial erosion. It must be remarked, however, that the effects
of such subaerial erosion are much better marked at the top of the cliff
than lower down, so that there is a progressive tendency to freshness in the
outcropping rocks, and a diminution of the effects of erosion toward the
bottom of the cliff. The Parting Quartzite, occurring a little more than
halfway down, has been eroded back a few feet, forming a terrace on the
top of the Silurian dolomite, but the dolomite itself shows no extensive
weathering. The cliff which it forms is strictly perpendicular, having no
tendency to crumble or to form a sloping surface. The rock is hard and
fresh, well polished along its whole face, and heavily and unitormly
striated. From the base of the cliff these striz can be distinctly seen to
extend as high as 75 or 100 feet from the bottom; higher than that they
appear to be obliterated. They are plainest and freshest at the base, and
grow dimmer progressively toward the top. he line of this cliff is the
outcropping of the Butte fault, as is shown by the relations of the strata
on both sides. Below the cliff the Parting Quartzite outcrops a con-
siderable distance farther down the hill, showing a downthrow to the south
of about 400 feet, which, it may be remarked, is the total height of the
escarpment.

The strize on the polished surface of the dolomite cliff dip 70 degrees
to the west on the vertical face of the cliff and indicate by their form an
unmistakable downward throw on the south side. It seems clear that this
polished surface is the actual plane of movement of the Butte fault, and

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TOURTELOTTE PARK SPECIAL MAP. 103

that the striz were formed during the progress of this movement. The
question, then, which naturally arises is, Is the fault progressing faster in
its upward movement than are the processes of erosion in their degrading
action, or has erosion simply acted more vigorously along the fault plane?
If the latter is true, it must be that the erosion which has produced this
“escarpment is post-Glacial, for any glacial action would inevitably have
abraded the polished surface and removed all traces of the strie. Judging
from the effects of post-Glacial erosion as exhibited elsewhere in the district,
and even in the vicinity of the butte, one must conclude that it has not
been nearly so great in amount as to be able to accomplish such a work;
and even if such an amount of work were possible the same objection
holds good as in the case of glacial erosion, namely, that during the other
processes of degradation the striz along the fault plane must have been
obliterated.

The talus at the foot of the cliff was examined to see what might be
its main source, and it was found to consist almost entirely of fragments
derived from the Parting Quartzite or from the overlying Carboniferous
rocks. The distinction in lithological character between the dolomite of
the Silurian and that of the Carboniferous is usually slight, but in Castle
Butte there seems to be a distinction in texture by which the two rocks
may be separately recognized; and judging from this, there appears to be
in the talus very little material derived from the Silurian.

On both sides of the fault at this point are rocks which have about the
same degree of resistance to erosion, for opposite the Silurian dolomite in
the cliff there lies the corresponding dolomite of the Carboniferous. There
is therefore no apparent reason why erosion should have attacked the rocks
to the south of the fault more vigorously than to the north. Moreover, the
peculiar freshness of the strize at the bottom of the cliff and the progressive
effacing of these marks toward the top, together with the fact that the
amount of erosion becomes progressively greater and greater to the very
top of the butte, is evidence that the erosive forces have acted longest at
the top of the escarpment and practically not at all for a distance of 75 or
100 feet from the bottom; and even at the top the amount of erosion has
been comparatively slight. The only explanation of this seems to be that
the scarp actually represents the entire amount of throw of the Castle Butte
fault, and that this fault has come about almost entirely since Glacial time.

104 3EOLOGY OF ASPEN MINING DISTRICT, COLORADO.

Pl. VII gives a view of the perpendicular cliff of jointed Silurian dolomite,
with its polished and striated face.

Another fault, which appears to be post-Glacial and which belongs to
the same system, is the Burro. Where this fault crosses the ridge to the

west of Spar Gulch there is a marked north-facing escarpment, approxi-

mately 150 feet high, which is about the actual throw of the rocks at this °

point. Pl. VIII is a view taken from the west side of Castle Creek fault,
looking eastward across the intervening valley. The escarpment is seen at
the top of the picture against the horizon. If this is imagimed to be removed
and the right half of the hill depressed to a level with the left half, it will
be seen that the hill has the lenticular, drumlinoid outline which is so char-
acteristic of glaciated surfaces. There can be little doubt that this was the
actual form in which it was left by the overriding glaciers. The preserva-
tion of this smooth outline to the present day shows that there has been no
great amount of post-Glacial erosion; and since the amount by which this
typical drumlinoid outline has been displaced is exactly equal in amount
and direction to the displacement of the underlying rocks by the Burro
fault, it seems highly probable that the whole movement has come about
in post-Glacial times. The rocks which now outcrop on the hill are, on
the right side of the escarpment, porphyry, and on the left the blue Weber
limestones which underlie the porphyry. —

The Butte and Burro faults are probably the most interesting and
conclusive proofs of the recent age of some faults of the east-west system.
There is, however, considerable additional evidence in various places to
show that the movements along many of these faults are still going on, and
some of them are probably attaining their maximum development at the
present time. Along many of the faults in Tourtelotte Park there are
scarps, but it must be borne in mind that such a scarp is not necessarily
one of uplift, but may be a scarp of erosion. Such an erosion scarp may
occur along a fault which has not had great development since Glacial
times, and may result from the rapid wearing away of soft beds on one
side of the fault as compared with the slower degradation of the harder
beds on the other. In PL IX is shown such an erosion scarp, which was
formed in Glacial time. This is along the Sarah Jane fault. The plate
looks to the northwest. On the right side the surface is underlain by the
soft shales of the Weber, while on the hill to the left the blue Leadville

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TOURTELOTTE PARK SPECIAL MAP. 105

‘limestone crops out, and the fault runs along the base of the scarp. In
such a case as this, where the dislocation was accomplished mainly in pre-
Glacial time, the erosive action of the glacier must have scooped out more
of the soft shale than of the harder rock, and thus produced the scarp. It
is to this differential glacial erosion that the formation of the entire hollow
basin called Tourtelotte Park is due.

As a general distinction between scarps of erosion and those of uplift
in this region, it may be remembered that erosion scarps are likely to occur
where there is considerable difference in hardness of the rocks on the two
sides of the fault, and that in this case the scarp will probably be sloping.
The uplift scarp, however, may originate perfectly well where the rocks
have the same hardness on both sides, and such a scarp may have an
almost perpendicular face. Faults undoubtedly exist where the movement
was begun in pre-Glacial times, and still continues slowly, so that part of
the movement is pre-Glacial and part post-Glacial; and along these may be
formed scarps partly of erosion and partly of uplift. Pl. X shows the scarp
of the Silver Bell fault, which is perhaps an illustration of this. The hill
shown on the right side of the picture is made up of the hard limestones
and dolomites of the Leadville formation, while the flat surface shown in
the foreground is underlain by the soft black Weber shales. At the base
of the hill is the fault, along which there is a zone where the dolomite is
altered and silicified, so that it forms a sort of chert, which may be called
jasperoid. The maim searp is undoubtedly due in this case to glacial
erosion, but it is possible that a few feet of the cliff at the bottom, which
may be found where not obscured by talus from the hill above, may be
due to uplift since the Glacial period. This cliff is nowhere very strikingly
developed, and in this picture can be seen only just to the right of the
gallows frame in the center.

RESUME OF STRUCTURE IN THE AREA OF THE TOURTELOTTE PARK
SPECIAL MAP.

The various mechanical accidents which have happened to the rocks
in the Tourtelotte Park district since their formation, bringing about
changes from their original position, may be enumerated as follows:

1. The first deformation——The first deformation consisted in a folding of the
sedimentary beds against the hard resisting granite axis of the Sawatch.

106 GEOLOGY OF ASPEN MINING DISTRICT, COLORADO.

The folding had its maximum development in a line running approxi-
mately parallel with this granite axis, and the movement was especially
important in the upper beds, resulting in an overthrown, easterly dipping
syneline, which had a slight pitch to the north. Judging, however, from
the nature of this folding in the lower rocks, as now exposed by erosion in
the southern part of the Tourtelotte Park special area, the amount of detor-
mation is there not nearly so great; and it is probable that the fold became
progressively less with depth and disappeared entirely in the granite. It
has already been noted that with the increase in depth the overthrown,
eastwardly dipping syneline tends to straighten up, and finally resolves
itself into a normal open fold. To the west of this chief axis of folding
there is a series of open folds, which, however, die away in a short distance,
so that the beds become comparatively undisturbed. ‘To the east of this
main axis, and between it and the granite, there existed a series of open
folds, such as are now exposed by erosion in the Tourtelotte Park district,
which were probably heavy in the upper strata, but all very gentle in the
lower beds.

2, The Silver system of faults —Synchronously with the folding, and as a result
of it, there was a certain amount of slipping of one bed over another to
accommodate themselves to the new position into which they were forced.
This gave rise to fault zones or fault planes nearly or quite coincident with
the bedding, which, however, have great persistence and a notable amount
of displacement, and have played an important part in the economic his-
tory of the region. These faults are very numerous throughout the whole
district, but two of them are perhaps more important in the study of ore
deposition than any two other faults which may be found. One of these,
which has been called the Contact fault, appears to be strictly parallel with
the bedding, at the contact between the blue foraminiferal limestone and
the underlying dolomite of the Leadville formation. Its displacement,
therefore, can not be measured, but that it has been considerable is proved
by the slickensiding and brecciation almost always found along it. The
other fault is also very nearly parallel to the bedding, but frequently cuts
it at a very slight angle, so that portions of the strata are carried away by
its action in certain localities. The amount to which the strata have thus
locally been cut down shows that the movement along the fault has been
very great.

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TOURTELOTTE PARK SPECIAL MAP. 107

3. The first system of north-south faults —T he overthrust fold described above cul-
minated in a great fault along its axis, called the Castle Creek fault. This
fault varied in magnitude, as did the preexisting fold, being greatest in
the upper beds, diminishing in the lower, and probably dying out in
the granite. With depth, also, the easterly dip steepened, and finally,
as shown in the southern part of the Tourtelotte Park special map (Atlas
Sheet XII), became practically vertical. Probably at about the same time
with the Castle Creek fault other parallel displacements occurred, the
ereatest naturally being close to the master fault. The most notable are
the north-south faults of West Aspen Mountain, which have a heavy throw,
while the parallel breaks farther to the east have progressively slighter
displacement. There was also developed, probably at about this time, a
series of cross fractures, running east and west between the main north-
south faults, but the rocks do not seem to have had any great movement
along these east-west planes till a later date.

The movements which have been thus summarized, together with
some complications which need not be mentioned here, all occurred
previous to the deposition of ore, as is shown by the fact that ore solutions
have chosen them by preference as loci for the mineralization. They may
be conveniently separated from the succeeding movements which are about
to be enumerated, and which took place subsequent to the deposition of
the ore, and may be classified as premineral, while the later movements
are postmineral.

4. Postmineral movement.—Subsequent to the period of ore deposition there
was a movement along certain north-south fractures which had originated,
probably, at the same time as the north-south faults on West Aspen
Mountain. This postmineral movement produced, chiefly, the Tourtelotte
Park north-south fault system, of which the Justice, the Copper, and
the Ontario faults are examples.

5. Post-Glacial movement —A continuation of the movement made itself mani-
fest in the east-west fractures, which also probably originated at an early
date, but did not attain any great importance until this later period.
This movement, a large part of which was brought about in post-Glacial
time, gives rise to the system of east-west faults, of which there are
numerous examples in the northern half of the Tourtelotte Park special
area.

108 GEOLOGY OF ASPEN MINING DISTRICT, COLORADO.

DESCRIPTION OF SECTIONS.

On account of the extremely complicated structure in the Tourtelotte
Park area, it was necessary to construct many sections in order that the
geology might be made reasonably clear. (See Atlas Sheets XIII, XIV,
XV.) Inasmuch as the axis of the main fold runs parallel to the main
ridge in Tourtelotte Park, cross sections were constructed at right angles
to this ridge, and six east-west sections were finally selected for publica-
tion. Another series of sections was constructed at right angles to the
others. Thus the two sets form a sort of rectangular grating, as shown
on the map (Atlas Sheet XII), and by taking the east-west sections
together with the north-south ones a comparatively clear idea of the
structure of the district may be obtained. All the east-west sections look
toward the north, and all the north-south sections toward the east, a
system which has been adopted throughout this report.

Section a—At the western end of the section the Maroon beds are over-
turned at the surface, while with depth the return of the strata to their
normal succession is seen. The overthrown fold rests against the Castle
Creek fault, and the curved form of this fault, which has been inferred
from its change of dip toward the south, is shown in the section. On the
east side of the fault is the Archean granite, showing how great the throw
has been at this point. Toward the east granite outcrops in the section
continuously nearly to the Saddle Rock fault. Just west of this fault, how-
ever, there comes in, probably in its normal succession above the granite,
the Cambrian quartzite, which contains in its lower part a thin sheet of
diorite. These beds dip to the east, forming a part of the west limb of the
Aspen Mountain syneline, and they are successively downfaulted to the east
by the Saddle Rock and the Sarah Jane faults. These two faults are shown
in the section as cut and displaced by a lower fault. This belongs to the
east-west system, but on account of its dip cuts the plane of the section in
somewhat the manner represented.’ This east-west fault has a slight down-
throw to the south, and is called the Dixon fault, from its being best shown
in the mine of that name. Last of the Dixon fault is shown a very shallow
syneline, the axis of which lies nearly under the ridge of the hill. This

1Tn studying the sections care should be taken to remember that the angle of the faults as
plotted is not always the actual dip, for the angle represented is that which the fault plane makes
with the plane of the section. Thus a fault which has a dip of 70 or 80 degrees may appear as a
horizontal line in a section parallel to its trend.

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XI Id IxXxx HdVHSONOW ABSAYNS 1V9INO103D “Ss “nN

TOURTELOTTE PARK SPECIAL MAP. 109

syucline is unbroken as far as Spar Gulch, where the Justice fault is
encountered, which has a considerable downthrow to the east. East of the
Justice fault the beds dip at an angle equal to the slope of the hill, and so
present their basset edges in outcrop on the eastern side of the hill in Cop-
per Gulch. In the bottom of Copper Gulch the Copper fault is encountered,
which has a slight downthrow to the east. This is, however, abnormal,
being caused by the later movement of the minor east-west faults which
have introduced much complexity in the structure of this locality.

Hast of the Copper fault is a flat, easterly dipping fault, which forms,
apparently, a sort of splinter between the Ontario and Copper faults, and
which has probably no great persistence, as it certainly has no great throw.

In the strata between the Ontario and the Copper faults appears the
axis of the anticline which joins the Aspen Mountain syncline on the
west, and which is indicated on East Aspen Mountain and is present in
a large part of Tourtelotte Park. his tendency toward the assumption
of a flat position, or even of a slight anticlinal structure, is also found
in the Hunter Park and Lenado districts. In Lenado Canyon a’ slight
anticline, resting against the granite, is fully exposed on a vertical cliff
a short distance above the village, and the same structure, dying out
toward the south, can be traced over a large part of the Hunter Park map.

The Ontario fault, in this section, has a comparatively slight down-
throw to the east, but the next fault to the east probably belongs to the
same system, and it may well be that the two have split off from the main
Ontario fault, which was traced farther to the south. In the block to the
east of the fault last mentioned, which may be called Ontario No. 2, the
beds have a position which indicates a slight syncline, resting against
granite. The tendency toward this final synclinal structure is also shown
in parallel sections farther south. The last fault shown on the map as
existing in the granite is the continuation of a fault of the east-west system.

Section B——In Section B there is shown on thé west, as before, the Castle
Creek fault, and the steeply dipping beds which lie against it. In this case,
however, the overthrown beds resume their normal position at a much less
distance from the surface than in Section A. There are also shown two
minor faults to the west of the Castle Creek fault, which are nearly parallel
to the main fault, and divide the total throw, there being a continuous
upfaulting to the east along each plane. The actual number of these slip

110 GEOLOGY OF ASPEN MINING DISTRICT, COLORADO.

planes is very great and can not be precisely ascertained, but on some of
them the movement has been much greater than on others, and along such
planes it has been found advisable to represent the total movement as
having occurred. The two faults shown in the section have actually been
traced over nearly the whole southern part of the area of the Tourtelotte
Park special map (Atlas Sheet XII). The western one may be called
the Annie fault, and the eastern one the Dubuque fault, from their being
best shown, respectively, in these mines. Faults of this character may be
called dependent faults, since they are really parts of the main or master
fault, which in this case is the Castle Creek. Owing partly to the action of
these dependent faults, and partly to the change m attitude of the beds on
the west side—partly, also, to the somewhat lower position of the rocks on
the east side—the entire throw of the Castle Creek fault has considerably
diminished from that shown in Section A.

East from the Castle Creek fault the Cambrian quartzite is soon
encountered above the granite. This is in turn overlain by the Silurian
dolomite, which extends as far as the Saddle Rock fault. This fault has
its usual downthrow to the east, and places the outcrop of the Carbon-
iferous dolomite adjacent to that of the Silurian. Farther up the hill
comes the Silver fault, with the thin strip of crushed shale which separates
the Leadville limestone from the main sheet of porphyry. Close to this
point the Sarah Jane fault is encountered, with its usual downthrow to the
east. East of this fault is shown the remnant of the Aspen Mountain
syncline, in a position corresponding to that in Section A. This is practi-
cally continuous and unbroken as far as the Justice fault. Between the
Justice and the Sarah Jane faults is a slight displacement, arising from
the Good Thunder fault. his fault belongs to the east-west system, but,
on account of an irregular crumpling in this plane, actually cuts the section
as represented. In the 300-foot section (see Section F, Atlas Sheet
XXIJID, along this same line, the fault is more accurately represented
as intersecting the plane of the section m two lines, but in the 800-foot

section the intersection has been represented, for the sake of simplicity, as,

in a single line. The Justice fault has its usual downthrow to the east and
is cut at the place where its throw has been best measured. Immediately
east of the Justice fault the main sheet of porphyry cuts up across the
bedding of the Weber shales, leaving a considerably increased thickness of

x

PL.

MONOGRAPH XXX!

U. S. GEOLOGICAL SURVEY

SILVER BELL FAULT SCARP.

‘ wou

TOURTELOTTE PARK SPECIAL MAP. 111

shale between it and the limestone. Farther east come in two faults of the
east-west system, which, on account of the angle of intersection which their
planes make with the plane of the cross section, seem to have a flat dip to
the west. Their actual dips, however, are nearly vertical, as can be seen
on some of the north-south sections, which cut their planes more nearly at
right angles. Hast of these faults the Parting Quartzite crops at the top of
the hill) In the gulch on the east side of the hill runs the Copper fault,
having here its normal upthrow to the east. At about this point the Aspen
Mountain syneline flattens, preparatory to forming the adjacent anticline,
and so the outcropping beds pass into the air, giving place to granite
farther down the hill. The throw of the Ontario fault, however, brings
down the rocks so that the Silurian dolomite on the east abuts against the
granite on the west. Below the Silurian dolomite the Cambrian quartzite
and the granite are again exposed. The last fault shown in the section
belongs to the east-west system.

In the block which lies between the Ontario fault and this east-west
fault last mentioned is a little synclinal basin, which dips in on all sides
toward the center.

In this section the thin diorite sheet is somewhat higher up in the
Cambrian quartzite than in Section A. This sheet also thins out and disap-
pears toward the west, so that where the quartzite outcrops on the western
slope of the hill no diorite is found.

_ Section c—West of Castle Creek fault in this section the Maroon and
underlying formations are slightly overturned at their outcrop, but right
themselves almost immediately below the surface, and assume their normal
succession. In this section the Weber formation comes in definitely and
persistently in its normal place below the Maroon formation. East of
the fault the Silurian dolomite outcrops. The dependent faults west of the
Castle Creek drag up wedges of the underlying formations, so that the
Leadville limestone nearly reaches the surface at the outcrop of the main
fault. The throw of the fault is thus greatly diminished, although still
large.

Kast of the Castle Creek fault the Saddle Rock fault comes in, having
its usual downthrow to the east. The next break is the Sarah Jane, which
has at this point a considerable downthrow to the east, and the next is the
Justice, whose movement is a downthrow to the west, the reverse of

112 GEOLOGY OF ASPEN MINING DISTRICT, COLORADO.

the usual displacement. 'The increased throw of the Sarah Jane and the
apparent reversed movement of the Justice are, as before explained, due to
the downfaulting of the wedge included between these two faults near
their intersection. The first fault east of the Justice is apparently slight,
and is probably a nonpersistent cross fault, having a northwest trend. It
is marked in the topography by a continuous scarp, and seems to haye a
slight downthrow to the northeast, as represented.

East of this fault the continued westerly dip brings the Silurian lime-
stone into outcrop. On the eastern slope of the hill the Copper fault is
encountered in its usual position, with its maximum development. Its
movement is an upthrow to the east, so that the Cambrian quarzite rests
against the Silurian dolomite. Below the quartzite granite outcrops along
the section plane till the east-west Butte fault is obliquely intersected. On
the south side of this fault come again the Silurian dolomite and Cambrian
quartzite, which in turn give way to the granite

In this section the only shale is that in the little downthrust block
between the Justice and the Sarah Jane faults, and there is no porphyry
whatever. This is due to the northerly pitch of the beds, which carries
the strata successively above the surface toward the south. The diorite
sheet. has in this section taken up its place in the middle or near the upper
part of the Silurian dolomite, having cut up across the strata in the distance
intervening between this section and Section B.

Section D— West of the Castle Creek fault in this section the beds change
at their point of outcrop from their reversed easterly dip to their normal
westerly one. Hast of the fault the Cambrian quartzite and the lowest
part of the Silurian dolomite outcrop. The next fault encountered runs
north and south, and is probably the Saddle Rock. This has a slight
downthrow to the east. ;

The first of a series of east-west trending faults, which have a dip
toward the south, is next cut. On account of their dip, these faults cut the
plane of the section im nearly horizontal lines, as represented. The fact that
both the east-west and the north-south faults cut the same section explains
the somewhat complicated structure here shown. The Justice fault, which,
after uniting with the Sarah Jane, probably dies out against one of these
east-west faults, outcrops at this point a little to the north of the line of
the section, and does not, therefore, cut this section plane at the surface;

TOURTELOTTE PARK SPECIAL MAP. 113

but since the fault against which it is represented as stopping has a
southerly dip, this fault and the Justice fault with it enter the section at
some distance below, as represented, and continue indefinitely downward.

The general structure is that of a westerly dipping monocline, with
some slight trace of the gentle foldigs which were observed in the section
farther north on the east side of the hill. The granite outcrops in its natural
position below the quartzite until cut off by the Ontario fault, which has
its normal downthrow to the east, and brings the bottom of the Silurian
dolomite against the granite. The beds at this point lie nearly flat, and
possibly have a very slight westerly dip, so that on going down the hill
the edges of the dolomite and underlying quartzite are passed over to the
granite. In this section the diorite sheet is thicker than in the sections
farther north, and lies only a short distance below the Parting Quartzite.

Section E—West of the Castle Creek fault the beds have in this section
definitely resumed their normal position, and dip steeply to the west. East
of the Maroon formation nearly the whole Weber formation outcrops, and
it is probable that below this line porphyry, blue limestone, and the rest of
the usual succession occur.

East of the fault there lies, as in the preceding section, the Cambrian
quartzite, which has a gentle westerly dip. This dip being considerably
less than the slope of the hill, the Silurian dolomite comes in above the
quartzite a short distance up. The first fault encountered runs north and
south and has a slight downthrow to the east. This is probably the Saddle
Rock fault. East of the Saddle Rock fault there intersect the plane of the
section a number of the southerly dipping east-west faults which have been
previously mentioned, and which, on account of their trend being nearly
parallel with the trend of the section, intersect the section plane in a nearly
horizontal line.

As in the previous section, the general structure is that of the westerly
dipping monocline, with some slight indication of a tendency toward the old
anticlinal structure near the top of the hill. Where the strata successively
outcrop on the west side of the hill, however, they have still a slight west-
erly dip. Granite outcrops a short distance down the hill, as far as the
Ontario fault, when the downthrow of this fault brings in the Silurian dolo-
mite to the east. Passing down the hill, however, one goes across the edge
of the Cambian quartzite to granite, which continues to the end of the section.

MON XXXI——8

114 GEOLOGY OF ASPEN MINING DISTRICT, COLORADO.

In this section the diorite is slightly higher in position than in any of
those farther north. It has attained about the horizon of the Parting
Quartzite, which it frequently cuts across, and small bodies of which it
sometimes surrounds. Its thickness is probably about the same as that of
the Parting Quartzite itself.

Section F—In this section the beds west of the Castle Creek fault are
seen more fully restored to their normal succession. The chief dependent
faults—the Annie and the Dubuque—both outcrop. The convergence
toward the south between the trend of the Castle Creek fault and the line
of contact between the granite and the overlying sedimentary beds has so
reduced the distance between the Castle Creek fault and the granite in this
section that it is very slight. The northerly pitch of the beds, moreover,
has brought to the surface successively lower and lower formations, so that
in this section the highest horizon east of the Castle Creek fault is that of
the Parting Quartzite. The Parting Quartzite, however, is not represented
in the section, for the diorite sheet, here apparently as much as 100 feet
thick, has superseded and traversed the Parting Quartzite until the exact
position of the latter is not recognizable. Thus the place of the Parting
Quartzite is occupied by the diorite, and above the diorite the Leadville
formation comes in. Below the Silurian dolomite on the east side of the
hill the Cambrian quartzite is continuous to the Ontario fault. This fault
brings down into the section the very bottom of the Silurian dolomite,
which passes immediately across the Cambrian quartzite into the granite.
The fault represented just below the contact of the Cambrian quartzite with
the granite is a nonpersistent north-south fault, which has some slight
upthrow to the east. The last fault shown in the section as outcropping in
the granite on the side of the hill is one of the series of east-west southerly
dipping faults.

Sections G, H, and I (Atlas Sheet XV) are north-south sections, run-
ning at right angles to the six sections which have already been described.

section G.—This section starts in granite on the slope of Hast Aspen
Mountain, just above Roaring Fork Valley, and at a little distance south it
runs into the north-pitching series of sedimentary beds. The pitch of
these beds tends to carry them into the air, but they are continually thrust
down toward the south by parallel east-west faults. These faults are
shown in the section as reversed, and from all the information that could

PL. XI

MONOGRAPH Xxx!

U. S. GEOLOGICAL SURVEY

:

VIEW FROM LENADO, LOOKING EAST UP THE CANYON.

TOURTELOTTE PARK SPECIAL MAP. 115

be obtained they are actually so, but it is possible that additional infor-
mation might prove them to be otherwise.

In the most important of these downthrust blocks appears the peculiar
local syncline described in Section B. If the two are taken together it is
seen that the beds form a true synclinal basin, in which the strata dip on
all sides toward a common point. Between the southern end of this syn-
clinal basin, where it is cut off by an east-west fault, and the corresponding
sedimentary beds on the south side of the Butte fault, there intervenes the
upthrust block which has already been referred to as having apparently not
been affected by the movement of the Ontario fault. In this block, there-
fore, only granite comes into the section. South of the Butte fault the
section runs into the Cambrian quartzite again, and so continues nearly to
the end, since the strike of the beds is nearly parallel with the section.
This continuity is interrupted in occasional blocks, which are shifted from
their normal position by movement along east-west faults, and toward the
southern part of the section a slight deviation between the strike of the beds
and the line of the section brings in the bottom of the Silurian dolomite.
Between this point and the southern edge of the area mapped the section
encounters three parallel east-west faults, all of which have a uniform
upthrow to the south; and as their dip seems to be in a southerly direction,
they are apparently reversed. These faults bring in the granite.

Section H.— Section H runs along the ridge of the hill through a region
of great disturbance. In the northern half of the section there is a general
northerly pitch of the beds. The rocks are disturbed by many east-west
faults, which have apparently no uniform movement, so that it appears as
if the rocks had been divided by these parallel faults into blocks, which
have moved irregularly one upon the other.

The Copper fault, which belongs to the north-south system, has a
westerly dip, which carries it into the section. Many of the east-west
faults which lie to the east stop on reaching this fault, while many on the
west side are also nonpersistent and stop at this plane. This explains
the presentation of the faults in the section. Those which are drawn
below the Copper fault and which stop on reaching it represent faults in
the eastern block, while those which crop at the surface and stop in their
downward course on reaching the Copper fault are the nonpersistent faults
which lie in the western block. There are, however, certain ones which

116 GEOLOGY OF ASPEN MINING DISTRICT, COLORADO.

run from top to bottom of the section, and these are the faults which run
across both blocks, traversing the Copper fault without any apparent
break. This section illustrates well the great difference in persistence of
these east-west cross breaks.

The Butte fault has a slight downthrow to the south, and south of
this are a great number of parallel east-west southerly dipping faults.
The beds along the top of the hill have a slight northerly pitch, so that
lower beds tend to outcrop successively toward the south; but these
parallel faults have a uniform slight downthrow to the south, so that the
outcropping horizon, which is about at the Parting Quartzite, is kept very
nearly the same. The southernmost of these faults, however, appears to
differ from the rest in having a reversed upthrow to the south.

In this section the change of position in the diorite, as illustrated from
place to place in the east-west sections, may be continually followed. At
the southern end of the section the diorite occupies the position of the
Parting Quartzite, between the Silurian dolomite and that of the Carbon-
iferous, and it appears here in its maximum thickness, so far as the present
mapping goes. Toward the north it cuts very gradually down across the
beds until about the center of the section, where it cuts down more rapidly
and enters the Cambrian quartzite. In this it continues, gradually getting
deeper, as far as the northern limit of the mapped area, where it is a very
thin sheet, lying close to the granite. A short distance farther north, on
Aspen Mountain, the diorite disappears.

section!—In this section granite outcrops at the north end. Farther
south is a series of faults which belong to the east-west system, and which
have the effect of thrusting down the blocks to the north.

Between this faulted area and the place where the section cuts the
Castle Creek fault there is a comparatively undisturbed portion, in which
the beds lie nearly flat, with only slight undulations along the strike.
Thus the Cambrian quartzite is exposed in outcrop, with the Silurian
dolomite overlying it, on the ridge cut by the section. The Castle Creek
fault is cut obliquely, as well as the two main dependent faults, the Annie
and the Dubuque. The east-west fault, which has been called the Butte,
has cut and faulted the Castle Creek fault, being of later origin; and as
the section cuts the formations near the intersection of all these faults, the
structure shown is complicated.

xi

PL.

MONOGRAPH XXxXI

U. S. GEOLOGICAL SURVEY

FOLD IN CAMBRIAN QUARTZITE ON THE NORTH SIDE OF LENADO CANYON.

2
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Notes

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LENADO SPECIAL MAP. 117

South of the Castle Creek fault the section does not encounter any
disturbance, but cuts the steeply dipping sandstones and shales in a nearly
horizontal zone.

RESUME OF FAULTING.

In the six east-west sections which have been described the north-
south faults have a general downthrust to the east. This is comparatively
uniform, The throw of the east-west faults, however, as seen in the three
longitudinal sections, G, H, and I (Atlas Sheet XV), is not nearly so uni-
form. In Section G the east-west faults to the north of the Butte fault have
a general downthrust to the south, while in the same section the common
throw of the same system of faults to the south of the Butte fault has been
up tothe south. In the northern part of Section H there is a general down-
throw to the south; in the central part there is no uniform direction of throw,
the blocks having moved up and down indiscriminately; in the southern part
there is a tendency toward a downthrust to the south. In Section I the ©
common throw of the faults in the northern part of the section seems to be
down to the north. So the total effect of all the faulting in the ourtelotte
Park area may be summarized as a general downthrow to the south and
east, the downthrow to the east being strongly marked, while that to the
south is not so uniform.

LENADO SPECIAL MAP.

FOLDING.

The only noteworthy feature in the flexure in the beds at Lenado is a
slight anticlmal dome on the extreme eastern edge of the area of the
special map, where the lowest beds of the sedimentary series abut against
the granite. The fold is best seen in the bed of Woody Creek, about three-
quarters of a mile above the little camp of Lenado. At this point the
stream emerges from its granite bed and crosses over the uptumed edges
of the overlying sedimentary formations. This change from the Archean
to the overlying rocks is marked by a very striking gap, which is shown in
Pl. XI. This view looks east up the valley of Woody Creek from Lenado.
The distance between the houses in the foreground and the cliffs which
rise above the canyon on both sides is about half a mile. The top of the
steep cliff at the right is of Cambrian quartzite, and the quartzite also

118 GEOLOGY OF ASPEN MINING DISTRICT, COLORADO.

outcrops at about the same elevation on the other side, which is also very
steep, but is not well shown in the picture. Overlying the quartzite at the
extreme left of the plate are the lowest beds of the Silurian dolomite, while
underlying the quartzite and forming the base of both of the cliffs is
granite. The main dip of the beds is not seen im this picture, being
directly toward the observer, but the minor dips to the north and south can
be made out in the cliffs on both sides. The top of the cliff at the right
shows an outline against the sky corresponding with the attitude of its
strata for a short distance north of its brow to the bottom of the little sag.
Through this sag runs a heavy fault, to the south of which lies the granite,
so that at the extreme right of the picture the outline of the hill has no
reference to any stratification.

The cliffs on the left side of this picture are better shown in Pl. XII,
which is from a photograph taken from the hill on the south side, looking
north across the canyon to the nearly vertical wall. On the extreme left
of this picture is the same locality as the left side of the preceding plate,
but the two pictures are, as explained, taken at right angles to each other.
The abrupt cliff is made up of Cambrian quartzite, and the height of the
cliff is very nearly the entire thickness of the formation. The changes
of dip in these rocks may be well observed, and bring out the slight anti-
clinal structure, for this is a natural cross section at right angles to the axis
of greatest folding. In the central part of the picture the cliffs are nearly
horizontal, as viewed in this east-west section, while to the west the dip
grows steeper, until near the bottom itis 35 or 40 degrees. ‘To the east,
on the other hand, the beds assume a very gentle easterly dip as far as the
gulch which may be dimly seen through the trees at the right in Pl. XII.
At this gulch the beds are cut out by the heavy fault before referred to,
so that they abut directly against granite. Below the quartzite cliffs the
rock is granite, while above them comes in the Silurian dolomite.

The folding in the remainder of the area of the Lenado map is simple,
and even monotonous, there being a continuous westerly dip from the
western side of the slight anticline above described. Near the eastern end
of the area the dip is flatter than farther west, the average at first bemg
perhaps 30 degrees. This dip flattens on the tops of hills and steepens
in the valleys, showing the persistence in the curving of the beds con-
formable with the folding shown in the Cambrian quartzite in Pl. XI.

PL. Xill

MONOGRAPH XXXI

U. S. GEOLOGICAL SURVEY

eee ae

ena

SILVER CREEK VALLEY. ERODED IN WEBER SHALES.

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LENADO SPECIAL MAP. 119

Farther west the dip steepens gradually, until, at the western end of the
section, it averages perhaps 45 or 50 degrees.

Along the valley of Woody Creek the rock exposures are almost con-
tinuous, so that a complete section is obtained. After passing westward
through the canyon above described, there are successively encountered the
Silurian dolomite, the Parting Quartzite, the Carboniferous dolomite, and
the overlying Weber shales. Above these come the Maroon beds, with
their basal gray limestone. These Maroon beds run continuously in the
bottom of Woody Creek as far as the limit of the area mapped, but at some
little distance west the line of division between the Triassic and the Car-
boniferous has been placed, and the strike of this contact just carries it
across the top of the hill in the extreme northwestern end of the area.

The successive formations over which the creek passes in its westerly
course give rise each to different variations in the shape of the valley.
Above the Archean gateway which has been described the valley broadens
out, being flanked on either side by steep granite hills which have been
worn down from their original shape by the action of glaciers. The sharp-
ness of the canyon across the anticlinal fold is apparently due not so much
to the nature of the rocks. as to the presence of the fold. The center of
the dome, which has a steep dip to the west and a gentle dip to the north,
the south, and the east, has been eroded with comparative ease, while the
rocks on its sides have been more resistant. Just west of this canyon
erosion has gone on with much greater rapidity, so that the widening out
of the valley is very striking. The side gulches which run into the main
creek now have a considerable length and a comparatively low gradient.
This is seen in Pl. XIII, from a photograph taken from Woody Creek look-
ing up Silver Creek, which is one of the side gulches referred to. This
gulch has been eroded in the Weber shales, about midway between the
contact with the Maroon on the west and the contact of the Leadville dolo-
mite on the east. The Maroon beds come in at the extreme left of the
picture. After passing through the Weber formation and entering the red
sandstones of the Maroon, followed by similar but probably Triassic rocks,
the valley of Woody Creek assumes again a new form, which is continuous
throughout a large part of its course, until it passes beyond the sandstones.
This part of the valley is in general v-shaped, the hills on both sides hay-
ing a steep but uniform slope, and the side gulches being short, with steep

»

120 GEOLOGY OF ASPEN MINING DISTRICT, COLORADO.

gradient. The hills on both sides of this valley are largely bare of vege-
tation, so that the outcropping strata of red or brown sandstone give a
characteristic hue to the landscape, which can be seen at great distances.

Pl. XIV is a view of the northern side of this Lenado Valley in the
sandstone district. It is taken from the top of the hill on the south side of
the valley, at a point about 1,500 feet above the creek, and looks across
the valley and up one of the side gulches. On the left of this side gulch
are the perfectly bare outcrops of westerly dipping strata of Maroon sand-
stone. This type of valley continues until the stream emerges from the
red sandstones into the comparatively flat and much softer Cretaceous rocks.
Where the stream flows through these, as it does for several miles above its
junction with Roaring Fork, the rocks have been worn down to nearly the
level of the stream bed itself, so that there is no very deep valley.

FAULTS.

Silver fault—The contact. between the Weber shales and the Leadville
dolomite is, throughout the whole of the area shown on this map, appar-
ently a true fault contact, for it is characterized by a brecciated zone and
by evidences of slipping in the formation of polished and striated surfaces
and in little slip faults parallel to the maia contact. These features are, of
course, best exposed in underground workings, and are especially well
shown in the Clark tunnel and in the Bimetallic tunnel. As far as the
evidence on this map alone goes, the fault seems to be strictly parallel to
the bedding. In all places the formation lying above the fault is the
Weber, and that below is Leadville dolomite. There is not found in this
area, so far as observed, any of the blue foraminiferal limestone which lies
above the dolomite at the top of the Leadville formation on Aspen
Mountain and in Tourtelotte Park.

There may be made three suppositions to account for its absence:
(1) That the blue limestone referred to was a local deposit, which was not
formed at all in this region; (2) that the limestone was deposited over this
area originally as over the area farther south, but that during the erosion
interval between the Leadville and the Weber formations the blue limestone,
and probably a part of the underlying dolomite, were worn away, so that
the Weber shales were deposited directly upon the dolomite; (3) that both
the dolomite and the blue limestone existed in this district up to the time

‘AATIVA WARN AGOOM JO GIS HLYON NO SSNOLSGNVS NOOUVIN

AIX “1d IXXX HdVYDON
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LENADO SPECIAL MAP. 121

of the folding and the formation of the Silver fault, and that the movement
of that fault resulted in cutting off the blue limestone and a portion of the
dolomite.

The first of these suppositions appears impossible, for the thickness of
the blue limestone on Aspen Mountain and in Tourtelotte Park is from 100
to 150 feet, and this formation is known to extend a long distance to the
south of this point. North from Aspen Mountain, however, the blue lime-
stone disappears in the bottom of the valley between Aspen and Smuggler
mountains, and is not found at any point north of the Roaring Fork in the
area examined. It is not probable that a formation having the considerable
thickness above referred to should naturally die out in such a short lateral
distance. The second supposition has more evidence in its favor, for there
is known to have been an important upheaval and erosion interval between
the deposition of the Leadville limestone and that of the Weber shales.
During this interval the beds must have been in many places eroded,
and it is not unlikely that in certain places whole formations were stripped
away. It may be that in this way the Leadville blue limestone was
removed over the Lenado area, and that the succeeding deposition of
the Weber shale took place immediately upon the dolomite. The third
supposition has fully as strong evidence in its favor, however, as has the
second, for the contact of shale and dolomite is invariably, not only in the
Lenado area, but throughout the whole district, a fault contact, and its char-
acter shows that the movement along it has been very great, the amount of
brecciation being greater than would result from a slight movement. Ina
fault of so great magnitude it would be very easy for the plane of greatest
movement to deviate locally from the plane of the bedding, and this devia-
tion would produce the differences in the rocks on both sides of the fault
which have been observed. A very slight deviation of this kind might, by
faulting, remove whole formations.

It may be possible that both the latter Ae are in a measure
true, and that some of the lack of uniformity results from an unconformity
below the Weber and some of it from faulting. The facts, however, are
sufficient for most purposes, namely, that in the contact between the Weber
and the underlying rocks there has been invariably, so far as observed
in this district, a fault of great actual displacement which, on account of its
parallelism to the bedding, or close approach thereto, does not exhibit any

122 GEOLOGY OF ASPEN MINING DISTRICT, COLORADO.

striking changes in the rocks lying on either side of it; that along this fault
there appear and die out gradually, owing to its character as above described,
comparatively slight discordances, so that at one point the Weber shales
rest against the blue Leadville limestone and at other points against the
Leadville dolomite; and near Hunter Creek the shales rest against the
Parting Quartzite and the Silurian dolomite. This fault has been more
important than any other one thing in determining the deposition of min-
erals throughout the whole Aspen district.

The Silver fault originated earlier than any of the other main structural
disturbances in the district, with the exception of the folding. It is sup-
posed that it took place at about the same time with the folding, and that it
represents the slipping of one formation over the other in their endeavor to
accommodate themselves to the new conditions.

East-west faults —T'here are shown on the map two faults having a general
east-west trend. These evidently belong to the same system, and there
seems to be more of them in the district just north of the northern end of
the map, running in the same direction. The chief of these two faults is
called the Lenado fault. It has, in general, an east-west trend; and its dip
is always steep, often approaching the vertical. In the Bimetallic tunnel it
dips steeply north, and since the downthrow is on the north side, the fault
is normal. This northerly dip causes the outcrop to recede in a southerly-
direction toward the west, so that it runs from the Aspen Contact mine
in a southwesterly direction. In the Aspen Contact and the Leadville
mines, however, the dip is nearly vertical, and even slightly overturned, so
that it is steeply toward the south; in this case the fault is reversed, and,
from its course east of the Aspen Contact mine, it may be judged that its
southerly dip persists to the eastern edge of the area mapped.

This fault may be traced throughout most of its distance across the
area. It was first observed in the bend in the road above the Bimetallic
tunnel, where the Leadville dolomite comes into contact with the hard
black Weber limestones. This contact is one which normally appears
throughout this district as the Silver fault, which has led to a great deal of
confusion among the miners. But in this case the fault cuts across the for-
mations diagonally, while the Silver fault is always nearly or quite parallel
to them. The true Silver fault runs into the Lenado fault very near the
point mentioned, and is cut off, bemg displaced so that its continuation on

LENADO SPECIAL MAP. 1233

the northern side of the fault is nearly three-quarters of a mile away to the
northeast. The’ Lenado fault is cut in the Leadville and Aspen Contact
mines. Just above the Leadville mine it is shown in the Daisy and Ajax
tunnels, which run into it on opposite sides of the gulch. Farther on
the fault crosses the cliff on the south side of the granite gateway, in the
little sag shown in PI. XI, and from here apparently runs across the gulch
in granite so as to cut off the quartzite on the northern side of the
canyon. This last point is not shown on the map, but may be seen in
lel, 2UE

This fault, as estimated in Section B (Atlas Sheet XX), has about
1,300 feet vertical downthrow on the north side. The result of its displace-
ment, as seen on the map, is a shifting of the formations to the east on the
north side. The formations exposed on the south side of the fault abut on
the north side always against formations which are stratigraphically above
them. Thus, at the Aspen Contact mine, Cambrian quartzite on the south
lies against the Weber shales on the north. There are in this place, as
probably all along the fault, a number of parallel slips, which are close
together, and which divide the total throw between them. In the Aspen
Contact mine there are two faults close together, the most northerly of
which has shale on the north side and dolomite on the south side, while the
one next south has dolomite resting against quartzite. In the general
description and mapping, however, these parallel faults are considered as
one, and it is in this sense that the statement that the shales rest directly
against the quartzite must be taken.

It is probable that the total displacement of the rocks occasioned by
this fault was actually a nearly vertical downthrow to the north of about
the distance mentioned, without any great lateral movement, for the lateral
offset of the beds as now seen in outcrop is almost exactly the amount by
which the beds would separate from the results of a vertical throw. This
arises from the fact that the beds all have a steep dip of 35 or 40 degrees
to the west, so that the downthrust of the formations on the north side of
the faults causes the contact to advance a certain distance to the east, in a
direction opposite to that of the dip. The amount of this advancement
depends upon the angle of the dip of the beds, and upon the vertical throw.
The distance by which the outcrops of such beds would travel to the east
on the north side of the fault has been computed at an average dip of 30

124 GEOLOGY OF ASPEN MINING DISTRICT, COLORADO.

degrees to the west and a vertical downthrow of 1,300 feet on the north,
and is very close to the actual separation.

The distance by which formations would be separated by such a fault
depends upon the angle of the dip, as observed, for the flatter the dip the
greater will be the resulting distance. It therefore happens that in the
eastern end of the area the formations are farther separated than they are
a little farther west, for toward the west the dip becomes steeper and the
apparent lateral displacement less. This may be noted in the distance
between the contact of the Weber and the Maroon on the two sides of the
fault. It is very likely, moreover, that toward the west the fault actually
decreases in throw, the stress which in the more rigid rocks was relieved by
actual displacement being partly taken up by interstitial movement in the
loose sandstones. Thus it is probable that the fault loses most of its throw
in traversing Red Mountain, for in the shales on the west side of Castle
Creek fault there is no evidence of any large amount of displacement. (See
Section B, Aspen district map, Atlas Sheet VII.)

Of the east-west faults which appear north of Lenado, only one is shown
on the map. This fault has an upthrow to the north of about 600 feet.
(See Section G, Aspen district map.) In this way the dolomite on the south
side is brought into contact with the granite on the north. The section just
referred to shows throughout this area an uplifting of the beds along this
faulted zone, which has somewhat of a correspondence with the similar
uplift in the faulted area of Aspen Mountain and Tourtelotte Park, and
is made conspicuous by the fact that in the Hunter Park district, which
lies to the south, between Lenado and Aspen, there is no evidence of such
disturbance.

In point of age these east-west faults, of which the Lenado fault is
typical, are evidently younger than the Silver fault, since they displace
it in the same degree as they do the rock formations. Another fact which
is significant as to their age is that in the case of the Lenado fault there is
absolutely no evidence of mineralization throughout the most of its extent.
As cut in the Bimetallic tunnel, for example, there is no trace whatever of
its having been the channel of circulating mineral-bearing solutions. An
apparent exception to this is in the Aspen Contact and Leadville mines,
where much valuable ore has been taken out along the fault, and in these
localities all the ore which has been shipped from Lenado has been found.

LENADO SPECIAL MAP. 125

It is the opinion of those who have worked these mines, however—and their
opinion has been agreed to by the writer, after careful examination—that
the broken and bunchy condition of the ore indicates that it was not formed
in place, but has been dragged up along the fault from some other locality.
The usually barren condition of the fault goes to show that it originated
later than the ore deposition, and the conclusions which have been arrived
at in regard to the ore in the Aspen Contact and Leadville mines point in
the same direction.

Another slight point in the determination of the age of this fault is the
topography. Where the fault cuts across the top of the cliff on the south
side of the canyon, it forms a groove instead of a scarp. This is evidence
that there has been no movement of importance since the Glacial period.
The age of the fault is therefore determined as postmineral and pre-Glacial.

DESCRIPTION OF SECTIONS.

Section A——On the eastern side of this section, which, like all other east-
west sections, looks toward the north, the slight anticlinal structure, as
exhibited in the cliffs above Lenado, is shown. The various formations
represented in this section are actually visible, for in traversing this line
one passes from Cambrian quartzite and the Silurian dolomite into the
Parting Quartzite, which outcrops on the side of the hill and in the bottom
of a little gulch, as indicated; then across a slight thickness of Leadville
dolomite to the Silver fault, which is encountered at the bottom of the
gulch in which the Tilly shaft is located. Farther on are the westerly
dipping Weber beds, and overlying these the whole thickness of Maroon
sandstones, with thin-bedded limestones and shales, while at the extreme
western end of the section comes the assumed contact between the Maroon
and the Triassic beds. In this section the thickness of Leadville dolomite
between the Parting Quartzite and the Silver fault is very slight, probably
about 100 feet. This may be due to the faulting, as previously explained,
or possibly to the erosion which took place previous to the deposition of
the Weber rocks.

Section B—'This section is taken across the Lenado fault. Its eastern
end is in granite, and it runs west into the steeply dipping Cambrian
quartzite. After passing across the upturned edge of the quartzite to the
lowest beds of the Silurian dolomite, the Lenado fault is encountered,

126 GEOLOGY OF ASPEN MINING DISTRICT, COLORADO.

which brings down the Weber shales. Below the shales on the north side
of the fault, which is the west side as shown in the section, the Silver fault
and the Leadville dolomite have been computed to be present at about the
depth represented, so that the throw of the fault at this point is about 1,300
feet. 'The Weber shales are crumpled and folded against the fault, as
shown. Farther west is the usual succession of Weber shales and Maroon
sandstones, with at first a gentle and finally a slightly steeper dip.

HUNTER PARK SPECIAL MAP.

The Hunter Park district is a comparatively isolated area lying
between the Lenado and Aspen districts. It offers comparatively few diffi-
culties in mapping, on account of the simplicity of its structure. Most of
the southeast portion is in granite, while most of the northwest is occupied
by the red sandstones of the Maroon formation. In the northwest corner
of the map the Triassic sandstones are represented as coming in above the
Maroon. This representation is based on calculation rather than actual
observation, for the difference between the Maroon and the Triassic sand-
stones is so slight that the actual contact can scarcely be located in any
case.

Between the area occupied by the granite on the one hand and the
sandstones on the other there is a narrow zone extending continuously with
unbroken northeast course across the district. Throughout this belt there
are numerous outcrops, affording good opportunity for satisfactorily solving
the structure. The greatest break in the continuity of the rocks is offered
by the drift-filled valley of Hunter Creek, which, however, is comparatively
narrow. The drift in this valley is morainal in character, but has been
somewhat worked over by stream action; hence it has become of some
agricultural value.

Pl. XV gives a fairly good idea of the general aspect of the Hunter
Park region. The view was taken from a point at the southwest corner
of the area mapped, looking northeast. The hill in the foreground to the
right is heavily drift covered. In the foreground to the left and in the
center of the picture is the drift-filled valley of Hunter Creek, while in
the distance the peculiarly rounded outlines of the hill are characteristic of
this Hunter Park area, being due to extensive glacial erosion. ‘The small

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HUNTER PARK SPECIAL MAP. NAY

apparently isolated hill a little to the right of the center of the picture is in
the zone which lies between the granite and the red beds. At the base of
the hill to the right the granite outcrops; higher up is the Cambrian, and
at the top of the hill is the Silurian dolomite, while in the peculiar gap
comes in the Silver fault, and to the left of that the Weber shales. The
shaft dimly shown in the gulch at the left of the hill is the Badger, which
has gone down through the shales to the contact of shale and dolomite at
the Silver fault. In outline against the sky at the left of the picture is
shown a peculiarly rounded hill. The base of this hill, as seen in silhouette
where it meets the slight westerly dipping slope on the east side, is about
at the contact of Weber and Maroon. The hill, therefore, occupies the base
of the Maroon formation with its alternating thin beds of calcareous sand-
stone and arenaceous limestone with intercalated shales. These strata dip
to the west, or toward the left of the plate, and a peculiar and striking
feature in the landscape is that the slight amount of vegetation, consisting
chiefly of bushes and aspen trees, which has accumulated on the side of
this hill, has arranged itself in symmetrical bands indicating the position of
the outcropping strata. The reason for this appears to be that in the more
porous beds there is a greater amount of moisture, and that the vegetation
along this zone becomes more thrifty, or that the limy beds furnish more
nutrition to plant life than the more arenaceous ones. This banding is best
shown in autumn, when the frost gives the aspens their most brilliant
coloring.
FOLDING.

In the northeast part of the district the broad outcrops of Cambrian
and Silurian indicate a flattening of the strata to the east, corresponding to
the fold which has been described in the canyon at Lenado. West of this
flattening, as at Lenado, the beds become steeper, and in a short distance
the dip becomes uniform, and so continues to the western edge of the dis-
trict. This flattening of the strata to the east is not shown in the central
and southern parts of the district, for here erosion has removed the upper
part of the fold, leaving only the steeply dipping beds below. Through
the whole section west of the granite, in these portions of the district, the
uniform dip to the west is probably about 45 degrees, being less in some
places and greater in others.

128 GEOLOGY OF ASPEN MINING DISTRICT, COLORADO.

FAULTING.

Silver fault—The Silver fault is traceable across the district, either by
outcrops or, more accurately, by underground exploration. It has always
been well recognized that this plane is one of the most favorable localities
for prospecting, and so there is a continuous series of shafts or other work-
ings set at a short distance from one another along the whole line of the
fault. These workings always reveal at this plane the broken and shattered
zone, which shows this to be a true fault contact. The outcrop of this
fault, as shown on the map, is not strictly parallel to the formation lines,
although in a general way it is so, and the deviation from parallelism illus-
trates its fault character. In the northern part of the district the fault lies
between the Weber shales and the Leadville dolomite, and there is lacking
only the Leadville blue limestone to make up the entire section. In the
central part, however, the Silver fault tends to approach the underlying
strata toward the south, so that it cuts across the Leadville dolomite into the
Parting Quartzite, and at a point near the top of the isolated hill seen in
the accompanying plate it cuts across the Parting Quartzite into the Silurian
dolomite. These ditferent formations come successively to rest against the
shale, which persists on the northwest side of the fault. It is probable that
the occurrence of Weber shale resting upon Silurian dolomite, as found in
the vicinity of the Badger mine, is continuous across the creek under the
drift covering, for in the workings on the southern edge of this drift we
find the same conditions. At a point near the southern termination of the
outcrop of the Silver fault this fault cuts upward again across the strata,
revealing the whole of the Silurian dolomite, then the Parting Quartzite,
and finally cutting up into the Leadville dolomite. It does not, however,
get to the top of this last formation, and in the whole Hunter Park district
there was found no trace of the Leadville blue limestone.

Lenado fautt— The Lenado fault is shown on the northern part of the
map, but it is not actually traced across this district. From the trend of
the fault when last identified it must cut the Hunter Park area in about the
line indicated, and from its great throw at Lenado it must persist for a
long distance. In the thick red sandstones, however, which present no
well-marked difference from top to bottom, it is impossible to follow any
fault, and an additional difficulty is introduced by the drift covermg. The
probable effect of the fault is to bring the Triassic beds on the north

HUNTER PARK SPECIAL MAP. 129

against the Maroon on the south, in the northwestern corner of the area, as
shown on the map.

From the Lenado fault there was not discovered any noteworthy break,
with the exception of the Silver fault, until the southwest corner of the
district was reached. Here there is a slight break marking the extreme
northeastern border of the area of complicated faulting which extends
throughout the whole southern part of the district examined. This area of
extreme faulting, which is accompanied by a domelike uplift, is best
developed in the district shown on the Tourtelotte Park special map, m the
northern part of which it seems to attain it greatest importance. North-
ward from this point faults are strikingly developed over the whole of
Aspen Mountain; they are still well marked, but to a shghter degree, on
Smuggler Mountain, and they die out in the southwestern corner of the
Hunter Park area. The most northern of these faults observed is seen in
outcrop on the hill above the St. Joe and Bertha shafts. On this hill the
contact of the granite and quartzite is offset to the west on the north side, as
shown by its outcrop, about 200 feet. From this point the outcrop of the
fault passes into the granite on the east and under the drift covermg on the
west. In the Alta Argent mine, however, there is cut m the Cowenhoven
tunnel a fault which is probably identical with the one seen in outcrop in
the hill, This fault has a displacement to the west on the north side,
which has been approximately estimated as aggregating 100 feet or so.
This separation, however, has not taken place along any single plane, for in
place of a single slipping surface there are many parallel fractures, consti-
tuting an intensely sheeted zone of some thickness, and the displacement
has probably been distributed among these separate planes. The fault has
been located only in these two places, and is represented on the map as
dying out at both ends—to the east in the granite and to the west in the
sandstones on the north side of Hunter Creek. In these comparatively
homogeneous rocks the disturbance could not be followed, and so it can not
be told whether the fault is actually persistent or not. It seems probable
that the actual direction of movement along this fault was down to the
south, combined with some westerly lateral movement on the north side, so
that on the slipping plane of the fault, which, as shown in the Alta Argent
mine, is vertical, with a northwest-southeast trend, the movement was
diagonally down to the southeast on the south side. The lateral movement

MON XXXI 9

130 GEOLOGY OF ASPEN MINING DISTRICT, COLORADO.

in faults is well shown in the case of the neighboring Della fault, which
has a different slipping plane, but a similar direction of movement.

Age of Alta fautt—In the mines there are some ore shoots which apparently
have formed along fractures belonging to the Alta fault system, but these
are on the outskirts of the chief displacement and have only a slight
movement. Along the main fault there does not appear to be any
mineralization, but there are, instead, fissures and open watercourses. It
may be judged from this that the fault movement probably began immedi-
ately before the mineral deposition, but was mostly developed at a later
period. These conclusions in regard to age are almost surely true in the
case of the neighboring Della fault.

Della faut—The Della fault was not actually located in this district, but
was extended across the map on account of calculations based on data
obtained in mine workings on Smuggler Mountain. Its location, therefore,
is not of necessity exactly correct. It is represented on the map as having”
a throw similar to that which it possesses in Smuggler Mountain, but with
the amount of this throw diminished; and it is represented as dying out
in the granite. These are, however, assumptions. This fault will be
described in detail in considering the geology of Smuggler Mountain; but
it may be stated that its apparent displacement is to the east on the south
side; that its trend is east and west, and its dip about 30 degrees to the
south, and that the striz along this plane show that the movement has
been to the southeast on the south side of the fault, at an angle of about
45 degrees to the horizontal.

RESUME OF THE STRUCTURE OF HUNTER PARK.

First. The first deformation of the original strata was a heavy folding.
This resulted in a general steeply dipping monocline, which in the eastern
part of the district, near the contact with the granite, shows a flattening of
the dip and an approach of the strata to the horizontal. But the beds thus
dipping are often removed by erosion.

Second. Almost contemporaneous with the folding was the develop-
ment of the Silver fault, which runs very nearly parallel to the bedding,
but often cuts across it at a slight angle so as to remove whole formations.
Along the southern end of this fault many ore deposits exist; its age,
therefore, is premineral.

HUNTER PARK SPECIAL MAP. 131

Third. Next came the development of east-west faults, which seem to
be referable to two divisions The Lenado fault is apparently referable
to a distinet fault district which begins at the northern part of the Hunter
Park area and extends northward. The southern division begins with the
Alta fault, the extreme outlier of the complicated faulting which is central-
ized in the Tourtelotte Park area. All these faults have a general east-west
trend, although no two of them are strictly parallel. The Lenado and the
Alta faults are nearly vertical, but differ in trend, while the Della is a flat
fault, pitching to the south. In point of age these three faults seem to be
nearly alike, all of them having had an important movement since the ore
deposition, and so being in large part postmineral. The Della, however, as
will be shown, existed as a well-marked fault previous to the ore deposition,
while the Alta fault appears to have been very slightly developed at this
time, and there is no evidence that the Lenado fault even originated before

the mineralization.
DESCRIPTION OF SECTIONS.

(ATLAS SHEET XVIII.)

Section A——On the east side of the section the beds flatten to correspond
with the Lenado fold, and the various formations are well exposed in
outcrop. The Silver fault in this section separates the Leadville dolomite
from the Weber formation. The contact of Maroon and Weber is well
shown in outcrops, and from this contact west there is nothing but Maroon
beds in the section. The Lenado fault has been calculated to occupy
about the position shown.

Section B—he whole eastern part is in granite. On the hills along this
section, especially on the western part, there is much drift covering, but
the drift has been represented only in the valley of Hunter Creek, while the
rest of the area is represented by its bed rock.

The hill just west of Hunter Creek is shown in Pl. XV, and has
already been described. In the gulch west of it the Silver fault crops, and
a little west of this the Badger mine has gone down to the fault. On this
hill there outcrops above the granite the Cambrian quartzite, which is
overlain by the Silurian dolomite. The dolomite is here quite thin, and
is separated from the Weber shales by the Silver fault. The thickness of
shales in this section appears to be abnormally slight, but whether this is
due to the action of the Silver fault or to original deposition can hardly
be stated. The whole western end of the section is in the Maroon red beds.

132 GEOLOGY OF ASPEN MINING DISTRICT, COLORADO.

Sectionc.—This section shows at the outcrop of the contact of granite
and Cambrian quartzite a slight flattenmg of dip, but the flatter beds
above have been removed by erosion. Above the Cambrian there lies
nearly the whole thickness of the Silurian, but, as in the previous section,
the dolomite rests in outcrop against the Weber shales. The Parting
Quartzite does not outerop, but in the St. Joe shaft, which cuts the Silver
fault, it was discovered underground. The peculiar curve of the
Silver fault at this point, as represented on the section, and the manner in
which it cuts across the upturned strata, have actually been developed in
the mine workings. The contact of Weber and Maroon comes under the
drift-filled Hunter Creek Valley, so that the first outcrops on the north side
are of Maroon sandstones.

The section has been continued beyond the limits of the Hunter
Park map across the northwest corner of the Aspen special district and a
little up the side of Red Mountain, so as to give a more general idea. The
whole of this mountain side is in the uniformly dipping Maroon beds.

THE ASPEN DISTRICT MAP.

OUTLINE OF STRUCTURE.

In order to combine and to bring out the connection between the
special parts of the general mining region which have been described in
the 800-foot maps, a single large map was constructed, covering the areas
of these smaller ones and furnishing some additional information. In
reducing the 800-foot maps to the half-mile scale many of the details were
omitted, and the structure was thus generalized, but in all cases the
distinctive features were carefully preserved. In the complicated areas this
was especially necessary, as, for example, in Tourtelotte Park, where the
faults are so close together that they can not well be represented on the
scale of half a mile to the inch in such a manner as to be intelligible. A
variation in the plan of this map from that of the maps on the 800-foot
scale is the omission of the Recent or Glacial formations. In the space
between Aspen and Smuggler mountains, where the valley is filled with
deep glacial material, the connection between the rocks on the two sides
of the valley is not always well understood by the mining population. As
shown in this map, the relation of the two is not very difficult to conceive,
the apparent great difference being due to the uplift of the strata on Aspen

ASPEN DISTRICT MAP. 133

Mountain, which causes the outcrop of the sedimentary beds to advance
to the west. The north-south faults of the Aspen system are shown dying
out under the valley of the Roaring Fork. The exact point at which
these die out is, of course, not known, and they may extend farther into
the Maroon formation than has been represented; but in this formation
there is no means of tracing their extension, on account of the similarity of
the beds on either side.

This joming of the several maps brings out more clearly the salient
features in the structural geology of the district. As one looks at the map
and observes the comparatively narrow zone along which outcrop the beds
lying below the Maroon and above the basal granite, the most distinctive
feature is the contrast between that part of the belt north of the town of
Aspen and that part to the south. Throughout the Hunter Creek district
the beds maintain comparatively uniform strike and dip, and are not broken
to any extent by cross faulting. Southwest from this there comes in a
remarkable change at the town of Aspen, which is marked by the sudden
advance of the outcrops toward the west, by the change in the strike of
the beds from northeast to nearly north, and by the beginning of a series
of important and complicated faults. All these disturbances appear very
suddenly, and may be said to be centralized in the northern part of the
area of the Tourtelotte Park special map. The sudden advance of the out-
crops toward the west is due to the presence of the uplifted dome, which
apparently has its highest point in the northern part of Tourtelotte Park,
but has a steep face toward the north, so that it is practically wanting in
the Roaring Fork Valley. The change in the strike of the beds has no
apparent connection with this extremely local uplift. If one regards, how-
ever, the general line of contact between the granite and the overlying
beds from the northern part of the Hunter Creek area to the southern edge
of the district, it will be seen that this outcrop forms a single large curve.
Along this line the beds have a uniform dip away from the granite, except
where, as in the Tourtelotte Park area, this dip has been locally altered.
It may be, therefore, that all these beds are lying upon the flanks of an
uplifted dome, which was larger and had a more uniform and a gentler
uplift than had the more concentrated disturbance in Tourtelotte Park, and
that the Tourtelotte Park uplift was but a smaller and comparatively more
violent manifestation of the same uplifting force which caused the larger

134 GEOLOGY OF ASPEN MINING DISTRICT, COLORADO.

movement. At the extreme northeastern corner of the district there is an
area which is also faulted, and between this and the northern part of the
Hunter Park area the strike of the beds becomes more nearly north, devi-
ating considerably from the normal trend across Hunter Park. This
change in strike indicates an uplifting of the strata shown in Section G,
Atlas sheet VIL This uplifting is accompanied by faulting, and as ore has
also been found in this district, it may be that the disturbance was similar
to that of the Tourtelotte Park uplift. In the undisturbed region between
these two uplifts the rocks, so far as yet known, are practically barren of
mineral values.

The uplift of Tourtelotte Park and Aspen Mountain is one of the most
interesting structural features in the district. By comparing the amount of
uplift, as seen in the longitudinal section, with the corresponding difference
in throw of the Castle Creek fault at various points, it is seen that all the
uplifting has taken place subsequent to the formation of the fault, and that
the beds on the east have moved upward along it. The uplifted region
stopped short at the fault, the beds on the west side having had no corre-
sponding movement. On the west side the beds have a uniform northerly
pitch, which reveals successively lower strata toward the south. South of
the northern limit of the fault, as shown on the map, the formations occur
in normal succession, from the Laramie, through the Montana, Colorado,
and Dakota of the Cretaceous, the Gunnison formation of the Jurassic, the
Triassic, the Maroon and Weber formations, and even the intercalated sheet
of porphyry, which is found in the lower part of the latter; this porphyry
outcrops in the extreme southern part of this district, as the Laramie does
in the extreme northern part.

The beds east of the fault, however, have no uniform pitch, but show dif-
ferences at different points, forming a strong contrast with the uniformity of
the beds on the west. From the northern part of the district to Red Butte
there is a gentle northerly pitch, which is somewhat less than that to the
west of the fault at this place, so that the amount of displacement increases
northward from Red Butte. South of Red Butte there is a sudden steepen-
ing of the pitch on the east side. Near the pomt where the beds begin to
pitch most steeply there comes in a series of faults which, like the increase
in pitch, operate to upthrust the beds on this side of the fault. Thus West
Aspen Mountain is simply an isolated block which has been uplifted above
the surrounding strata between certain of these faults.

ASPEN DISTRICT MAP. 135

On the northern edge of West Aspen Mountain there is shown on the
map a series of cross fractures, which represent the slipping of the rocks
on the northern end of this block over each other while the southern end
of the block was being upthrust. The bending of strata and the faulting
were apparently developed at the same time and extend over practically
the same area, so that they are both probably the manifestation of a single
force, which tended to push the beds upward. The point of greatest
uplift, which is situated at about the top of Aspen Mountain or in North
Tourtelotte Park, is also the point of most intense faulting. The steep
northerly pitch on the north side of Aspen Mountain continues up to the
top of the mountain, or to the point of greatest disturbance. At this point
the attitude of the beds changes again somewhat abruptly, so that they
have no pitch, or a slight southerly one, and this attitude persists to the
southern edge of the district. Since on the west side throughout this same
district the uniform northerly pitch continues, it results that from Aspen
Mountain the displacement of the Castle Creek fault steadily diminishes
toward the south.

The amount of faulting at Red Butte has been computed at about
2,600 feet. On Aspen Mountain, near the center of greatest uplift, the
section shows a throw which has been increased by the differential dip of
the beds to the east and to the west of the fault, and by the upfaulting
of blocks immediately to the east to about 9,000 feet. South of this
point, however, the throw steadily decreases again, until near the southern
edge of the area it is only about 2,600 feet.. It appears from this that the
amount of movement along the Castle Creek fault has been about the same
at Red Butte and at Queens Gulch, while in the intervening space there
is a great, but purely local, increase, so that the throw becomes three and
four times as great as in these two places. ‘This crease is apparently
independent of the beds on the west of the fault, and is caused simply by
the uplifting of the dome which has been described on the east side, and
which has its center of greatest disturbance at the point of maximum
displacement along the fault. .

In the interval between Roaring Fork and the top of Aspen Mountain,
the longitudinal section (Section G, Atlas Sheet VII) shows an uplift along
the strike amounting to about 5,000 feet, caused by the combined effects
of folding and heavy faulting. The difference in the displacement of the
Castle Creek fault between the point where it is displayed at Red Butte

136 GEOLOGY OF ASPEN MINING DISTRICT, COLORADO.

and a point opposite the top of Aspen Mountain, which is the point of
ereatest disturbance in the uplifted beds lying to the east, is about 6,400
feet, as nearly as can be estimated. The amount of uplifting as shown by
the longitudinal section, therefore, is amply accounted for by the differen-
tial movement which has gone on along the fault. The inference from this
is that the main uplifting and faulting in this disturbed area has gone on
since the formation of the Castle Creek fault. The amount of increase in
the throw of the fault, producing its maximum displacement of 9,000 feet,
is due mainly to the increased steepening of the dip on the north side of
Aspen Mountain and to the associated faulting, while to the south of the
region of greatest displacement the dip changes, so that the rocks on both
sides of the fault tend to converge, and therefore the throw steadily
decreases. The local and enormous increase in the amount of displace-
ment is, therefore, to be entirely accounted for by this local uplifting on
the east side of the fault; and there is no evidence that the beds on the
west side have had any part in this movement.

The summit of the dome is traversed by an intricate system of faults,
which have their greatest development at the point of greatest uplift, but
are conspicuous and important over the whole of the uplifted area. North
of this area they disappear as quickly as the uplifting itself, while on the
south they disappear somewhat more slowly, as does the upliftmg. The
faults may be divided into two chief sets, one parallel to the axis of
greatest disturbance and to the Castle Creek fault, and a second at right
angles to the first. It is probable that both these originated simply as sets
of fractures and were formed at about the same time, but the maximum
displacement along each took place at different periods. This period must
be worked out from every fault separately, for movement has been going
on continuously from the formation of this uplift to the present day. As a
general rule, those faults which were parallel with the longest axis of the
uplifted dome, or which run in a north-south direction, had their greatest
movement at an earlier period than the other set; and the movement along
these has been greater than that along the others, as might be expected
along faults developed parallel with the axis of greatest disturbance. ‘The
east-west faults have less importance, and the amount of their throw in no
case attains anything like the proportions which are found in several of
the other set.

ASPEN DISTRICT MAP. 137

The intersection of these two systems of faults has produced many
blocks, and, in the process of uplifting, these blocks have often been moved
one upon the other in such way as to result in a very complicated structure.

The portion of the district which lies to the southeast of the areas of
the detailed maps which have already been described is entirely in gran-
ite and without important structure, so far as the present study goes, and
so need not further be dwelt upon. It is all glaciated and in places thickly
covered with morainal deposits. That portion which lies to the northwest
of the special areas includes, besides the formations already described, the
upper part of the Triassic, which consists of massive deep-red sandstones,
the sandstones and variegated shales of the Gunnison formation, and the
heavy sandstones or quartzite of the Dakota, which is throughout this region
the lowest member of the Cretaceous. Above these comes the Colorado
formation, which is capable of division into its two members, the Benton
and the Niobrara. Above the Niobrara comes the Montana formation, con-
sisting of a great thickness of black shales, and above this the lower part
of the Laramie, which is the youngest pre-Glacial formation shown in the
district. These formations are crumpled into folds, in part overthrown, in
the immediate vicinity of the Castle Creek fault, but these die out in a sur-
prisingly short distance westward, the beds assuming a horizontal or gently
dipping attitude. The chief feature in the folding immediately west of the
fault is a northerly pitching syncline. In the central part of the district
this syncline is closely compressed and overturned, while in the northern
and southern parts it is open. The general structure of this fold and its
relation to the Castle Creek fault may best be seen from the study of the
accompanying sections.

DESCRIPTION OF SECTIONS.
(ATLAS SHEET VII.)

Section A——The eastern part of Section A has already been shown on a
larger scale in a cross section through the Lenado maps, where the steeply
dipping Cambrian and Silurian rocks are seen to lie upon the uplifted
granite. These are cut off by the Lenado fault, which brings the Weber
formation in outcrop against the Parting Quartzite. Westward from this
outcrops the whole of the Maroon formation, which is overlain by the
Triassic. The Triassic is continuous from the point of its contact with
the Maroon to the Castle Creek fault. There is probably, as is shown by

138 GEOLOGY OF ASPEN MINING DISTRICT, COLORADO.

observation farther north, a slight syneline in the red beds against the fault
at this point. On the west side of the fault there outcrops the top of the
Montana formation, and a short distance farther west comes the contact of
Montana with Laramie. The throw of the fault at this point is estimated
at about 5,500 feet. The beds to the west form a comparatively shallow
syncline, which, so far as is known, is not at all overturned. The Laramie
sandstones which outcrop along this section show that this fold is really in
the nature of a synclinal basin, for the dip is toward the center on all sides.

Section B.—In this section the Lenado fault is shown with a lessened
throw. This location of this fault was not actually made in the field, but
by extension from its known outcrop. In these uniform red beds there is
no possibility of determining accurately any extensive fault. As in Section
A, the steeply dipping monocline which lies to the west of the granite core
of the Sawatch changes into a gentle syncline at the Castle Creek fault.
On the west side of the fault the shales of the Montana outcrop, while
a very short distance below the Niobrara, Benton, and underlying forma-
tions are represented as running into the fault. This representatio1 is
based upon the actual outcrop of these beds a little farther south, where
the general northerly pitch of the fold brings them to the surface.

Section c-—This section illustrates the nature of the Castle Creek fault
and the folding in the beds on both sides of it. Nearly all its features are
based on reliable data. The slight synclinal fold in the red beds east of
the fault is shown by outcrops on the flanks of Red Mountain. The
prominent hill to the west of the fault is Red Butte, and on the steep side
of this hill the different formations as represented, namely, the top of the
Triassic, the Jurassic, the Dakota, the Benton, Niobrara, and the Montana,
are actually found in outerop, lying in the reverse of their usual order
and dipping to the east. The representation of the rocks west of Red
Butte is based upon an almost continuous section along the river bank
and railroad cut. The fold, as shown by these exposures, becomes very
gentle a short distance west of the fault, so that the beds have only a
slight easterly dip. A short distance west of this section the dip gradually
changes so as to form a slight anticline, the western limb of which has a
gentle westerly dip.

Pl. XVI is a view taken looking west from near Red Butte. In the
center of the foreground is the valley of the Roaring Fork, while the ridge

“SLING G3aY 30 1SAM V3Yv SNOSOVL3EYO

AX “1d IXXX Hd VHYSONOW AJSAYNS 1V9INO1OSD *S “NN

ASPEN DISTRICT MAP. 139

on the left is Red Butte itself, although the different formations can not be
distinguished. In the distance the uniform, gentle, north-facing slope of
the hills is identical with the dip of the rocks which form the north limb
of the gentle anticlime referred to.

The section as described seems to show that at the point of maximum
disturbance there once existed a sharp, compressed anticline, which was
overturned to the west, and that along the axis of this anticline the great
fault developed. It is a marked feature of this folding, as compared with
that of other closely folded areas, that it is confined to a narrow zone, east
and west of which the beds are comparatively undisturbed.

Section D.—Section D passes through the central portion of the uplifted
area in Tourtelotte Park. In this area are shown the minor folds and the
numerous faults generalized from the special maps, and east of this there is
nothing but Archean granite. In this section the Castle Creek fault sepa-
rates the granite from the Triassic sandstones, its vertical displacement
being about 9,000 feet. The beds west of the fault are still overturned,
having a steep easterly dip. The structure of the ridge which lies between
Maroon Creek and Castle Creek shows that here there is a slight anticlinal
which has no counterpart in Section C. In the western part of the section
the beds have a gentle easterly dip, which corresponds to the similar dip
in the western part of Section C. The outcropping Dakota sandstone runs
along the surface west of Maroon Creek.

Section E—'The extreme east end of the section is somewhat beyond the
limits of the map, bemg the point where Difficult Creek runs into Roaring
Fork Valley. At this place is granite, which continues to near the top of
Richmond Hill. The strata exposed on this hill belong to the lowest por-
tion of the sedimentary series, and constitute a west-dippine monocline.
The faulting connected with the Tourtelotte Park uplift is also shown. West
of the Castle Creek fault the beds are still slightly reversed, having an east-
erly dip which approaches the vertical. It is near this point, however, that

‘the beds overturn and resume their normal succession. The Weber forma-
tion outcrops directly west of the fault, being brought up by the northerly
pitch of the fold, and from here to the top of the mountain between Castle
Creek and Maroon Creek there is apparently nothing but Maroon beds, but
the top seems to be formed of the heavier and brighter red Triassic sand-
stones. The syncline, in the bottom of which, as in the previous section

140, GEOLOGY OF ASPEN MINING DISTRICT, COLORADO.

(Section D), Castle Creek flows, has become broader and is slightly over-
turned against the fault, while the anticline between Castle and Maroon
creeks is still present and has become shallower and broader.

Section F—Just east of the eastern end of Section F granite outcrops, the
distance between it and the Castle Creek fault being very slight. The
sedimentary beds on the east of the fault constitute, as in Section E, a
gentle, westerly dipping monocline. Immediately west of the fault the
beds have a steep but uniform westerly dip, and lie in their normal succes-
sion. Owing to the northerly pitch of the fold, there are brought into
outcrop Weber shales, with the intercalated sheet of porphyry which
usually lies at this horizon. The Weber formation is overlain by the
Maroon, which is continuous to the end of the section, with the exception
of the very top of the mountain between Castle Creek and Maroon Creek,
where the Triassic probably comes in. The general structure of the fold
along this plane of section is that of a well-marked but open syncline, in
the bottom of which Castle Creek lies. The relative structure of the beds
on the east and on the west side of the fault along these different sections
‘is obscured in large part by the subsequent local uplifting and faulting
throughout the southern part of the area immediately east of the Castle
Creek fault. But on comparing this section (Section F) with Section ©, it
is seen that on the disappearance of the overturned syncline on the west
there also disappears the slight open syncline on the east; so that from the
compressed folding at Red Butte there is a change to a more simple structure.

Section G—Section G is drawn as nearly as possible parallel with the
general strike of the beds throughout the district, and reaches from
the extreme northeastern corner of the district shown on the map to the
western side of the Castle Creek fault south of Aspen. It shows in its
central part a nearly horizontal intersection with the different beds, while
the southernmost part is conspicuous on account of the uplifting and
faulting. In the northeastern part there is a similar but not so sudden
uplifting, which is also accompanied by faulting, although to a less degree.
The relation of the Silver fault to the sedimentary beds, as it varies from
point to point, is better seen here than in any of the cross sections. In
the northeastern part of the section it separates the Weber shales from the
Leadville dolomite, and the distance between the fault and the Parting
Quartzite is comparatively slight. In the Hunter Park area the fault cuts

‘NIVLNMOW G3Y GNV ASTIVA Y33Y9 SILSVO

th

S

Pp
D

as

WAX “Id IXXX HdVYSONOW ASAYNS 1V9ISOIO3S “Ss “nN

ASPEN DISTRICT MAP. 141

down into the formations, so that there is found on its lower side the
Silurian dolomite, with the Cambrian quartzite not far below. The Weber
formation, however, is still on the upper side. This cutting down of the
fault is only local, for farther southwest it cuts up across the Parting
Quartzite into the Leadville dolomite. The line of this fault throughout
the Hunter Park region, as compared with the line of the formation
beneath, is suggestive of unconformity, and, as has been stated, there was
actually some unconformity at this period. It is certain, however, that
this plane is representative of a true fault, and that the fault is a heavy
one, for it is marked by great brecciation. It may be that some uncon-
formity existed previous to the faulting, and that the disturbance simply
caused the Weber sediments to slide over the beds which lay beneath, or
it may be that the disparity in the beds was not always so strongly marked
as now, but was brought about by the removal of some formations through
the faulting. The only positive facts are that there was a heavy fault
along this plane, and that along this fault certain formations have locally
been removed.

In the southwestern part of the section is a heavy porphyry sheet,
which lies very close to the Silver fault, being separated from it only by a
thin and variable sheet of broken shale. Only the main faults are shown
in this section, such as the two chief faults at Lenado, the Della fault on
Smuggler Mountain, and the principal faults of Aspen Mountain. These
are, however, such as bring out the actual structure best.

By putting all the cross sections together the general structure of the
beds on the west side of the Castle Creek fault is seen to be about that of a
permanent synclinal fold. In Section F, in the southern part of the district,
the fold is deep, broad, and open. ‘Toward the north it becomes somewhat
shallower, but also more closely compressed, and is overturned throughout
the central part of the area, while in the northern part it again becomes
open, and is here still shallower.

The fault itself is continuously traceable throughout the whole district.
In the extreme southern part, in Section F, its throw is only 2,600 feet,
while in Section E it has increased to about 6,300 feet, and in Section D to
9,000 feet. This last point, which is opposite Aspen Mountain, is the point
of maximum throw. Pl. XVII gives a view looking down Castle Creek
across the Roaring Fork Valley to Red Mountain. On the right-hand side

142 GEOLOGY OF ASPEN MINING DISTRICT, COLORADO.

of the valley, where Castle Creek runs into Roaring Fork, is the point of
West Aspen Mountain. The rocks on this mountaim which are shown in
the picture are Archean, Silurian, and Cambrian, and the Castle Creek fault
runs along the base of the mountain, parallel to and just east of Castle
Creek. The whole of the left-hand side of the valley is of bright-red
Triassic sandstone, which has a dip of 50 degrees or so toward the east,
forming part of the overturned fold which lies against the fault. From this
point the fault pursues a comparatively straight course, crossing the Roaring
Fork Valley and running across the southeastern end of-Red Butte.

Pl. XVIII is a view taken from near Red Butte on the northeast side
of Roaring Fork. The river and the butte occupythe foreground. In the
center of the picture is the flat Roaring Fork Vale. y, with Aspen at the left
side. The even terrace which the river has carved in post-Glacial time is
very well seen. In the background is Aspen Mountain, the projecting
ridge of West Aspen Mountain just left of “he center. The woody gulch
on the right side of Aspen Mountain is Keno Gulch, across which, as
described, the Castle Creek fault runs. In this picture the Castle Creek
fault runs from Roaring Fork, across the southern point of Red Butte,
south-southeast for 14 miles, and just to the right of the smokestack on the
lixiviating works, then swings to the south and crosses Keno Gulch, and so
on out of the area represented on the plate.

From Red Butte the fault continues northward over the gently sloping
western side of Red Mountain to Woody Creek. Pl. XIX shows this part
of Red Mountain. The view is taken from the west bank of Maroon
Creek at Red Butte. The sharp ridge in the foreground is the north-
western extension of the butte, and along this ridge the outcropping beds
of the Triassic, Gunnison, and Lower Cretaceous formations dip steeply to
the east and are overturned, as shown in Section C. The ridge separates
Maroon Creek from the Roaring Fork, and the two streams unite just to
the left of the pictured area. The fault runs diagonally across the pictured
area from behind the ridge of Red Butte at the right to near the western
edge of the horizon, which it crosses at about the point where the short,
level outline changes to a slope. Along this mountain side the fault is
often obscured by the heavy covering of glacial drift, but its course is
made sufficiently clear by occasional outcrops, which show that it separates
the Triassic sandstones on the east from the Montana shales on the west.

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WAX "1d I1xXX Hd VHYSONOW ABZAYNS 1VIIEO1039 “Ss “Nn

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ASPEN DISTRICT MAP. 143

On a hill overlooking Woody Creek the base of the Laramie is brought
down on the west side of the fault, so as to abut against the Triassic sand-
stones on the east. From its northern termination, as shown on the map, |
the fault can be traced along the northeast side of Woody Creek for some
distance. Its course is marked by a large amount of gypsum, which forms
a continuous white zone along it. Just below Woody station there is a
prominent hill jutting out from the Roaring Fork Valley on the northeast
side, and through this the fault appears to run. Only a hasty examination
was made, but the Dakota and Niobrara formations on the southwest
appear to abut against the Triassic red sandstones on the northeast. The
top of this hill is a dark, vesicular basalt; according to Holmes,' this basalt
has risen along the fault. No attempt was made to trace the fault farther
northwest than this point. The southern extension of the fault, also, from
the point where it leaves the area of the Aspen district map, in the vicinity
of Little Annie mine, has not been looked for, but it probably grows con-
tinually less, and if it keeps its normal course runs into granite on both
sides and is lost.

RESUME OF STRUCTURE IN THE ASPEN DISTRICT.

The initial disturbance in the rocks in the Aspen district seems to
have been a general folding. This folding took place certainly after the
deposition of the Laramie, and also after the intrusion of diorite and quartz-
porphyries into the sedimentary beds. It probably followed very close,
however, upon this igneous intrusion. The deformation seems to have
been due to a lateral thrust which pushed the sedimentary beds against the
hard resisting mass of the Sawatch Mountains. The cause of this lateral
thrust was probably the uplifting of the Elk Mountains to the westward,
which in turn was due to the intrusion of large masses of molten material
upward into the sedimentary beds along a line of weakness. A continuation
of the same force, therefore, which thrust the intrusive rocks into the sedi-
mentary beds brought about the folding and breaking of these intrusive
sheets along with the inclosing strata. The disturbance arising from the
lateral thrust is restricted to a comparatively narrow zone, running parallel
to the main axis of the Sawatch. The greatest folding occurred along a
still narrower zone, at some short distance from the granite. Along this

'Report of the Hayden Survey, 1874, p. 60.

144 GEOLOGY OF ASPEN MINING DISTRICT, COLORADO.

zone there was heavy folding, which resulted in the overthrust, easterly
dipping, and northerly pitching folds of the Aspen district. These folds
appear to have opened out to the north, and, as at present exposed in
outcrop, are also open to the south. It is possible, however, that the
compression was more intense in the upper sedimentary beds than in the
lower ones, and therefore that those portions of the folds which are now
open, in the southern part of the area, may have been closed and over-
turned in the overlying sedimentary beds which have been removed by
erosion. Between this line of greatest folding and the granite there was a
series of slight open folds, which often are hardly recognizable and again
are very noticeable. West of the line of folding there is very little defor-
mation, the disturbance dying out in a surprisingly short space, so that the
beds resume a horizontal or gently dipping attitude.

The folding along this line culminated in a fault which appears to
have originated along the axis of an overthrust anticline, and to have
extended to the south and to the north along the line of maximum strain.
This is called the Castle Creek fault. :

Silver fault system —At the time that the folding in the beds was going on,
certain of the more rigid of the formations slipped upon certain others,
forming a number of bedding faults. Some of these faults were parallel
to the bedding, while some of the larger ones were not always parallel,
but ran locally at a slight angle to it. There are many of these faults,
but they are not often conspicuous, for the very reason of their parallelism
with the beddmg. In the Weber and Maroon formations they have not
been carefully traced, although in the Cowenhoven tunnel several faults
belonging to this system may be observed, a specially well-marked one
occurring at the contact of the Weber and Maroon. It is probable that
these faults are more important in the lower sedimentary beds than in the
upper, being caused by the slipping of the strata over the underlying, more
rigid granite. The most important fault of this system—the Silver fault—
occurs at the contact of the Weber with the underlying formations, and in
places has a certain amount of obliquity with the bedding planes. A short
distance below this fault is the Contact fault, which lies between the blue
limestone and the dolomite of the Leadville formation. This latter fault is
apparently much slighter, and, so far as observed, is strictly parallel with
the bedding. These faults of the Silver system probably originated earlier

‘NIVLNNOW G3Y 40 GNV 3LLNG Gay 40 3dIS 1SaM

|
XIX “Id 1IXXX HdVHDONOW ASJAYNS 1VOINO1IOAS ‘Ss ‘nN

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ASPEN DISTRICT MAP. 145

than the Castle Creek fault, and were faulted by it. They are very impor-
tant in studying the economic geology of the district, smce the ore has
been to a large extent deposited along them.

Tourtelotte Park uplitt— Immediately after the formation of the Castle Creek
fault, or perhaps synchronously with it, there began an uplift such as
would arise from a vertically exerted force. This was a doming-up of the
rocks just east of the Castle Creek fault, extending north and south over
a limited area. The movement did not affect the rocks to the west of the
fault, and thus the throw is correspondingly increased in the region of
uplift. The summit of the dome is in the northern part of Tourtelotte
Park, while the abrupt north side is on Aspen Mountain and ends very
suddenly in the Roaring Fork Valley; the south
side of the dome is gentler, and its structure
is obscured by erosion, which has brought the
granite to the surface. his uplift affected the
granites as well as the sedimentary formations,
but in the granite there is no means of meas-
uring it, or even of ascertaining its existence.
There are indications of a similar tendency
toward local uplifting or doming at Lenado.

Faulting —With the beginning of the forma-
tion of this local dome there also began a

system of local faulting, which continued
from that time to the present. The first-formed
system was parallel with the Castle Creek fault, and ihe faults belonging
to it have a heavy throw, which is most pronounced on Aspen Mountain
and diminishes from this pomt more or less rapidly to the north and to the
south. At the same time there were formed many fractures without impor-
tant throw, some of them being north-south and parallel with the actual

Fia. 5.—Fractures in Weber limestone.

faults, while others ran across in an east-west direction. In this way the
summit of the dome, and, to a less extent, its sides, were profoundly frac-
tured. Some graphic idea of this fracturing may be gained from the
accompanying figure (fig. 5), which is from a photograph (natural size)
of a small piece of thin-bedded Weber limestone. This specimen came
from Tourtelotte Park, where faulting on a large scale is most pronounced,

and it represents so closely in miniature the complicated fracturing which
MON XXXI——10

146 GEOLOGY OF ASPEN MINING DISTRICT, COLORADO.

this district has undergone that it seems both the minute fractures and the
larger faults must have resulted from the same cause. In closely folded
regions it has already been demonstrated that the slight wrinkles or flutings
in rocks have an intimate connection with the more important system of
folding, and may often be used in deciphering this system. On studying
the fracture planes in the specimen figured, and in other specimens from
the same locality, the conclusion is forced upon one that this finer structure
may be taken, in a guarded way, as indicative of the more general system
of fracturing and of faulting on a larger scale. Almost every feature con-
nected with the fracturing in this specimen (and they can not all be well
seen in the reproduction) finds its parallel in the peculiar system of fault-
ing in Tourtelotte Park. The different blocks which these fractures make
by intersection have been brought into relief by shght weathering, which
has removed more iron from certain blocks than from others, and so
produced a difference of coloring, which brings out the structure strikingly.
Careful observation will show that there are not only different systems of
fracture in this specimen, but movements of Citerem ages, for some of
them have slightly faulted others.

Mineralization —Immediately following this faulting and fracturing at the
beginning of the uplift came ore deposition. Ores are now universally
found along these faults and fractures, either in vertical faults or, more
commonly, at the contact of vertical ones with those which are parallel to
the bedding. The ore was deposited as sulphide, and the mineral-bearing
solutions evidently: circulated along the channels which the faults and frac-
tures offered. The epoch of ore deposition was short compared with that
of the faulting, for we know that the faulting has heen continuous, and can
trace several distinct systems which have developed successively from the
earliest period to the present. The first-formed systems are ore bearing,
showing that they existed at the time of the presence of the mineral-bearing
solutions. The later systems are, however, barren, and evidently no ore-
bearing waters have circulated along them. ‘This refers, of course, to the
main or primary mineralization. There is always going on a secondary
deposition of ore, due to the rearrangement of the first-deposited minerals,
but this process is comparatively unimportant.

Fault systems.—After the formation of the first or north-south system of
faults, which we may call the Aspen Mountain system, the next in point
of age was the Della system. These faults are not numerous, and have no

ASPEN DISTRICT MAP. 147

great throw. They have an east-west trend and a dip to the south of about
30 degrees. The phenomena along these faults tend to show that they
originated previous to the ore deposition, but continued after it, so’ that
they belong in a later system than do the Aspen Mountain faults, which
appear to have been almost entirely developed before the cessation of this
process. According to Mr. D. W. Brunton, who has made a careful study
of the Della faults, about three-fourths of the movement occurred since the
ore deposition. .

Next in the order of development of faults seems to have come the
Tourtelotte Park system, which has a north-south trend and a nearly ver-
tical dip. The faults of this system have their greatest throw in Tourtelotte
Park and diminish toward the north and to the south. They have appar-
ently been developed entirely since the close of the ore deposition, and are
therefore barren.

Belonging to a slightly later date than the north-south Tourtelotte
Park system are the east-west faults of Tourtelotte Park, which constitute
the Butte system. This system, although probably it originated at about
the same time as the north-south Tourtelotte Park faults, has apparently
had its greatest activity at a slightly later period, and some of its faults
have developed entirely in post-Glacial time. This is the most recent of
all the fault systems, and the disturbance is still going on. Most of the
other faults in the systems previously enumerated are still moving slightly,
but not to such great extent as the Butte system. The universal motion
shows, however, that the Tourtelotte Park uplift is still slowly progressing.

Cause of uplift—'The most interesting feature in the structure of this
district is the local uplift which has caused the formation of numerous
faults, and, indirectly, of the ore deposits, for along these faults the ore-
bearing solutions have circulated, and there they have deposited their load.
This uplift is purely local and has no apparent reference to the structure in
the surrounding rocks. It does not seem probable. therefore, that it has
been formed by regional stress or by any lateral thrust, but is such as
might be formed by a vertical push from below by some restricted force.
The period at which its formation began was one of intense eruptive
activity. Immediately previous the diorite-porphyry and quartz-porphyry
were intruded into the sedimentary rocks. The diorite-porphyry has been
shown to be probably an outlying sheet connected with the main dioritic
mass of the Elk Mountains, while the quartz-porphyry has apparently

148 GEOLOGY OF ASPEN MINING DISTRICT, COLORADO.

close genetic connection with the eruptive rocks of the Mosquito Range,
on the opposite side of the Sawatch. As already described, there have
been found at Aspen dikes of porphyry which come directly across the
sedimentary formations and connect with the overlying sheet. These
dikes were found in the Bonnybel, Smuggler, and Park Regent mines. In
the first named of these mines the dike sends out thin and limited sheets
into the Carboniferous dolomite before reaching the horizon at which
the main sheet spreads out. It has been concluded, therefore, that the
porphyry at Aspen came up directly from below and was derived from
some larger reservoir. Throughout the whole of this western mountain
region igneous rocks are common as sheets, as lenticular bodies or
laccoliths, and even as cylindrical pipes or ‘‘plutonic plugs,” as described
by Russell. The same quartz-porphyry, or a rock very closely related,
forms laccoliths on the Mosquito Range, and thick sheets, such as are seen
at Leadville. A possible explanation of this Tourtelotte Park uplift would
be that igneous rocks, probably derived from the same reservoir as the
previously intruded porphyry, accumulated in a restricted area; that
upward propulsion of this rock elevated the overlying rigid formations,
and that this uplift caused the fracturing and faulting. We may conceive
that if this upward tendency of the molten rock beneath had been actively
continued, the rock would have forced its way to the surface, and what is
now the limited, faulted, uplifted dome would have become the neck of a
voleano. Actually, however, no rock was erupted, although, as previously
noted, there is a late eruption of basalt along the (Casille Creek fault a few
miles farther northwest, near Woody Station.

Rate of faulting —One of the most striking things in the geology of Aspen —
is the evidence of great activity in the deformation of the rocks, both in
the past and in the present. This evidence offers, perhaps, an opportunity
for estimating the rate of movement along these active faults. Mr. D. W.
Brunton, in a letter written to the author, makes the following interesting
observations concerning recent fault movements:

That the movement along the fault planes is now going on is plainly proved in
a great many ways. Survey monuments, which have been located by different
engineers with exactitude, are now in some instances 4 and 5 feet from the position

they occupied ten years ago. The upper portion of many shafts in the camp has
been moved entirely across the lower portion, in some instances shutting off com-

1 Jour. Geol., Vol. IV, pp. 25, 189.

ASPEN DISTRICT MAP. 149

munication with the bottom end of the shaft, and in others, where mining has been
going on steadily, the two disjointed ends are connected by a short incline. Where
the Della 8. fault passes up through the Park Regent there is one drift along the
line of this fault. The square sets with which this drift is timbered assume the
form of rhomboids so rapidly that the superintendent, in order to avoid trouble with
the track, laid the rails on short ties instead of spiking them to the square-set sills,
so that the track could be kept up level without any reference to the timber sets
inelosing the drift. J inelose a little sketch [fig. 6] showing the timbers as they
were originally placed and the position of the timbers after they have been in posi-
tion from one to two years.

DOLLA DELETION ELL A aM IN LY GGLL090 YGSOOVPILAIELEOOPATU GCA OL A OTM YLT ITIL
Seen ep ey POLLS 2; Let pespgsgEsd VLOCGIGDLIEGLOC ATID ALTGELD TT CILIGE
GLEE ELE:

\

N

NS

\S

MQ
SWQAVY
W

\ \ RAN
NAY
SAAN

UK
SSMAVAWY
AWS SN
QQ
LIRQNAAYY

\
\:
\
SS
AWN
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WY
\ W \

Fig. 6.—Deformation of drift in Della S. mine by movement along fault.

In the Butte fault in Tourtelotte Park there seems to have been a
movement in post-Glacial time of at least 400 feet. If, then, we can arrive
at any approximation of the period which has elapsed since the disappear-
ance of the ice sheet, we may have some measure of the recent rate of fault-
ing. Warren Upham,’ after correlating the various estimates as to the
period which has elapsed since the disappearance of the continental ice
sheet from the northern half of North America, comes to the conclusion that
it may safely be estimated at between six thousand and ten thousand years.
Glaciation in the Rocky Mountains has been considered somewhat more
recent, but the country around Aspen bears evidence of profound glacial
activity in no very recent times. The whole of the district mapped has
been glaciated, and the ice sheet must have been of enormous thickness,
since it filled up the Roaring Fork Valley and overrode Smuggler, Aspen,

1 Pop. Sci. Monthly, Dec., 1893, p. 161.

150 GEOLOGY OF ASPEN MINING DISTRICT, COLORADO.

and Red mountains. After the disappearance of this vast ice sheet there
was a comparatively quiet period, during which erosion went on rapidly and
the river valleys were filled with local glaciers, which formed distinct and
later moraines. In many cases the débris of this earlier ice sheet has been
stripped by erosion from the mountain sides and is found only on top, as
in the case of Red Mountain. In other places it has probably been entirely
remoyed. This amount of erosion, even taking into consideration the actiy-
ity with which material was removed in this mountainous region, indicates
that the main ice sheet disappeared at no very recent period. We may
therefore assume that the minimum figure given by Upham represents the
period of post-Glacial time in the Rocky Mountains, namely, six thousand
years. If the Butte fault has moved 400 feet in that time this would make
arate of about 1 foot in fifteen years. This rate is the maximum, so far as
is actually known, of present movement, and in estimating the rate of the
faulting as a whole other considerations come in. At the beginning of the
uplift and faulting there was a great load of overlying rocks in the uplifted
areas and this load rendered faulting slower and more difficult. The load
amounted to at least 15,000 feet of strata on the east side of the fault at
Tourtelotte Park. These 15,000 feet are all exposed in the district just
west of the fault, but on the east side are stripped away by erosion, which
has usually kept pace with the uplifting and faulting, though often lagging
behind. The disturbance which began under this heavy load consisted in
the upbending of the strata, with few fractures, but along these few the dis-
placement was important. With the stripping of the strata there developed
more numerous faults, which, however, had in general slighter movement.
Thus the intersecting faults in Tourtelotte Park are numerous and compli-
cated, but are all comparatively late in origin. So the rate of the fault
movement at the present day, which has been approximated at a maximum
of 1 foot in fifteen years, is probably the maximum for the whole period of
deformation. It has been roughly estimated that about two-thirds of the
faults originated since the ore deposition, but the premineral faults are
characteristically heavier, and from the considerations above stated it seems
probable that the ore deposition lasted through two-thirds or even more of
the time from the beginning of the uplift to the present day. Thus the ore
began to form under not more than 15,000 feet of sediments and probably
ceased when covered with 5,000 feet or less.

COBIAN IE apis IE EAL.
DESCRIPTION OF MINES AND PRODUCTIVE LOCALITIES.

In the preceding chapter the general geology of the Aspen mining
district has been discussed. Within this district are certain segregated
areas to which the actual ore production has been almost entirely confined,
and where most of the mines are located. In the most important of these
localities the geology has been more accurately determined, thanks to
the numerous opportunities offered in mine workings, and special maps
of these localities have been made on the 300-foot scale.

ASPEN MOUNTAIN.

One of the areas of greatest production is the north slope of Aspen
Mountain, between Tourtelotte Park and the town of Aspen. In the east-
ern limb of the synclinal fold of Aspen Mountain there is a continuous
series of underground workings, reaching connectedly from the level of the
town up to the top of the mountain. In this particular region the Contact
fault between the blue limestone and the dolomite has been considered the
most favorable place for exploration, and hence this fault, or “‘contact,” as
it is called, has its outcrop marked the whole distance up the hill by a
continuous line of tunnels. From this outcrop the workings have often
gone downward along the dip to a great depth, as is especially the case in
the Aspen mine.

Bonnybel mine and Visino tunnel. (See Pl. XL, A).—This mine is situated in a
small downfaulted block which is bounded on the east by the Bonnybel
fault and on the west by the Chloride fault. These faults dip to the south-
west and converge in dip and in trend, so that they probably unite in
depth and merge into the Silver fault. The downfaulted block is marked
on the surface partly by the Parting Quartzite beds. he course of these
beds seems to be comparatively normal from Spar Gulch southward nearly

to the Bonnybel mine, but here the outcrop is faulted down the hill for
151

152 GEOLOGY OF ASPEN MINING DISTRICT, COLORADO.

some little distance. <A little farther on, however, on the south side of the
downfaulted block, the quartzite resumes its original position. Farther up
the hill this block is characterized by the Weber shale which lies in it,
between the blue limestone on the north and that on the south. The
block between the two main faults is not simple, but is cut by very many
slips, which are in a general way parallel to those that bound the block,
so that actually the block is a sort of downthrust shear-zone in which the
rock is cut into thin slices. Besides these parallel faults there are also
minor slips running in all directions. A peculiar feature in the structure is
the absence of the blue limestone in the Bonnybel mine, for here porphyry
and Weber shale directly overlie the Leadville dolomite. That this dolo-
mite probably belongs to the permanent and original bed which forms the

lower portion of the Leadville horizon is indicated by its estimated thick-.

ness, which is that usually found in the Leadville dolomite. There is
evidently, therefore, a fault which here locally cuts out the blue limestone
and brings the Weber formation down upon the dolomite below. This is
the condition of affairs in the northern district, from the bottom of the
Roaring Fork Valley to Lenado, and it results from the action of the
Silver fault. Throughout Aspen Mountain and Tourtelotte Park, however,
there is usually blue limestone between the dolomite and the shale. In
the outcropping cliff on either side of the downfaulted block in which the
Bonnybel mine is situated there is continually shown the usual Contact
fault overlain by the blue limestone, and thus it is in this block alone that
the limestone is missing. The fault, therefore, can be only a local one.
Another unusual and especially interesting feature of the mine is the
occurrence of porphyry in the dolomite in the form of a large crosscutting
dike and of small interbedded sheets. The dike seems to be nearly
vertical as exposed at many points in the workings, being present in the
rock as far down as explorations have gone, or nearly to the horizon of the
Parting Quartzite. From this dike there run off one or two interbedded
sheets, perhaps more. ‘These sheets are cut in the main workings, and have
always altered the dolomite along their contact for several feet to a coarsely
crystalline, nearly white marble. This is the only place in the district
where porphyry sheets have been found at a horizon lower than the Weber.
In the dolomite, however, these sheets are small and thin, and no important
thickness is found till the horizon of the Weber shales is reached, at which

ASPEN MOUNTAIN. 153

horizon the porphyry has spread out more or less irregularly, and includes
fragments of the shale.

Nearly the whole of the dolomite in this downfaulted block has been
highly mineralized, so as to form ore of greater or less richness. The
richest ore, however, lies in irregular shoots which are parallel with the
main faults, dipping steeply to the southwest and having a northwest trend.
These rich shoots lie very close together, as seen in the Visino workings,
and from them an immense amount of ore has been taken out. At the
surface, in the middle of the block, the ore was first discovered in out-
crop, and here $110,000 worth was taken from the great Bonnybel open
stope, without timbering. This stope seems to occur between two parallel
faults of the main system. ‘The richest ore is in the southwest side of the
block, where the faulting seems to have been greatest. In the Bonnybel
fault, which bounds the block on the east, only one pocket of ore has thus
far been found, that in the Forest tunnel.

The occurrence of the ore in the Bonnybel is noteworthy among that
of the other mines of the district, in that nowhere else has the rock been
mineralized to such a degree. In other mines there are small bodies of ore
far richer than that in the Bonnybel, but here not only has the whole rock
been transformed into low-grade ore, but the mineralization is in distinct
steeply dipping shoots which cut across the formations. The explorations
are now not far above the Parting Quartzite and there is still rich ore in
sight, so that it is hard to tell how much farther down the ore deposits will
extend.

The ore itself is a mineralized, broken dolomite containing much
barite, and so far is all oxidized. A little native silver has been found.

Durant mine—The Durant is connected with the Bonnybel by the Visino
incline, which in descending runs to the westward with the dip of the
rocks. This mine is situated on the east limb of the Aspen Mountain syn-
cline and near the summit of the Tourtelotte Park uplift, where the steep
north face of this uplift begins to flatten in Tourtelotte Park. As the
result of this position there occur in the mine many small fractures and
cross faults, which complicate the structure very much and render scientific
mining absolutely necessary. The eastern limb of the syncline becomes
very steep a little below the surface, turning down so as to become vertical,
and even locally overturning so as to dip to the east. After this sudden

154 GEOLOGY OF ASPEN MINING DISTRICT, COLORADO.

steepening the beds recover and assume a flatter westerly dip, which sud-
denly changes to a very gentle dip in the bottom of the syncline. Near
the point where the dip changes there is developed the Aspen fault, vertical,
and with only a slight throw, which is down on the eastern side. The
workings of the Durant mine show this structure well, the whole of it
having been accurately demonstrated from the surface to the bottom of
the syncline. Most of the workings lie in a comparatively narrow zone
between the vertical Aspen fault and the Contact fault, which is here
turned up with the beds so as also to be vertical and for a long distance
parallel with the Aspen fault. West of the Aspen fault there is developed
in the workings another fault belonging to the same system, namely, the
Schiller. There are many smaller faults parallel to these greater ones, and
also many complicated cross slips and intermittent fractures. Many of these
occur between the Aspen and the Contact faults. They have been admira-
bly and carefully worked out by Mr. Rohlfing, the superintendent of the
mine, but are not of sufficient importance to be dwelt upon in this general
summary. The Silver fault is also cut in the southern part of the workings,
but has nowhere been very greatly explored.

The ore has been found chiefly in the narrow vertical zone between the
Aspen and Contact faults. On account of the northerly pitch of the Aspen
Mountain syneline, the point where the steep eastern limb of the syncline
flattens out to form the bottom of the fold becomes gradually deeper toward
the north; and for this reason the narrow vertical zone which is highly
productive in the Durant mine extends still farther downward in the Aspen,
where it has been followed nearly 1,500 feet from the surface before the
bottom of the syncline was reached. In the Durant ore has formed in
immense bodies, especially along the various faults and fractures. Of
these there are many, and «those which have a slight throw or no throw
at all are apparently as important in forming ore as are the greater ones,
showing that the only effect which a fault has in the formation of ore is to
furnish a channel through which the ore-bearing solutions may circulate.
The ore is nearly always found in the dolomite at the intersection of one
or more of these faults with the Contact fault. In such cases ore may
occur above the Contact fault in the blue limestone, when it is generally
surrounded by an envelope of dolomite, the dolomite in turn being sur-
rounded by limestone. In one case lead ore was found directly in the

ASPEN MOUNTAIN. 155

limestone with no dolomite envelope, but on analysis the ore was found
to contain 5 or 10 per cent of magnesia, while the limestone around it
contained none. These facts indicate that dolomization was, in part at
least, attendant upon the mineralization; that the ore deposition took
place from solutions circulating along fault fractures, and that they
deposited their contents by preference at the contact of two or more of
these fractures.

The ore in the Durant varies greatly, both in composition and in quality.
There has been a large amount of oxidized ore taken out, but now a great
portion of it is sulphide, although most of the existing stopes show more or
less transition between the sulphide and oxidized conditions. As is the
case throughout a large part of the camp, the ore is chiefly an argentiferous
galena, which has replaced the dolomite and limestone to a greater or less
extent. There is also considerable zinc sulphide and carbonate, and in:
some of the ore the silver probably occurs in large part as argentite. On
Pl. XL, B, a cross section through the Durant and down the “Electric
winze” of the Aspen mine is given, showing the typical structure of the
Durant and the Aspen mines and the occurrence of the ore bodies. The
ore figured on this section is that which has actually been taken out, and
the narrow zone to which it is confined is well shown. There are, however,
evidences of ore in other parts of the rock, particularly in the faulted region
in the right-hand or western part of the section.

Aspenmine—'T'he Aspen shaft passes through a small quantity of por-
phyry and Weber shale and through the blue limestone to the Contact
fault, along which most of the workings are located. The general
structure shown in the mine is a continuation of that in the Durant.
Throughout the whole runs the Aspen fault, very nearly vertical and
with a north-south trend. A short distance east of the Aspen fault,
between the blue limestone and the dolomite, is the Contact fault. This
fault has slickensided walls and often a triturated zone, showing its nature.
In its main course it has a north-south trend, nearly parallel with the
Aspen fault, but approaching it slightly toward the south, so that finally
they meet. From the sixth level down the dip of the Contact fault is
reversed and becomes very steeply east. At the sixth level it is about
85 degrees, but farther down it approaches 70 degrees. At a certain
point, which varies, being deeper in the Aspen mine than anywhere else,

156 GEOLOGY OF ASPEN MINING DISTRICT, COLORADO.

the Contact fault flattens out and runs into the Aspen fault. On the west
side of this it becomes shallower, with a more northerly dip and a general
east-west strike. The point at which the Contact fault runs into the
Aspen fault naturally becomes lower toward the north, so that in the
successive levels we find this poit constantly advancing.

Besides the Aspen and the Contact faults there are, as in the Durant,
a number of minor faults and cross fractures, which seem to be dependent
upon and synchronous in origin with these greater faults. They are
nonpersistent, often continuing but a short distance before running into
one of the larger faults and disappearing. Along these faults, especially
at their intersection, the ore is formed im immense and rich bodies. On
account of the vertical position of the ore-producing zone, the mineral has
been almost continuously stoped out down to nearly 1,500 feet below the
surface, and it is claimed that for this reason the Aspen mine has been by
far the greatest producer, in proportion to its surface acreage, among the
mines of Aspen.

Owing to their parallelism with the Contact fault, the ore shoots have
a general dip to the east. The ore occurs indiscriminately im limestone or
in dolomite, or in the Contact fault between the two, since immense stopes
have been excavated in dense dolomite, while im other cases they lie
entirely inclosed in blue limestone. But, as seén in the cross section, the
ore bodies are, in a general way, confined to the fractured and sheeted
zone where the beds have been overturned against the Aspen fault.

The ore is practically the same as in the Durant mine, consisting in
the lower levels principally of argentiferous galena with some blende.
Most of it contains some barite. In the upper levels the ore has been
oxidized, so that the metals occur chiefly in the form of carbonates and
oxides. A peculiarly interesting type of ore was noted on the third level,
near the shaft. This ore is to the eye a pure and apparently unaltered blue
limestone, being hard and fresh. It contains no lead, and the silver is said
to exist in small black: specks of sulphide. This ore is said to be high
erade, running 200 ounces or more. On both sides of it there is barren blue
limestone. In the Forest stopes, at about the second level, the ore also
occurs with blue limestone on both sides, far from the solid dolomite, but
in this latter case the ore is dolomized or has dolomite as a gangue, the
dolomite being derived from the local alteration of limestone ; and as this

U. S. GEOLOGICAL SURVEY MONOGRAPH XXXi_ PL. XX

A, M. AND S. MINE, NO, 6 STOPE.

ASPEN MOUNTAIN. 157

association of ore with dolomite is almost invariable, its occurrence in an
unaltered blue limestone is extraordinary.

Schiller mine —The Schiller workings lie just west of the Durant, and the
ore-bearing horizon occurs somewhat lower down. The mine is reached
by the Schiller shaft, and also by the Schiller incline, which runs from the
Durant workings. The Schiller shaft passes through about 390 feet of
porphyry and 190 feet of broken porphyry and shale to the bottom, which
is in the Silver fault. From the shaft an incline runs down through the
Silver fault, across the blue limestone, to the Contact fault. The Schiller
fault runs in dolomite from the 200-foot level of the Durant down to the
level at the bottom of the Schiller workings. This level runs off to the
south in dolomite to the breast, where a bed of quartz and black dolomite,
with a fine material strongly resembling the Parting Quartzite, is encoun-
tered. The Schiller fault runs through the foot of the incline from the
Durant in a nearly vertical line with a north-south trend. There are one
or two parallel slips near the Schiller fault, evidenced by slickensides and
fissures filled with fine clay, and the Contact slip is shown in the lower
workings. Along these several faults ore has formed and has been stoped
out at intervals. :

The Aspen Mining and Smelting Company mine——This mine, currently called the
A. M. and §., is reached by the Veteran tunnel, which cuts through the
glacial drift to a point close to the Franklin shaft, where it enters Weber
shale. It soon after crosses a thin bed of blue limestone and enters the
Contact fault. The formations in the A. M. and 8. are the same as in the
Aspen and the Durant, but the great local steepening and overturning of
the, beds noted in the mines just described is here absent. There is, it is
true, a slight steepening, but, so far as exposed, the dip is fairly uniform
from the outcrop down to the bottom of the workings, being about 35 or
40 degrees. The Silver fault is shown in the tunnel, where the zone of
shale above the blue limestone is very much crushed, and also at several
other places in the lower workings. In this mine the Silver fault cuts down
across the formations so that the blue limestone becomes quite thin. The
Contact fault between the blue limestone and the underlying dolomite is
well shown, the brecciated zone along it being often thick and conspicuous.
A feature of the Contact fault which is not noted in the most of Aspen
Mountain is the presence of bowlders of porphyry in the breccia, these

158 GEOLOGY OF ASPEN MINING DISTRICT, COLORADO.

bowlders being often of large size and very conspicuous in the black matrix.
This seems to be a result of the thinning of the blue limestone and the con-
vergence of the Silver and the Contact faults. There are many large and
interesting caves in the blue limestone just above the Contact fault in this
mine, which mostly seem to have been formed since the ore deposition.

The ore occurs along the Contact fault, but chiefly along certain
parallel zones or shoots in this fault. These shoots, which are three or four
in number, have a northeast trend and correspond to a system of fractures
and slight faults which are found in the rocks in this vicinity and which
are cut in the Durant tunnel. The ore is an altered limestone, containing
much galena and often a great deal of barite. Pls. XX and XXI are from
photographs of stopes in the A. M. and S. mine. ‘

Durant tunnel The Durant tunnel runs in from the bottom of Aspen
Mountain to the deep mines, thus affording convenient means of transporting
ore and of drainage. It starts in the Leadville dolomite very close to the
Parting Quartzite, and soon encounters a series of northeast faults and
fractures, which are in general vertical, although some dip northwest and
others southeast. Along these faults are triturated zones and open water-
courses. There are many of these faults, and their general effect is to
shift the formations very slightly back to the east on the south side. The
strike of the formations at the north is slightly more easterly than the gen-
eral trend of the tunnel, so that the tunnel tends to go down in the series,
but the effect of the faults is to keep it along nearly the same horizon,
near the Parting Quartzite, for the first 1,000 or 1,500 feet. Then comes
a marked steepening of dip, as has already been noted in the Aspen and
Durant mines, so that the rocks become nearly vertical. The strike also
swings round more to the north and the tunnel goes steadily up in the
series till it strikes the Contact fault.

Homestake shaft—The Homestake shaft went through 240 feet of drift, 265
feet of porphyry, and 115 feet of shale to the Silver fault; then through
225 feet of blue limestone to the Contact fault. These thicknesses, how-
ever, are taken on a very steep dip, so that the .actual thickness of blue
limestone is not over 40 or 50 feet. This is also its thickness in the
northern part of the A. M. and S. mine. Close to the Homestake shaft is
situated the mouth of the Enterprise tunnel, which runs from this point
east to the Contact fault.

U. S. GEOLOGICAL SURVEY

MONOGRAPH XXX! PL. XX!

A. M. AND S, MINE, GOLCONDA STOPE.

ASPEN MOUNTAIN. 159

Enterprise tunnel_— [he Hnterprise tunnel runs in drift to the blue lime-
stone, and through this to the Contact fault. A drift runs from this point
northeast and southwest on the Contact fault, which shows slickensiding,
brecciation, and watercourses filled with mud. These workings have
developed some ore along the Contact fault, in shoots which probably
belong to the same system as those of the A. M.and 8. Ore is also found
along the same shoots in the Little Nell tunnel and the Thousand-and-one
incline.

Argentum-Juniata mine——In this’'mine the formations are the same as in the
A.M. and 8., but they do not outcrop, since they are entirely beneath
Roaring Fork Valley and are deeply covered with drift. This mine affords
one of the most favorable means for determining the structure which lies
under the river valley and which is hidden by the glacial material, and from
its workings, and those of the Mollie Gibson on the other side of the valley,
it appears that there is no great complication in the space between Aspen
and Smuggler mountains. The Argentum-Juniata workings are run on the
Contact fault between the blue limestone and the dolomite, which, with the
other formations, have a steep but comparatively uniform dip. There is
some slight faulting shown in the mine, but none which has any very
heavy displacement, if we exclude the Silver fault. This fault is exposed
between the shale and the blue limestone at one or two points by cross
drifts running west from the Contact fault, and is characterized by a thick
breccia of porphyry, shale, and limestone, and by open fissures and water-
courses in the limestone, parallel to the main fault. Besides the Silver and
the Contact faults the disturbance consists mostly of a series of parallel
fractures, which have some slight displacement. These strike northwest
and have a steep southwest dip. Along some of these fractures much water
pours into the mine. An interesting feature is the alteration of the lime-
stone and dolomite along some of the zones of fracture to a soft, black
material, which so closely resembles the softened Weber shale that the two
can not easily be distinguished.

The ore has been found chiefly along the Contact fault, but irregularly
distributed. It is not yet determined whether the system of northwest
fractures has any reference to the localization of the ore deposits. The ore
is an alteration of limestone or dolomite, is generally stained brown by iron
oxide, and carries considerable barite.

160 GEOLOGY OF ASPEN MINING DISTRICT, COLORADO.

Princess Louise and Hidden Treasure——T he Princess Louise shaft is situated in
Spar Gulch, near its junction with Copper Gulch, and ‘he Hidden Treasure
is near by, in Copper Gulch. Both these workings are now abandoned.

The Princess Louise started in the Silurian dolomite and went down into
the Cambrian quartzite. It is said that a small quantity of ore was mined
in the Cambrian quartzite at a distance of about 60 feet below the contact
with the Silurian. The ore carried silver, and occurred along nearly
vertical east-west fractures in the quartzite. The chief interest which
pertains to this shaft is the fact that ore has occurred here in the Cambrian
quartzite, although in small quantity.

WEST SIDE OF ASPEN MOUNTAIN.

On the west side of the Aspen Mountain syncline there are a number
of workings, chiefly tunnels, some of which are very extensive. These
usually find some ore along the vertical north-south faults, especially in
the chief ones—the Saddle Rock and the Pride.

New York tunne.—T'he New York tunnel is one of the longest of these
workings. It runs south into the hill, so that it cuts across the formations
and reveals successively lower strata. The first 500 feet is in the shale
which overlies the porphyry, the second 500 in the porphyry itself, and
then about 100 feet in the shale which underlies the porphyry. At this
point the Cambrian quartzite is reached by crossing the Saddle Rock fault,
and is continued in for about 285 feet to the granite below.

Great Western tunnel— The Great Western tunnel starts in the hillside above
the New York. It passes through a few feet of the shale which overlies
the porphyry, and then continues in porphyry to near the end, where it
cuts a little shale and crosses the Saddle Rock fault into the granite.

Pioneer tunnel— I'he Pioneer tunnel starts on the hillside on about the
same level as the New York tunnel, but farther to the west, and like it,
runs south into the hill. After passing through a slight thickness of glacial
drift, it goes through 330 feet of shale, 50 feet of porphyry, and 230 feet
of shale, then crosses into the blue limestone, of which there is about, 75
feet, to the Saddle Rock fault, and crosses this fault into granite.

Gatenatunnel-—The Galena tunnel starts in dolomite in the block
between the Saddle Rock and the Pride faults, and runs west, slightly

ASPEN MOUNTAIN. 161

south, for 250 feet to the contact between dolomite and granite caused by

the Pride fault.

Late Acquisition mine. (See Pl. XL, C).—The Late Acquisition shaft is 125
feet deep and is entirely in dolomite, which is probably Carboniferous. In
this shaft there are four levels, of which the upper two are short and
extend in a westerly direction. The third level, which runs to the east,
cuts the Parting Quartzite 50 feet from the shaft. On this level a consid-
erable amount of medium-grade lead ore has been found along the Saddle
Rock fault and along parallel slips in the dolomite. One hundred feet
below the third level is the fourth or tunnel level, which runs due north and
south on a fault plane which is marked by a perpendicular, highly polished
and striated wall of dolomite on the west side and by blue limestone on
the east. This is not the main Saddle Rock fault, but a parallel slip about
50 feet west of the main one. The rock along this fault is mineralized,
containing considerable lead and zine sulphide, which has replaced the
dolomite.

The ore throughout this mine has the general characteristics of the
West Aspen Mountain ores, as shown in the Pride of Aspen mine. It is a
high-grade lead ore with only a small amount of silver. There is almost
no barite, and tons of the ore often average less than 1 per cent of baryta.

ASPEN MOUNTAIN MINING MAP.

The Aspen Mountain map (Atlas Sheet XXV) includes the produc-
tive mines of Aspen Mountain, except those near the pomt of West Aspen
Mountain. Through the center of the district runs the outcrop of the hghly
metalliferous zone which is continuous from the Argentum-Juniata up to
the Durant. In the bottom of the Aspen Mountain syncline little mining
has yet been done, although it offers a favorable field for exploration, while
on the west side of the syncline are some long tunnels.

Besides the structure already shown on the smaller-scale map, some
additional details appear on the Aspen Mountain map. The Contact fault
between the limestone and dolomite of the Leadville formation is repre-
sented, and the distinction between limestone and dolomite is indicated by
different coloring. An east-west fault which crosses Spar Gulch at the
southern edge of the mapped area and which represents a system of nearly
vertical northeast faults, with usually very slight throw, is also shown.

MON XXXI it

162 GEOLOGY OF ASPEN MINING DISTRICT, COLORADO.

This has a slight downthrow on the north side. It is probably only a local
cross fault, running diagonally between north-south faults of the Ontario
or Tourtelotte Park system and the Silver fault. The main systems of
faults are shown on this map as on the larger one. West of the Silver
fault there come in the Schiller and the Sarah Jane, and farther west is
shown a portion of the Saddle Rock, where it flattens and locally advances
in outcrop toward the east.

Section a— The eastern end of Section A, Atlas Sheet XXVI, is near
the northern poimt of East Aspen Mountain, in granite. To the west the
upturned beds of Cambrian and Silurian are successively crossed, then the
Parting Quartzite and the Leadville dolomite. There are represented in
this section the two faults into which the several breaks of the Ontario
system have resolved themselves on East Aspen Mountain. Their position
is not certain, but is approximately as shown, both having probably a
slight downthrow on the west side. The blue limestone above the Contact
fault actually outcrops, and above this comes the Silver fault, separating
the porphyry from the blue limestone, with generally some little shale
between. The Aspen fault is not well marked, but is shown as splitting off
from the Silver fault and assuming a steeper dip at the point where the
east limb of the syncline flattens to form its bottom, while the Silver
fault continues across the syncline with the beds. The section cuts through
the Homestake deep shaft and shows the large amount of drift which that
shaft has traversed. This mound of drift is very conspicuous in the field,
forming a low hill at the bottom of Vallejo Gulch. To one who is familiar
with the landslides of the Rocky Mountains it is evident that this hill
originated in some such catastrophe, and that Vallejo Gulch was cut
through the material which formed this mound. The landslide took place
in post-Glacial time, since the débris juts out into the valley, covering
up the glacial materials.

West of the Homestake shaft there are few opportunities for determin-
iug the underlying rocks, and the structure is inferred from data gathered
farther south.

Section B—QOn the eastern side of Section B the beds flatten, indicating a
tendency toward anticlinal structure. The two faults of the Ontario sys-
tem are cut at a point farther south than in Section A. Their throw, there-
fore, is greater. The flat dip on the top of the mountain steepens toward

ASPEN MOUNTAIN. 163

the west and then flattens again on nearing the bottom of the syncline.
The slight thickness of blue limestone shown between the Silver and Con-
tact faults has been well proved by mine workings. On the bottom of the
section, below the Franklin shaft, the Aspen fault is represented as splitting
off from the Silver fault, as in Section A. West of the Franklin shaft the
bottom of the syncline is passed through.

Section c.— The eastern end of Section C shows the tendency to anticlinal
structure somewhat more strongly than Section B. Just west of the eastern
end a cross fault of the Tourtelotte Park later system is cut. The beds
have a comparatively gentle dip, almost identical with the slope of the hill.
The section runs nearly parallel to the Bonnybel and Chloride faults, but,
being vertical, while these faults have a southwest dip, it intersects them.
The intersection with the Bonnybel is nearly horizontal, while that with the
Chloride, which has a slightly differing trend, is more steeply inclined, and
the two faults come together and run into the Aspen fault in the Durant
mine. The section cuts through the Bonnybel mine, the Visino incline,
and the Durant workings, where many of the data have been obtained.
The steep easterly dipping fault not far west of Spar Gulch is one which
is found near the mouth of the Visino tunnel, and in the Bonnybel mine a
fault has removed the blue limestone from the small downtbrust block
between the Bonnybel and the Chloride faults. A vertical dike of por-
phyry, sending out small sheets, is also found in the Bonnybel and has
been followed nearly down to the Parting Quartzite. This is shown contin-
uing downward indefinitely and faulted by the Bonnybel fault, which seems
in the mine to be of later date than the porphyry intrusion. The nature
of the Aspen fault, as shown, has been well developed in its lower course
by mine workings. It is represented as running into the Silver fault above.
Between the Aspen fault and the next important fault to the west (the
Schiller) there are a large number of minor breaks. Two of the chief of
these, which are called by the mine managers the Schiller No. 2 and the
Conomara, are known to be nonpersistent and are represented as uniting
and dying out in the porphyry above. ‘The section cuts the block between
the Schiller and the Sarah Jane faults just north of the outcrop of the
contact of porphyry with the overlying shales.

Section D—Section D, Atlas Sheet XXIX, is at right angles to Sections
A, B, and C, Atlas Sheet XX VI, which have been drawn at right angles to

164 GEOLOGY OF ASPEN MINING DISTRICT, COLORADO.

the general strike of the beds on East Aspen Mountain and throughout the
rest of the district in general. They are not, however, at right angles to
the strike of the beds in the main part of the Aspen Mountain area, for here
the strike is variable, being altered from the usual direction by the influence
of the Tourtelotte Park dome and by the Aspen Mountain syncline, which
lies on the north face of the dome. Section D cuts across the center of the
map and shows the westerly dipping strata on the east side of the syncline.
It also cuts through the Tourtelotte Park dome, so that the formations as
shown are not horizontal, but cross the uplift. In a section like this, which
cuts the formations obliquely, the thicknesses are greatly exaggerated, and
that of each bed varies with the changing local dips, the thickness bemg
apparently greater as the beds become steeper. At the northern end is a
thick covering of glacial drift, partly rearranged by water action, which
covers the bed rock in the Roaring Fork Valley. The section follows
continuously the line of workings which run along the Contact fault on
Aspen Mountain from top to bottom, reaching from the Argentum-Juniata
up to the Durant. Above the Durant the flattening of the beds indicates
the appearance of a slightly different structure, and throughout Tourtelotte.
Park the workings are not so large nor so continuous. The Silver fault
is also continuously shown in the section, except in the northern part,
where it runs into the glacial drift. Near the top of the hill are the
Chloride and the Bonnybel faults, or, rather, the sheared wedge which
these faults represent. These are shown near their junction with the
Silver fault, and are very close together, forming practically a single
fault. Beneath the drift on the north the two faults of the Ontario
system are represented with very slight throw, dying out against the
Silver fault.

Pl. XXII is a general view of Aspen Mountain from the slopes of Red
Mountain, looking south, showing the town of Aspen below. ‘The promi-
nent squat hill at the foot of Vallejo Gulch which appears in Section A,
Atlas Sheet XXVI, consisting entirely of loose material which the Home-
stake deep shaft has penetrated, is shown to the right of the center of the
picture. At the right is the edge of West Aspen Mountain and on the left
is East Aspen Mountain. In the center is Spar Gulch, with Copper Gulch
running into it, and near the top of the mountain is Tourtelotte Park.

‘NIVLNQOW G3Y NOUS ‘NIVLNNOW NadSv

\Ixx ‘Id 1XXX HdVHSONOW AAAUNS 1VOID01049 ‘Ss “0

MINES AND PRODUCTIVE LOCALITIES. 165

WEST ASPEN MOUNTAIN.

Pride of Aspenmine. (See Pl. XLI, d.)—The Pride of Aspen workings
consist chiefly of two tunnels and a shaft. The shaft is 400 feet deep,
having passed through 250 feet of glacial drift, 190 feet of Weber shales,
and 60 feet of the gray limestone which forms the base of the Maroon
formation. The position of the Weber above the Maroon gray limestone
in the shaft, taken together with the dips of the formations in the two
levels, shows that the strata have been locally overturned. There are
two levels from the shaft, one at 200 feet and one at 400 feet. The upper
one runs west a short distance in Weber shales; the lower one starts in the
Maroon gray limestone and runs west in solid limestones and shales, which
become soft as the drift advances westward toward the Pride fault. This
fault is cut about 200 feet from the shaft, and on the other side the Cam-
brian quartzite is exposed. The upper tunnel runs south, and is for most
of its length directly in the Pride fault. The Pride fault has a very steep
easterly dip, so that the foot wall is dolomite and the hanging wall shale.
The shale of the hanging wall is mixed with limestone and porphyry,
sometimes brecciated, sometimes in large, solid bodies. The second tunnel,
which is 90 feet below the other one, is in Weber limestone, and does not
cross the fault, although it runs very close to it. In this locality there are
many fractures, the chief set trending due east and west and dipping north
at an angle of 40 degrees. These fractures stop at the Pride fault and
correspond to the east-west breaks which are developed on the north end
of West Aspen Mountain. .

The ore in the Pride of Aspen. is found in the immediate vicinity of
the Pride fault. The known ore bodies all lie parallel to this fault and at
varying distances from it, in the shale on the east side, and have probably
developed along fractures which were formed at the same time as the main
fault. Some of the ore seems to have a connection, also, with the east-
west, northerly dipping faults and fractures. The owners of the property
believe that one of these faults crosses the Pride fault, and that at the
junction of the two their ore is situated. The continuation of the east-west
faults to the east of the Pride is doubtful, and certainly has not been
proved by the developments thus far. The ore is low grade in silver, and
carries much lead and some zine, with less than 1 per cent of baryta.

166 GEOLOGY OF ASPEN MINING DISTRICT, COLORADO.

Red Spruce shait— The Red Spruce shaft is 90 feet deep on the Pride fault.
It runs in ore all the way.

Aspen Mining and Drainage tunnel, including the Copperopolis— | his tunnel runs southwest
for 1,000 feet. Through the first 850 feet it cuts a breccia, apparently of
glacial origin, which at first is composed principally of bowlders of red
sandstone and blue limestone belonging to the Maroon formation, but farther
in chiefly of gray limestone. Beyond 600 feet the bowlders of limestone
decrease in size and are replaced by huge masses of Weber shale and lime-
stone which have been considerably distorted. At 475 feet from the mouth
of the tunnel a drift runs to the west 175 feet and cuts porphyry. This
porphyry is considered the foot wall of the vein, while the hanging wall,
which lies next it to the east, is composed of brecciated shale, porphyry,
and black limestone. Ore has been found continuously along this zone,
being developed by workings carried north and south. It lies in irregular
masses, comparatively close but not always parallel to the porphyry wall.
It is generally continuous and from 2 to 10 feet in thickness. The metallic
sulphides occur in spaces between fragments of limestone in the crushed and
broken zone. This breccia evidently lies along a north-south fault, extremely
close to and dependent upon the Pride fault. The actual Pride fault, how-
ever, is not shown in the workings.

Little Cloud tunnel — he Little Cloud tunnel runs into the hill between the
Pride of Aspen and A. M. and D. workings, and cuts the same fault that is
shown in both these mines. From here it cuts a little farther west than
does the A. M. and D. tunnel and exposes the main Pride fault with a west
wall of blue limestone underlain by dolomite. The east wall is composed
of very soft, compact shale and porphyry breccia. No ore has been taken
from these workings.

Mary B.mine—The Mary B. shaft is in shale and porphyry breccia and
touches the gray limestone of the Maroon series. From the shaft a level
which runs off south has struck a very heavy fault with a northeast trend,
which separates the top of the Weber and the gray Maroon limestone on
the northwest from the Silurian dolomite on the southeast. The junction of
this fault with the Castle Creek fault is seen in the tunnel just under the
old powder house in Castle Creek. Close to this fault there has been a
slight overturning of the strata, as they were dragged along the fault plane.
Along the fault, in the Mary B., bodies of workable ore have been discoy-

TOURTELOTTE PARK. 167

ered. This ore is different from the other ores of the camp, being char-
acterized by an abundance of coarsely crystalline iron pyrite, inclosed in
soft black material, which appears to have been triturated. The pyrite was
analyzed in the laboratory of the Survey and proved to be simply iron sul-
phide, containing also small amounts of arsenic, lead, copper, and zine, a
small amount of silver, and traces of cadmium, cobalt, and nickel. Assays
of this ore were also made to determine whether the values were chiefly in
the pyrite or in the inclosing black material. The two, being separated as
well as possible, were separately assayed. The pyrite assayed 14 ounces in
silver, while the black cement assayed 90 ounces. No gold was found by
either of these assays.

Homestake shaft— The Homestake shaft of West Aspen Mountain must be
distinguished from the Homestake deep shaft farther to the east. The
former lies on West Aspen Mountain, on the northwest side of the Mary B.
fault. It is in the basal Maroon gray limestone, and in some of its workings
the gray and red sandstones of the Maroon are cut. Near the end of the
drift, to the southeast, a crosscut west encounters the Mary B. fault and
crosses it into dolomite. The strike of the Mary B. fault at this contact is
N. 50° E.

Baltic tunne—T'he Baltic tunnel starts on the east side of West Aspen
Mountain and runs in a westerly direction to the Pride fault. It is 780
feet long and passes through 155 feet of glacial drift and other débris, then
through mingled shale and porphyry to the fault plane at the breast. On
the west side of the fault is granite.

TOURTELOTTE PARK.

There is no actual break between the Tourtelotte Park district and
that of Aspen Mountain, since ore is found continuously from one to the
other. Just south of the Durant mine, however, the steep northern face
of the domelike uplift flattens toward the south, and with it the Aspen
Mountain syncline becomes shallow. These changes become more marked
farther south, especially the flattening of the syncline, so that the dip of
the formations, and with them of the Silver and the Contact faults, along
which are the chief ore-bearing localities, becomes much slighter than on
Aspen Mountain. Most of the workings in Tourtelotte Park are, therefore,
comparatively close to the surface. Ore is found continuously from Aspen

168 GEOLOGY OF ASPEN MINING DISTRICT, COLORADO.

Mountain to near Castle Butte at the south side of the park. At this latter
point the northerly pitch of the beds carries the upper formations, such
as the shale, and finally the blue Leadville limestone, above the surface,
and with them the Silver and the Contact faults. South of this point the
country has been comparatively barren, and is not likely ever to be
very productive, with certain exceptions, such as in localities along the
Castle Creek or its dependent faults, where there appears to have been
ereat mineralization.

Bay State shatt—The Bay State shaft lies close to the northern border of
the district shown on the Tourtelotte Park ming map. The workings are
in the blue Leadville limestone and in the dolomite of the same formation,
exposing the Contact fault. This fault carries some ore, but no very
important body. There has been some cross faulting in the mine, by which
the Contact fault has been shifted about.

Ruby min.—The Ruby mine is near the Bay State, and shows practically
the same conditions. The shaft, which is 385 feet deep, starts in shale,
crosses the Silver fault, and proceeds downward through the blue limestone
across the Contact fault into the dolomite. There has been a great deal of
faulting in this mine, which has shifted the formations considerably, but
the faults do not seem to be very heavy or persistent. East of the shaft
the general effect seems to have been to thrust the formations down slightly
on the east side. There are two sets of fractures in the mine corresponding
with the two sets of slight faults, one of which runs north and south, and
the other east and west; and, so far as can be judged from the somewhat
meager evidence, the east-west faults antedate the north-south ones. Both
of these fracture systems seem to have influenced the deposition of ore, and
some valuable bodies have been discovered along them. Most of the ore,
however, occurs in the vicinity of the Contact fault.

Little Percy mine—The Little Percy mine is situated a short distance south
of the Ruby, and shows very nearly the same conditions. The chief work-
ings consist of an incline which starts on the hillside at the outeropping of
the Contact fault on the east limb of the Aspen Mountain syncline. This
incline runs in a northwesterly direction for over 1,300 feet, having a vary-
ing pitch. For most of this distance it is in the Leadville dolomite, or in the
Contact fault, which is marked by a brecciated zone containing large frag-
ments of shale and porphyry. From this incline there run out at mtervals

TOURTELOTTE PARK. 169

ten horizontal drifts. Of these the upper ones find ore, and there is also
some in the lowest or tenth level. The chief ore is associated with much
barite and is thoroughly oxidized. It contains a great deal of. a bright-red
powder, probably oxide of lead, often inclosed in barite crystals. ‘There is
also, in blotches, a rich dark-brown stain, which is thought by local chemists
to be an oxide of copper, and which is taken by miners as an indication of
richness. There are a number of small east-west slips in the mine, along
which ore appears to have made. ‘There are also some slight faults marked
by breccia and open watercourses, which have formed subsequent to the
ore deposition.

Best Friend mine —T he Best Friend mine is situated a short distance directly
south of the Little Percy, and has most of its workings on the Contact fault.
The shaft runs down through porphyry, then through about 30 feet of shale
to the Silver fault. In places in this mine the Silver fault comes down
very close to the Contact fault, so that the two are separated only by a
very thick limestone breccia. The Contact fault is marked throughout by
a brecciation which is not very profound, and by a persistent seam of lime
mud. This seam varies in thickness from an inch or two up to over 20
feet. It is beautifully stratified, sometimes cross bedded, and when thickest
is composed of fine lime mud alternating with coarse sandy layers. In the
thickest portions this mud has evidently filled large caves. The stratifica-
tion grows finer toward the top of this deposit, and on the bottom is a seam,
which seldom exceeds 4 or 5 inches in thickness, where the fine clay is
stained very black by oxide of manganese. A sample of this gave on
analysis 45.86 per cent of manganese oxide, with 12.83 per cent of iron
oxide. It was also assayed and found to be impregnated with silver to a
certain extent. Above the mud seam is almost invariably limestone, while
below it is dolomite; and the ore is nearly continuous with it, generally
lying in the dolomite beneath. The width of ore is comparatively slight,
the thickest pay streak in the mine thus far being only about 20 inches.
In character the ore is similar to that of most of the mines in Tourtelotte
Park, bemg entirely oxidized and containing much barite; and from the
oxides of the metals it derives a general brown color, locally red or yellow.

The following series of probable events in the history of the rocks in
this mine may be inferred from the phenomena along the Contact fault:

First, the formation of a fault which is parallel to the bedding, or

170 GEOLOGY OF ASPEN MINING DISTRICT, COLORADO.

nearly so. This is indicated by brecciation between the blue limestone
and the dolomite. Second, the mineralization and deposition of vein
material. This is shown by the fact that the breccia along this fault has
been changed to ore, and has in large part been cemented by vein mate-
rial, chiefly barite. The mineralization, therefore, is later than the faulting.
Third, dolomization. This was probably contemporaneous with the min-
eralization, but may have gone on somewhat later. It is indicated by the
alteration of the blue limestone in the immediate vicinity of the Contact
fault to dolomite. The irregular distribution of this dolomite, following
fractured zones and occurring in nonpersistent bands and blotches, shows
that it could not have been originally deposited, but that its deposition
came about through the waters which circulated through the fault zone.
Fourth, a movement of the rocks at a later period and a widening cf the
original fissure. This must have left an open fissure of varying width.
The opening of this fissure subsequent to the ore deposition is shown by
the fragments of ore as well as of limestone and dolomite in the clay which
subsequently filled it. Fifth, the deposition of bog manganese during a
period when the waters which filled the opening were comparatively quiet.
Sixth, a slight tilting of the rocks, which is shown by a gentle dip in the
mud layers and by some disturbance in the manganiferous lower layer,
which is often broken. Seventh, the deposition by a more rapid and
muddy current of the sandy and limy layers.

At the southern end of the mine a fault is encountered which may be
the Dixon. This cuts off the Contact fault and the ore, and although there
is blue limestone on both sides, showing that the throw has not been great,
the other side has not yet been sufficiently explored to show the exact
amount of displacement.

Bob Ingersoll mine—T he Bob Ingersoll mine immediately adjoins the Best
Friend to the east, the workings of the two mines running together. The
general occurrence of the ore and its nature are exactly the same as m
the Best Friend. From the Bob Ingersoll an incline runs down on the
Contact fault to the north and encounters the Hallet fault, which runs into
it at the end of the incline. This shaft is 210 feet deep, and has passed
through porphyry and Weber shales to the Silver fault, at the contact of
shales and blue limestone. This contact is brought down by the Hallet
fault to about the level of the Contact fault at the end of the incline. At

TOURTELOTTE PARK. 171

the bottom of the shaft a rich bed of ore was found, which was, however,
comparatively small, turning out $65,000.

Dixon shaft—This shaft, which is about 270 feet deep, runs through
porphyry and the Weber shales to the Silver fault. Below the Silver
fault dolomite was reported, which probably resulted from secondary
dolomization accompanying ore deposition. Drifts from the shaft cut the
blue Leadville limestone in its normal place below the fault. The main
drift runs slightly south of west and cuts the Dixon fault, which has a
slight downthrow on the south side, as shown on the map and in the
sections. There has been some mineralization in this mine along the
Contact fault, but there seems not to have been any large amount of
pay ore found.

Mayflower tunnel— [he Mayflower tunnel is situated on the west side of
Tourtelotte Park, on the slope of the hill toward Castle Creek. It is one
of the tunnels which cut the formation where it has an easterly dip, on the
western limb: of the Aspen Mountain syncline. It starts in dolomite and
runs east about 240 feet to blue limestone, the contact between the two
formations being very sharp. After about 100 feet of blue limestone there
comes a heavy breccia of shale and altered limestone, with occasional
porphyry fragments. This is probably the Silver fault. In this breccia
there are some very good seams of ore, especially one at the contact of the
breccia with the hard limestone below, which is here locally dolomized.

San Jacinto shaft— This shaft cuts the western limb of the Aspen Mountain
syncline, starting in porphyry and crossing the shale into the Silver fault,
then passing through the blue limestone into the Contact fault, and thence
for some distance into the dolomite. The only ore found in the workings
was some lead ore on the Contact slip.

Sam Houston shaft The Sam Houston starts not far from the San Jacinto,
and, like it, in porphyry. From the porphyry it passes through shale to
blue limestone on the under side of the Silver fault. Some ore was found
in the blue limestone, about 15 feet below this fault.

Saddle Rock shafts —T'here are two shafts on the Saddle Rock property, one
of which lies near the Sam Houston. This shaft shows essentially the
same conditions as the Sam Houston, except that it passes through a
larger body of porphyry. After the porphyry, it goes through shale and
limestone into the dolomite. There seem to have been two ore-bearing

ine, GEOLOGY OF ASPEN MINING DISTRICT, COLORADO.

zones in this mine, one at the Silver fault, in which the ore lay mostly in
the blue limestone, and one at the Contact fault, in which the ore was
mostly in the dolomite.

The second Saddle Rock shaft is situated on Saddle Rock, between
Keno and Ophir gulches. This shaft runs in altered limestone after
passing through a slight thickness of Weber shales. Two levels from the
shaft run east and cut the Sarah Jane fault only a short distance away,
showing that the alteration of the limestone in the shaft is undoubtedly
due to the proximity of this fault. According to these developments the
fault is here vertical, or has a very steep dip to the east.

Camp Bird shaft—T"he Camp Bird workings are situated on the outcropping
eastern limb of the syncline, at a pomt where this fold has become very
shallow. There is, therefore, no very great difference in the elevation of
the workings, which are mostly on the Contact fault. The ore is mainly
on the Contact fault, but follows certain definite zones, so as to make ore
shoots lying in the fault. The most marked of these shoots runs northeast
and southwest. It is cut off on the north side by the surface and on the
south side by the Silver Bell fault, which separates this mine from the lowa
Chief. This shoot has a variable width, averaging perhaps not more than
100 feet. The ore is a softened and brecciated brown-stained limestone,
having bowlders of typical blue limestone and also of frosty-lustered
dolomite. Above this comes usually blue limestone and below it dolomite,
the thickness of ore varying from a few inches to 30 or 40 feet. The
shoot has, therefore, a northeast trend and a pitch of about 25 degrees to
the north, with a restricted extent east and west and a comparatively slight
thickness. Together with the inclosing formations it is displaced by an
east-west fault which has a downthrust on the north side of about 50 feet.
This fault is barren, but on following up the fault plane the continuation of .
the shoot is found on the south side. The movement, therefore, came about
subsequent to the mineralization. From here the ore shoot is traced con-
tinuously southward to near the Silver Bell fault, where it is finally lost,
being faulted away by the parallel slips which lie close to the Silver Bell.

Another large ore body forms a so-called “chimney.” This is a
nearly vertical shoot, which was followed up continuously from the Con-
tact fault to the surface, ore being stoped out all the way. ‘There seems
to be no definite lateral trend to this chimney. At other localities in the

TOURTELOTTE PARK. 173

mine ore has made alone the Contact fault at the intersection with vertical
fractures, some of which have a north-south trend, while others run east
and west. Pl. XLI, B, is a cross section in a northeast direction through
the Camp Bird mine, and is extended into the Iowa Chief. It shows the
ore as actually developed along the Contact fault, and its relation to the ore
in the Iowa Chief.

Iowa Chief mine—The working shaft of the lowa Chief mine is called the
South Camp Bird. This shaft passes through 165 feet of porphyry and then
15 feet of shale to the Silver fault. Below this fault it passes through 100
feet of blue Leadville limestone, often dolomized and stained brown, but it
does not seem to have reached the Contact fault and the main body of Lead-
ville dolomite. A considerable amount of ore has been taken from this
mine, some of it of a very high grade. Although on about the same level
as that of the adjacent Camp Bird mine, the ore is actually at an entirely
different geological horizon, for while in the Camp Bird it occurs all along
the Contact fault between the blue limestone and the dolomite of the Lead-
ville formation, in the Iowa Chief mine it is found along the Silver fault,
which separates the blue limestone from the overlying porphyry, with a
small belt of broken shale between. The ore-bearing horizons of the Camp
Bird and Iowa Chief mines are separated by the Silver Bell fault. This has
a downthrow on the south side of 200 feet, so that it brings the Silver fault
down very nearly to the same level as that of the Contact fault in the Camp
Bird. The Contact fault in the Iowa Chief lies below all the workings, and
has not been at all prospected, although it is extremely probable that ore
exists along it, as it does in the Camp Bird.

The actual occurrence of the ore and the other geological features of
the mine are shown in Pl. XLI, B, in which the lowa Chief mine occupies
that portion to the southwest of the Silver Bell fault, at the left-hand part
of the plate, while the right-hand or northeastern half of the section belongs
to the Camp Bird. This section has been carefully made, and shows only
actually developed ores. As seen here, the ore occurs altogether in the
vicinity of the Silver fault, either in the actual zone of displacement or m
the dolomite immediately below it, where it has formed along minor slips
in the limestone parallel to the main fault. This ore is a soft, decomposed,
pulverulent limestone, containing much barite, with no copper or zine and
very little lead. There is little or no dolomite in the rocks inclosing the ore,

174 GEOLOGY OF ASPEN MINING DISTRICT, COLORADO.

which are almost entirely pure blue limestone. In the ore bodies themselves,
however, there often occur barren portions which are nearly pure dolomite.
This shows that dolomization was attendant upon the ore deposition. The
ore bodies are often separated from the inclosing barren rock by polished
and striated surfaces, evidently belonging to fractures which were made at
the same time as the main Silver fault. Along these fractures the limestone
has often been triturated so as to form the so-called ‘‘talc” of the miners.

Celeste and Edison No. mines.—'The Celeste and Edison No. 1 shafts start in
porphyry and run down through shale across the Silver fault into blue
limestone, and from here down to the Contact fault and the dolomite. Ore
is found at two main horizons—the Silver fault and the Contact fault.
The ore in the Silver fault seems to have been rather richer than in the
lower horizon, while the workings are rather more extensive on the Con-
tact fault. The ore is identical with that in other mines of the park,
being a limestone which has been replaced more or less by metallic
minerals, with a gangue which is chiefly barite. This ore has been nearly
all oxidized, so that it is soft and crumbling. Its value is very variable,
ranging from a few ounces in silver to several hundred. There is in the
lower workings, which run upon the Contact fault, a permanent floor of
dolomite, which is brown from the oxidation of its iron. Above the ore
at this horizon is generally blue limestone, which, however, is usually
altered and may be dolomized. In the drifts may be seen irregular bands
or tongues of dolomite, which follow the strongly fractured zones and cut
straight upward across the blue limestone. There is, therefore, evidence
of two periods of dolomization in this mine, one of which existed before
the faulting, since it has been faulted regularly in the same manner as the
blue limestone, and another which was subsequent to the fault, since it
has been formed in the limestone along fractured zones which accompa-
nied this faulting. It is significant that the miners call the dolomite where
it occurs with the ore ‘‘vein lime,” recognizing the fact that it is nearly
always present in connection with the ore. Through the Edison there
runs an east-west fault which has a slight downthrow on the north side of
from 20 to 50 feet and which appears to be the same fault as that running
through the Good Thunder mine. Along this fault ore has made continu-
ously in the breccia, the stopes at one point being 60 feet high.

On the lower level of the Celeste a drift runs a short distance northeast

TOURTELOTTE PARK. 175

and cuts the Justice fault, crossing from brown dolomite to Weber shale.
The dip of the fault here is about 65 or 70 degrees northwest, and it has a
northeast trend. Along it the shales have been bent and broken.

Good Thunder mine—There are two shafts on the Good Thunder claim, called
the upper and the lower shafts. Both start in porphyry and go down across
a thin belt of shale, through the Silver fault and the blue limestone, to the
Contact fault. The ore occurs almost exactly as described in the Edison
No. 1 and the Celeste, in shoots along the Contact fault, between the blue
limestone and the dolomite, and is of the same nature, being all oxidized
and containing much barite. There is also some ore in the dolomite in
small slips which are apparently parallel to the main Contact fault.

Little Lottiemine——The Little Lottie mine is situated close to the Good
Thunder and Celeste, and a little farther south. The workings are not
very extensive, but considerable ore has been taken out. The first horizon
from which ore was taken was the Contact fault, between the blue lime-
stone and the dolomite; but subsequently the Silver fault, between the shale
and the blue limestone, was explored, and considerable ore was found. A
short distance southwest of the Little Lottie shaft is a tunnel which runs in
a southerly direction, starting in the Weber shales and crossing the Silver
fault into the blue limestone. The Silver fault in this tunnel is marked by
a breccia 10 or 15 feet thick, which is underlain by a soft gray sand con.
sisting of separate grains of dolomite. The limestone along the fault has
been somewhat mineralized, showing often considerable barite, and some
ore has been stoped out both in the limestone and in the shale.

Justice mine —There are two shafts on the Justice claim, the northern or
lower shaft and the southern or upper one. The lower shaft starts on the
east side of the Justice fault and goes down through porphyry till it cuts
the fault, which here has an easterly dip. There are some bunches of ore
found in the fault, but they appear to be earlier in age than the fault itself,
and to have been dragged in by fault movement. The upper shaft is deeper
than the lower, being about 400 feet deep. Accounts of the formations
which this shaft passed through are conflicting, but after the evidence is
sifted it appears probable that there was no porphyry in the shaft, but that
it started directly in shale after passing through glacial drift. The bottom
is in the Contact fault. From the shaft an incline runs off to the northwest
along the fault, which dips about 40 degrees. At intervals along this incline

176 GEOLOGY OF ASPEN MINING DISTRICT, COLORADO.

there is some ore, both in dolomite and in blue limestone, which shows a
tendency to follow certain shoots along the Contact fault. The end of the
incline is in a highly brecciated zone, which is probably near the Justice
fault. Just southeast of the shaft there is a series of stopes which have a
northeast-southwest trend and are nearly vertical. Along these ore has
been taken out continuously from the Contact fault up through blue lime-
stone to the overlying shale. This shoot continues northeast until cut off
by the Silver Bell fault. The ore is a broken and mineralized blue lime-
stone, and its walls are smooth and distinct. It is evident that it formed
along a fractured zone in the limestone, although neither the dolomite below
nor the shale above shows any displacement. This ore shoot, in the lan-
guage of one of the miners, was “‘the bonanza of the park.”

The ore is in general low grade, is entirely oxidized, and contains a
large amount of barite, thus corresponding with most of the other
Tourtelotte Park ores.

Last Dollar, Minnie Moore, and 0. K.mines—The Last Dollar, Minnie Moore, and
O. K. form, with the Justice, a continuous series of workings underlying
the upper part of the Tourtelotte Park basin. Most of these workings run
on the Contact fault, and consist of inclines dipping with the fault about
30 degrees to the northwest, from which levels run out. The Contact fault
in these mines is remarkable for the immense amount of low-grade ore
which is formed along it. This ore is in many places practically continu-
ous, and presents to the eye the appearance of great mineralization, since
it is soft and pulverulent, is stained red and yellow with metallic oxides,
and contains a large amount of barite. Most of it, however, has a very
low amount of lead and silver, and the large amount of barite is a disad-
vantage, so that thousands of tons have been uncovered which can not be
profitably shipped. Along this mineralized zone the rocks show the
influence of dolomization and of silicification.

Those ore bodies which are of higher grade and which have been
profitably shipped seem to occur in steeply dipping fractured zones which
traverse the Contact fault. There are several such zones shown in the
mine, some of which have an east-west trend, while others run north and
south. Along these the ore has been followed up for varying distances, as
is the case with the great ore shoot of the Justice (which has been called
“the Canyon”), and these ore bodies have blue limestone on both sides.

TOURTELOTTE PARK. IR TEC

In the O. K. such a mineralized zone has been followed up across the blue
limestone quite to the shale, and there is rich ore lying immediately under
the shale. The ore in these steeply dipping shoots is crushed and broken
blue limestone, more or less dolomized, but with blue limestone on both
sides a short distance away from the vein, and it contains less barite and
more lead and silver than do the great masses of low-grade ore which are
found everywhere along the Contact fault. The occurrence of the two
varieties of ore under different conditions suggests two slightly differing
periods of mineralization.

In the region occupied by these mines the porphyry sheet, which in
the whole southern part of Tourtelotte Park and on Aspen Mountain lies
very close to the Silver fault, seems to have cut up abruptly to the south
across the shales, so that the amount of shales overlying the blue limestone
is greatly increased and the porphyry disappears altogether. Thus the
Last Dollar shaft, which is 465 feet deep, passed through 35 feet of glacial
drift, about 220 feet of Weber shales, and then crossed the Silver fault into
the blue limestone.

Little Rule tunnel— The Little Rule tunnel starts just above the Contact
fault, in a place where the original blue limestone has been entirely altered
to dolomite. It runs east, following a bedded vein which contains a great
deal of barite, but not enough lead and silver to make it profitable ore.
The rock on both sides of this vein, above and below, is altered to dolo-
mite, or “‘short lime,” and is considerably iron-stained, especially near the
vein. Near the end of the tunnel the rock, and with it the vein, becomes
broken and shifted about. A little farther in the Sarah Jane fault is
crossed, and the Weber shale, which lies on the east side of the fault at
this point, is entered. There is not much mineralization along the Sarah
Jane fault at this point, and very little pay ore has been found in the
workings.

The Sarah Janemine—The Sarah Jane workings are mostly in a zone of
shattered and highly altered rock in the vicinity of the Sarah Jane fault.
Although much of this rock was originally blue limestone, it is now all
dolomized. The ore, which is all oxidized, occurs in pipelike shoots,
which run up through the altered rock. It is highly siliceous, as is also
the rock in its immediate vicinity. Another peculiarity in the ore is the
presence of a large amount of calcite.

MON XXXI——12

178 GEOLOGY OF ASPEN MINING DISTRICT, COLORADO.

Highland Light shatt—The Highland Light shaft goes down through the
Weber shale and crosses the Silver fault into the blue limestone. A small
amount of ore has been taken out.

Hannibal mine——The Hannibal shaft, which is directly east of the Little
Rule tunnel, on the opposite side of the Sarah Jane fault, passed through
approximately 200 feet of porphyry and a small amount of shale to the
Silver fault below, where it encountered the blue limestone horizon, here
almost entirely altered to brown ‘‘short” dolomite. At the bottom of the
shaft ore occurs in what appears to be the Contact fault, or at the intersec-
tion of some more steeply dipping fractured zone with the fault. The ore
zone is locally as much as 8 or 10 feet wide, and the pay streaks occur in
shoots and chimneys in this zone. On the west side the ore has been cut
off by a slight fault, which strikes north and south and dips 80 degrees to
the east. This fault is probably auxiliary to the Sarah Jane.

Jay Gould mine —The Jay Gould shaft passes through a small amount of
shale into blue limestone which is irregularly dolomized and stained brown.
At the bottom a drift runs northwest parallel to a slip in the rocks. This
drift is partly in blue limestone and partly im dolomite, which probably
results from alteration of the limestone. The workings show a considerable
amount of the alteration which usually attends mineralization, such as the
replacement of the lime in the rock by silica and the presence of crystal-
lized calcite, but no pay ore has been found.

Buckhorn No. 2 mine——The Buckhorn No. 2 has a shaft about 200 feet deep,
which cuts the Contact fault about 75 feet from the collar. Ore is present
in considerable amount in the Contact fault, on the west side of the shaft.
This ore runs high in lead and baryta, and does not contain as much siliea
as does that of some adjoining mines. Where most of the ore has been
removed a slight synclinal basin is exposed.

Long John shaft The Long John shaft is probably about 260 feet deep,
and at this depth cuts the Silver fault. There is some ore in the Contact
fault between the shale and the blue limestone.

Adelaide shatt——The Adelaide shaft is 250 feet deep, and is mostly in
altered, silicified, and dolomized rock which belongs to the Leadville for-
mation. The workings are chiefly on the Contact fault, but no ore has
been developed. It is a peculiarity of the rock in these mines, however,
and in the neighboring mines, that while there has been no great minerali-

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TOURTELOTTE PARK. 179

zation, yet the process of silicification, which usually attends ore deposition,
has gone on more extensively than in places where more ore has been found.
This process results in the formation of zones of jasperoid, which follow
fractured zones and faults, and by means of this jasperoid the faults may
be traced continuously over the surface. Microscopic study of this rock
shows that some iron was deposited at the same time with the silica, but
apparently no great amount of the rarer metals.

TOURTELOTTE PARK MINING MAP.

The detailed map of Tourtelotte Park on the 300-foot scale comprises
essentially the whole of the productive area, and in it are situated nearly
all the mines which have been described. The region displayed is the
same as that on the 800-foot map, but is slightly more detailed and comes
out clearer by reason of the enlargement. On this map the blue Leadville
dolomite and the blue limestone which overlies it are distinguished by
different. colors, and the Contact fault which separates it is represented as
such, while on the 800-foot map both these formations are grouped together,
and the Contact fault was omitted. There are also put in several small
faults, which were not important enough to be shown on the 800-foot
scale, but which are sufficiently well marked to be put into the more
detailed map. Such a fault, for example, is that found in the Camp Bird
mine, which is represented as a splinter of the Silver Bell fault running
across to the Justice fault. The faults of the east-west system which have
not been described in the 800-foot map of Tourtelotte Park have mostly
been described in connection with the mine workings. There are seven
"cross sections and one longitudinal section, which show the geology as
developed in the mines and on outcrops as accurately as possible. Nearly
all the points shown have already been discussed, and a study of the map
and sections will explain the structure far better than any written descrip-
tion could do. The ore bodies are not shown in the sections, but the
oceurrence of the ore in general throughout this whole area may be
summarized as along the Silver and the Contact faults, or in the blue
limestone which lies between these two.

The accompanying plates give some idea of the general appearance
of Tourtelotte Park. Pl. XXIII is a view taken from the west side of
Spar Gulch, just north of the Best Friend shaft, and looks south up Spar

180 GEOLOGY OF ASPEN MINING DISTRICT, COLORADO.

Gulch, with the head of Tourtelotte Park in the distance. The cliff in the
foreground is of blue limestone, and is probably a sort of escarpment,
determined primarily by the Hallet fault. At the left is Copper Hill, and
on the hill at the right is the Dixon shaft house. Pl. XXIV is a view from
a point farther south, overlooking the main Tourtelotte Park basin. This
is taken from near the Camp Bird mine, and shows in the center the Last
Dollar and Justice shaft houses. The hill in the background is outside of
the Tourtelotte Park mining map to the south, and the Justice fault runs
approximately through the depression in the center. Pl. XXYV is a view,
taken farther up the gulch, of an area shown in the upper left-hand corner
of the preceding plate. It shows the uppermost workings of Tourtelotte
Park near the point where the ore-bearing faults outcrop and pass into the
air. At the bottom of the picture is the Last Dollar shaft house and dump,
while farther up are the dumps of other mines, such as the O. K., Minnie
Moore, North Star, and Silver Bell. At the left is Copper Hill, with the
dump of the Copper King shaft on top. Beyond Tourtelotte Park the
view looks across the Roaring Fork and other valleys to the summit of
the Sawatch Range.

SMUGGLER MOUNTAIN.

Smuggler Mountain is outside the district of greatest disturbance, and
does not contain any complicated faulting or folding. It has, however,
been the source of enormous ore production, being intimately connected
with Aspen Mountain and constituting the northern part of the rich
mineral district which is centralized in Aspen Mountain and extends from
the southern part of Tourtelotte Park to the valley of Hunter Creek.
Workings are now nearly continuous between Aspen and Smuggler
mountains beneath the Roaring Fork Valley. Although faulting in this
region is not very extensive, yet there is developed in the mine workings,
especially in the Smuggler and the Mollie Gibson, some complicated
structure, which results from the action of faults of different systems and
ages operating in a restricted field.

Pl. XXVI is a view of Smuggler Mountain, with the town of Aspen
in the foreground. At the base of the mountain, just to the right of the
center of the picture, are the shafts and dumps of the Mollie Gibson,
Smuggler, and Free Silver workings, while the great dump of the Cowen-

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SMUGGLER MOUNTAIN. 181

hoven tunnel is a little farther to the left. In the gulch on the mountain
side is the dump from the Johnson tunnel, which now forms part of the

Della S. mine.
MOLLIE GIBSON MINE.

The so-called “contact” in the Mollie Gibson mine, along which most
of the exploration for ore is made, is the Silver fault, which here separates
the Leadville dolomite from the Weber shale. Between these formations
there is a thick breccia containing fragments of blue limestone and occa-
sionally of ore. An interbedded sheet of porphyry lies in the contact near
the shale, sometimes separated from the dolomite by 20 or 30 feet of shale,
sometimes resting directly against it. This is the situation from the
Smuggler line on the north to a point 1,300 feet south of the Mollie
Gibson shaft, where the edge of the blue limestone comes in between the
shale and the dolomite. From this point the limestone wedge broadens
very slightly toward the south, so that probably 40 or 50 feet is the
maximum thickness in the Gibson workings. From the point of appear-
ance of the blue limestone there are two “contacts,” one between the
brown dolomite and the blue limestone, and the other between the blue
limestone and the shale. The former is the Contact fault, which is cut off
by the Silver fault at the pomt where the blue limestone disappears to the
north. The latter is the Silver fault, as before. Both these faults are
marked by a crushed zone of rock, with polished walls. From the point
of junction of the Contact and Silver faults southward the Contact fault is
generally prospected for ore, although there is no reason why the Silver
fault should not also be productive.

Gibson fautt—The Gibson fault, which belongs to the Della system, is
displayed in every level of the Mollie Gibson. It has an east-west strike
and a southerly dip of about 30 degrees, and faults both the Silver and the
Contact faults. The lateral displacement or perpendicular separation of
these earlier faults by the Gibson varies at different levels, showing that
the latter fault diminishes with depth. In the fourth level the separation is
about 105 feet, in the eighth about 70 feet, and in the tenth about 50 feet.

Emma fault—Qn the seventh level, 220 feet north of the Gibson, is a
fault having the same attitude and direction of movement. This move-
ment, which is to the west on the north side, results in a perpendicular
separation of about 35 feet. The fault is also shown in the ninth and

182 GEOLOGY OF ASPEN MINING DISTRICT, COLORADO.

tenth levels, and is probably the same as that which cuts the 40-foot level
of the Smuggler.

Smuggler faultt—The Smuggler fault comes into the Mollie Gibson mine on
the ninth level north. At this point the perpendicular separation of the
Silver fault by the Smuggler is about 70 feet, showing that the latter fault
increases as it goes down.

Della fault—The Della fault just cuts the end of the tenth level north in
the Mollie Gibson mine, and is not otherwise displayed in the workings.

Clark faut——There is evidence tending to show the existence of a fault
nearly parallel with the Silver fault and only a short distance from it.
This fault has displaced the original ore bodies which formed after the
development of the east-west southerly dipping faults. This fault is recog-
nized throughout the Mollie Gibson and Smuggler by the mine managers,
and is called the Clark fault. On the fifth, sixth, and seventh levels of the
Mollie Gibson it has been identified as a highly fractured zone, with dolomite
on both sides, not far away from the Silver fault. Its general effect is an
upthrow on the east side, so that the apparent dip of the ore-bearing rocks
becomes much steeper. It is probable that this fault is not a single plane,
but is rather a broad zone made up of many parallel faults, each of which

has a downthrow on the west. In the upper workings of the Smuggler.

mine several of these parallel faults may be recognized, with the effect on
the general dip which has been mentioned. On account of the approximate
parallelism between the Clark and the Silver faults the former often lies
between dolomite and shale, and in this case can not always be distinguished
from the Silver fault. The best evidence which is offered as to the nature
of this fault is the displacement of the peculiar ore bodies in the Smuggler
and Mollie Gibson mines. The main Mollie Gibson ore body consists of a
peculiarly rich ore, which contains a large amount of polybasite and native
silver inclosed in flesh-colored barite, locally called pmk spar. This ore
occurs along the uppermost of the Della system of faults—the Gibson.
Northward along the fault comes in lead and silver ore, not so high in grade,
and finally ore very rich in zine, such as is found only in a restricted region
here and ina similar restricted region at Lenado. ‘This zine ore, consisting
of mingled sulphides and carbonates, is found in the uppermost level of the
Smuggler mine and crops at the surface in an open cut. In the Mollie
Gibson the rich polybasite ore is cut off on the west side at the contact with

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SMUGGLER MOUNTAIN. 183

the shales, and the nature of the contact between shale and ore shows the
existence of a fault which originated since the ore deposition. From the
point where the solid body of ore was cut off ore was followed along
the fault plane for some distance, growing gradually smaller in amount as
the distance from the main body increased, and finally becoming too poor to
be profitably worked. This ore consisted of bowlders and angular fragments
in the breccia and of native silver cementing the fragments, the last being
evidently a secondary formation. In the Smuggler mine what appears to
be the same ore body is found, having a general connection with the Smug-
gler fault, as the ore body in the Mollie Gibson has with the Gibson fault.
In the Smuggler is found the same rich polybasite and native silver ore
inclosed in pink spar. Above this, along the fault zone, comes low-grade
N Ss

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DEVELOPMENT

Fig. 7.—Diagram of Smuggler and Mollie Gibson ore bodies.

lead ore and a body of zinc ore, exactly identical in every respect with the
zinc ore found at the top of the Smuggler shaft. Taking into consideration
the fact that the ore body in the Mollie Gibson has been cut off by a north-
south nearly vertical fault since the ore deposition, and that the Smuggler
ore body is almost exactly the same as that in the Mollie Gibson, it seems
probable that the two ore bodies were originally one and have been separated
by this faulting. Since the east-west striking and southerly dipping faults
were formed previous to the ore deposition, as is shown in both these mines,
the displacement of the ore must have been accompanied by the displace-
ment of the preexisting faults also. It follows from this that the Gibson
fault along which ore occurs on the Mollie Gibson was originally the same
as the Smuggler fault on which it is found in the Smuggler. Fig. 7 is an

184 GEOLOGY OF ASPEN MINING DISTRICT, COLORADO.

idealized diagram showing the ore bodies in the Smuggler and in the Mollie
Gibson, the section being taken along the plane of the Clark fault. Fig. 8
(see p. 199) gives a diagrammatic representation of the successive stages
in the history of the rocks as worked out in the Mollie Gibson and Smug-
gler mines.

Occurrence of ore in the Mollie Gibson —'"he main ore in the Mollie Gibson occurs
on the Gibson fault, with dolomite below and shale above. Most of it was
actually found in the shale, resting on a hard, polished, striated floor of
dolomite. This ore was of a rich character, having large amounts of poly-
basite and native silver. In structure it was solid and massive, containing
the polybasite in regular blotches or small true veins, and the large bodies
showed banding conformable to the plane of the fault. These phenomena
show unmistakably that the ore was originally deposited along the fault,
and there is little evidence of movement since its deposition. The rich
polybasite body appears to lie in a sort of subordinate shoot, trending south
of east and lying on the Gibson fault plane. This shoot is marked by
exceptionally large and rich bodies of a nature not found elsewhere in the
mine. It is noteworthy that this rich shoot is practically the lower termi-
nation of the ore on the Gibson fault. Most of the ore below this is native
silver, which, from the nature of its occurrence, is manifestly a secondary
deposit leached from the rich ore above. Some of these secondary deposits
are, however, of considerable size, and empty vugs are often found beauti-
fully and elaborately festooned with delicate wires of silver. The Gibson
fault becomes entirely barren a short distance farther down. Above the
polybasite ore, however, the ore appears to be pretty continuous, but the
amount of silver becomes less and there appears more lead and zine. Far-
ther up the zinc has formed in especially large quantities. At the intersec-
tion of the Gibson and the Clark faults ore has been stoped down for 100
or 200 feet. This ore was richest close to the main body and became pro-
gressively poorer with depth. It is a breccia which carries angular frag-
ments of polybasite and pink spar, such as form the solid body above, and
there is also a large amount of wire silver, evidently secondary, which has
formed in the interstices of this breccia. The ore has been followed along
the fault some distance north also, but isnot found southward. This ocecur-
rence of ore in the breccia along the Clark fault shows that the movement
was down and to the north on the west side; and this coincides with the

SMUGGLER MOUNTAIN. 185

conclusion that the ore bodies of the Smuggler and of the Gibson were
originally the same. At various points throughout the mine there are local
formations of ore, which consist mostly of wire silver that has formed in the
interstices of a breccia. These ore deposits, like some already described,
are evidently of secondary origin, later than the main ore deposition.

Pl. XLI, C, is a-geological section of the Mollie Gibson, made through
the working shaft on an east-west plane. This illustrates the following
features, which have already been described: First, the formation of the
Silver fault, which separates the Weber shales from the Leadville dolomite;
second, the development of the Della system of faults, which displaced the
Silver fault with the surrounding formations and effected a general offset
to the west on the lower or north side; third, the deposition of ore, which
took place mostly at the intersection of the Silver fault with the later faults
of the Della system; fourth, a movement nearly along the plane of the
Silver fault, which, however, assumed locally a slightly different plane.
This movement sometimes apparently coincides with the Silver fault, but
ordinarily is more nearly vertical, and this has cut off the faults of the
Della system and the ore which occurs along them. Thus the Gibson and
the Emma faults are represented as cut off on the west side by this move-
ment and as thrown down with the rock formations. The Smuggler fault
at the extreme lower left-hand corner of the section was probably origi-
nally continuous with the Gibson, while the continuation of the Emma
fault may well have been the Della, which is not represented in the section,
but which lies below the Smuggler fault at about the same distance that
the Emma lies below the Gibson.

SMUGGLER MINE.

In the Smuggler mine the zone which is usually followed for ore is, as
in the case of the Mollie Gibson, the Silver fault, which separates the shale
on the west from the dolomite on the east side. There is always a zone
of fractured material along this fault, and generally parallel slips with
polished and striated surfaces in the harder rock on each side. There is no
blue limestone in place in the Smuggler, the east wall of the Silver fault
being always dolomite. On the upper levels the dolomite is characteristic
“brown lime,” yellowish brown in color, and very closely jointed, or
“short.” In the upper levels, also, the shale is soft. In the deeper levels,

186 GEOLOGY OF ASPEN MINING DISTRICT, COLORADO.

however, such as the eighth and ninth, which are as yet beyond the reach
of oxidizing agents, the dolomite is hard and dark blue, with frosty luster,
and the soft shales change to hard, black, argillaceous limestone. In
several places there is exposed in the shale near the fault a sheet of
porphyry, which does not appear to exceed 15 or 20 feet in thickness and
which lies next to the dolomite. :

Della fautt—The Della fault is well exposed in the Smuggler mine in
the third, eighth, and ninth levels, having its usual movement to the west
on the north or lower side.

Smuggler fault—The Smuggler fault is shown in the Clark tunnel at the
northern end of the mine. It is also shown in the tunnel level and in
the eighth level, running parallel to the Della.

Emma fault—The Emma fault, which is parallel with the Smuggler and
the Della, outcrops at the northern end of the Smuggler ‘‘open cut” close
to the shaft, and is seen in the 40-foot level, where its lower wall forms a
smooth, polished, striated floor upon which the ore rests. This ore is that
variety, rich in zine, which is so characteristic of this shoot.

Clark fault——Several of the parallel slips which belong to the Clark fault
- system are seen in the open cut of the Smuggler, and also in the Clark
tunnel. They are nearly vertical in dip and have a north-south trend.
They have a general upthrow to the east, causing a marked steepening of
the line between the dolomite and the shale, which goes by the name of the
“contact.” Through the action of this fault the original ore bodies, as well
as earlier fault systems, have been displaced.

Nature of ores—Several varieties of ore are found in the Smuggler. The

peculiar rich silver ore, made up of polybasite and native silver inclosed —

in flesh-colored or gray barite, which corresponds to the rich ore in the
Mollie Gibson, is found in a continuous shoot in the seventh and eighth
levels south. From this shoot of solid ore broken material was followed
along the Clark fault, becoming progressively poorer as the distance from
the main body increased, and finally, as in the case of the Mollie Gibson,
becoming so low in grade as not to repay working. In the Smugeler, how-.
ever, the train of crushed ore was followed upward from the main body,
while in the Gibson it was followed downward. ‘This circumstance, among
others, goes to show that originally the two bodies were probably one.
As in the Mollie Gibson, the rich polybasite ore is confined to this one

SMUGGLER MOUNTAIN. 187

shoot. The majority of the other ores carry considerable barite and
varying amounts of lead and silver. There is a great deal of low-grade
ore consisting of altered dolomite carrying lead. In the upper levels this
ore is oxidized and can not be profitably mined, but in the lower ones,
where it occurs as a sulphide, it can be concentrated by mechanical proc-
esses and profitably handled when averaging only 8 ounces of silver to
the ton.

Occurrence of ore—'The main occurrence of ore in the Smuggler mine is in
connection with the Smuggler fault. Along this fault the ore has formed
chiefly at two places, one at the south and one at the north end of the
mine. The occurrence of the rich polybasite ore on the Smugeler fault
on the seventh and eighth levels south has already been mentioned. At
the northern end of the mine, at the Clark tunnel level, there are immense
stopes out of which a large body of high-grade ore has been taken. These
stopes are along the Silver fault at its intersection with the Smugeler fault
above, and are continuous down from this level to the plane of the Della
fault. The method of occurrence of the ore at this place is shown in PI.
XLII, A, while that of the rich polybasite ore at the southern end of the
mine is seen in Pl. XLI, D, which rens through the Smuggler shaft. The
Smuggler fault between these two points carries considerable ore at
intervals, and at one point is marked by large bodies of oxidized zine ore.
This zine ore, which is found in the third and fourth levels north, is identical
with that found in the open cut near the shaft and on the 40-foot level at
the shaft, and it is probable, as already stated, that these two bodies were
originally one, and that they have been separated by the Clark fault.

SUMMARY OF MOLLIE GIBSON AND SMUGGLER GEOLOGY.

These two mines are distinguished from the rest of the camp in the
possession of peculiar ore shoots, which are characterized by flesh-colored
barite, by poverty in lead, and by a large amount of polybasite and native
silver. Both of these ore shoots lie along east-west faults of the Della
system, and have evidently formed along fracture zones which were
developed subsequent to the Della faulting, but previous to the ore deposi-
tion. The existence of these fracture zones is shown by the nature of the
ore, which is mostly barite containing angular fragments of the country
rock, and thus has the character of a true vein filling. The lower-grade

188 GEOLOGY OF ASPEN MINING DISTRICT, COLORADO.

ore, on the other hand, which hes on the Gibson and on the Smuggler
faults side by side with the polybasite ore, is evidently a replacement or
impregnation of the dolomite, and does not contain a large amount of barite
or other gangue material. It seems probable that after the deposition of
the low-grade ore, but before the cessation of the period of ore formation,
these east-west fracture zones were formed, and that along these zones
fresh solutions deposited the polybasite and barite. The native silver
appears to be a product of alteration from the polybasite.

Evidence goes to show that subsequent to all the mineralization a fault
was developed nearly parallel with the Silver fault, but slightly steeper.
The effect of this fault was to throw the rocks on the west side downward
and to the north. Thus the original polybasite ore shoot was divided into
what are now the Mollie Gibson and the Smuggler ore bodies. This fault
must have also faulted the preexisting faults of the Della system. On this
supposition the Gibson fault and the Smuggler fault were originally one.
Measurements show that the Gibson fault narrows going down, its per-
pendicular separation being about 50 feet in the tenth level of the Mollie
Gibson and 110 feet in the third. The Smuggler fault, on the other
hand, has a more important movement with increasing depth, so that 10 or
15 feet of perpendicular separation in the fourth level of the Della S.
becomes 70 feet in the ninth level of the Mollie Gibson. There is abun-
dant evidence of this postmineral faulting below the rich stopes of the
Mollie Gibson, in breccias containing angular fragments of the ore, often
cemented by native silver. Mine sections on Pls. XLI and XLII show

the structure of the Smuggler mine as described. They are taken at oppo- -

site ends of the mine, one through the shaft and one through the great
stopes at the end of the Clark tunnel.

COWENHOVEN TUNNEL.

The Cowenhoven tunnel starts on the north side of the Roaring Fork
Valley at the base of Smuggler Mountain and runs under the mountain to
a point below Hunter Creek Valley. It connects all the mine workings
along the ore-bearing zone which lie north of the Smugeler mine, and is
used for transportation and dramage. The tunnel starts in an almost
easterly direction, and after passing through a considerable thickness of
glacial drift runs into red and white arenaceous limestones and the gray

SMUGGLER MOUNTAIN. 189

limestone which forms the base of the Maroon. Near the contact of the
gray Maroon limestone with the Weber shales there is a heavy breccia, 40
or 50 feet thick, which shows movement, probably along a bedding fault.
Near this fault zone the shales are bent from their normal position. After
passing through a considerable thickness of shale some porphyry is tray-
ersed, and then shales to the contact with the brown Leadville dolomite,
where the Silver fault comes in. There is no blue limestone in the tunnel,
or indeed anywhere in the Smuggler Mountain mines. After cutting
through the Leadville dolomite a little distance the Della fault is encoun-
tered, as a consequence of which the Parting Quartzite crosses the tunnel.
Passing through the fault, the tunnel swings to the north until it again
reaches the Silver fault, and from this point runs in a general northeasterly
direction, in Leadville dolomite, not far from the Silver fault. Sometimes,
however, it gradually diverges a considerable distance from the fault, as is
the case opposite the Park Regent station, where the Parting Quartzite
outcrops in the tunnel. The strike of this quartzite is nearly parallel with
the trend of the tunnel, but is a little more easterly, so that it enters the
tunnel from the south and passes out of it when the tunnel begins to curve
to the north, as it does at this point. The curve in the tunnel was necegsi-
tated by the action of a small east-west fault, which is called the Regent.
This has shoved the formations to the west on the north side. From this
point the tunnel runs entirely in dolomite until in the Alta Argent mine
another east-west fault is encountered, which has likewise a movement to
the west on the north side. Just before reaching this fault the tunnel had
again run so deeply into the Leadville dolomite that it is nearly down to
the Parting Quartzite, so that on crossing the fault it runs into Silurian
dolomite, the Parting Quartzite having been shoved over to the west side,
where it probably soon runs into the Silver fault.

The Smuggler Mountain mines which this tunnel connects form a
continuous series of workings reaching from the Smuggler on the south
to the Alta Argent on the north.

DELLA S. MINE.

The Silver fault has been followed throughout the Della S. as the
horizon on which ore most usually occurs. On the west side of this
fault is the Weber shale, and on the east the Leadville dolomite, with no

190 GEOLOGY OF ASPEN MINING DISTRICT, COLORADO.

intervening blue limestone. There are occasional blocks of porphyry in
the breccia along this fault throughout the workings, and in the southern
part of the mine a continuous band comes in at or near the fault. There
are also bowlders of blue limestone in the breccia in the southern part of
the workings, showing that the drag has been from the south.

Faults—The Della S. fault has an east-west trend, and dips to the south
about 30 degrees. It has an offset to the west on the north or lower side of
about 200 feet. According to Mr. D. W. Brunton, striation on the fault
plane shows that there has also been a southerly movement, so that the top
block has moved southeast over the bottom. This is the only large fault
in the Della S. mine, but there are many small ones, which are generally
parallel to it and belong to the same system. None of them, however,
appear to have over 50 feet displacement.

Occurrence of ore—he ore occurs in the neighborhood of the Silver fault
in certain localities. Throughout the mine there are recognized two streaks
or veins—the foot-wall streak and the hanging-wall streak. The former is
in dolomite on both sides, and is generally 5 or 10 feet from the contact
with the shale. In some of the larger stopes below the tunnel, where the
ore occurs in solid dolomite, the exact locality of the Silver fault is not
known. The hanging-wall streak is in the Silver fault itself, or even in
the shale above. At one place in the fourth level ore has been taken out
40 feet from the fault plane m the solid shale.

In the bottom of the Della 8. incline were observed two bands of
barite, which are conformable to the Silver fault. Hach of these bands
was about a foot thick and constituted rich ore. Between them was 5 or 6
feet of dolomite, which was mineralized so as to be profitably mined. The
Silver fault was not seen here, for upon the highest barite vein there still
lay barren dolomite. These veins, which constitute the so-called foot-wall
streaks, as well as those forming the hanging-wall streaks, are evidently
formed on slips auxiliary to the main Silver fault, on both sides of which
they-lie. In the dolomite these slips are especially well marked and seem
to be indefinite in number. They are nonpersistent and are generally
more or less mineralized. The slip nearest the main fault is nearly always
the richest, beg generally richer than the ore on the fault plane itself.

It is not at all points, however, that the Silver fault with its auxiliary
slips in the dolomite and the shale has been made the locus of very

———a

SMUGGLER MOUNTAIN. 191

extensive ore deposition. Where the ore has beem taken out in large
quantities, as is the case in the Della mine, there are developed certain
definite zones or shoots along the Silver fault which have been remarkably
productive, while most of the other rock along this fault contains so little
mineral as to be practically worthless. The most important of these ore
shoots lies directly below the Della 8. fault, where this comes into contact
with the Silver fault. At the junction of these two on the lower side there
are continuous stopes reaching from the Regent ground at the top of the
hill down to the fourteenth level in the Della. These stopes are often
immense, being in places 100 feet high, and they nearly always run quite
up to the Della fault and there stop. The Della fault. itself, however, is
very slightly mineralized, as a general rule not being worth prospecting;
but low-grade ore is frequently found along it, and in places bodies which
are workable. The intersection of the Della fault with the Silver fault
- immediately above is practically barren, being mineralized to no greater
extent than the Della fault itself. Another important shoot follows the
Smuggler fault up through the Della workings. This fault grows slighter
as it goes up, and is not always identifiable; but along it the ore shoot is
large and continuous, and is entirely similar to that formed along the Della
fault. The line of stopes is continuous to the bottom of the glacial drift.
There are other well-marked shoots in the mine which have been followed
out, and each of them seems to be connected with some slight fault or well-
marked fracture zone, the ore occurring at the intersection of these faults
or fractures with the main Silver fault.

Nature of the ore—'T"he ore in the Della S. seems to be of two distinct
varieties. One of these is a dolomite which has been altered and softened,
and which contains a paying amount of metals; but there is no large
amount of vein material, and the process of mineralization seems to have
been in large measure a replacement. The dolomite is yellowish brown in
color, and is blotched with barite and sometimes with lead. The more
common variety of rich ore is very high in baryta and poor in lead. It
generally occurs in veins, made up chiefly of coarsely crystallized barite,
and called “spar streaks.” In this barite there occurs a small and variable
quantity of gray sulphide, which is probably in part, at least, tetrahedrite
or tennantite. This sulphide goes by the name of ‘gray copper,” and
occurs in blotches or in small vein fillmgs which are not persistent. - A very

192 GEOLOGY OF ASPEN MINING DISTRICT, COLORADO.

common and characteristic form of ore contains numerous small veins of
tetrahedrite, which often form crosses in the barite. This peculiar ore goes
by the name of “crisscross spar.” The crosses are doubtless deposited at
the intersection of microscopic cracks, and their occurrence shows that the
metallic sulphide was later in deposition than the barite. This sulphide is
highly argentiferous, and is always a valuable ore. On oxidation a small
amount of green copper carbonate is formed from it, which stains the rock
and is taken by miners throughout the camp as an evidence of rich ore.
In places, however, this carbonate has been carried some distance and
deposited in barren barite. This barren spar has then the appearance of
ore, while it is actually destitute of value.

From the phenomena in this mine the following deductions as to the
manner of ore depositions may be made: First, the formation of the Della
fault preceded the ore deposition, since this fault has been one of the most
important factors in determining the locus of the ore. Second, since it is
on the under side of the Della and other faults that ore has formed, and
since on the upper side the rock is nearly barren, it is probable that the
ore-bearing solutions were ascending, and that they came up along the
Silver fault to the Della, at which point they deposited their metallic
contents. Third, although the barite is the gangue of the metallic sulphide,
it was deposited in large measure before the richer metals were, since in the
crisscross spar and similar ores the valuable sulphides have been deposited
in cracks which were formed in the barite subsequent to its crystallization.
These cracks are purely mechanical, such as might arise from any strain in
the rock.

Although the Della fault existed previous to the ore deposition, yet
there has been motion along it subsequent to this period. Indeed, there is
evidence from the deformation of old raises and drifts that movement
is going on along the fault at the present day. In most of the other faults
there is also evidence of some movement subsequent to the ore deposition.
This is true even of the Silver fault, where broken, angular fragments of
ore may be found in the breccia.

Pl. XLII, B, is a section through the Della mine, showing the actual
occurrence of the ore. Although the shape of ore bodies is somewhat
generalized, the main ones occur as represented, in connection with the
Della and Smugeler faults, while the Silver fault has also been very

fo)
important in determining the locus of ore deposition.

SMUGGLER MOUNTAIN. 193
BUSHWHACKER MINE.

The Bushwhacker mine lies next north of the Della S., along the
Cowenhoven tunnel. The nature of the Silver fault is the same in this
mine as in the Della, since it has solid dolomite on the east side, with
shale on the west. Between the shale and the dolomite is a brecciated
zone which is very thick, so that the solid shale has hardly been cut in
the whole workings below the shaft. This breccia contains shale and
porphyry, with large bowlders and slabs of blue limestone, but most of it
is so ground up and altered that its original nature is not discernible. A
dike of porphyry cuts across the northern end of the mine, as seen in the
lower levels. From here it passes up through the Park-Regent, appearing
on nearly every level. It has a width of from 2 to 20 feet and a dip of
60 degrees or-less to the northeast, thus cutting up through the Leadville
dolomite to the Silver fault. There are no developments to show whether
it is continuous through the breccia of the Silver fault into the shale
beyond, but, so far as has been seen, it appears to be faulted with the
inclosing rock, for, on approaching the fault, it becomes squeezed and
slickensided, and angular fragments of it are found embedded in decom-
posed limestone.

There are two main ore shoots in the Bushwhacker, as pointed out by
the manager, Mr. Bulkley. These shoots are parallel. One reaches from
the first to the third level, and is continuous north and south to the Park-
Regent on one side and to the Della on the other; the second is along the
sixth and seventh levels, and the two come together and disappear in |
the Park-Regent workings. Along these zones the stopes go up vertically
for 40 or 50 feet, both the dolomite below the Silver fault and the
ground-up material of the breccia being mineralized. Mr. Bulkley pointed
out that both shoots are marked by slight faults which cause an offset to
the west on the lower side, so that a kind of bench is made along the
Silver fault; and it is along this bench that ore has been formed. The ore
of these two shoots, however, was not exactly alike, the lower one being
almost entirely a high-grade, heavy spar ore, containing much gray
copper, while the upper one contained very little barite and carried much
lead and some zine. Besides the two most important ore channels there
are several shorter ones, one or two of which have a northwest trend,

MON XXXI——13

194 GEOLOGY OF ASPEN MINING DISTRICT, COLORADO.

nearly at right angles with the main shoots. Except along these zones the
Silver fault is practically barren.

Pl. XLII, C, is a cross section through the Bushwhacker mine and
through the southern part of the Park-Regent mine, which lies at this
point above the Bushwhacker on the Silver fault. The features which
have been described in the Bushwhacker mine will be seen in this section,
while those which belong to the Park-Regent will be next described.

PARK-REGENT MINE.

The nature of the Silver fault in the Park-Regent is identical with that
which has been described in the Bushwhacker and Della. Most of the
workings run in dolomite below the fault, although the solid shale which
forms the hanging wall is cut in many places. Between the solid shale
‘and the dolomite there are generally about 40 or 50 feet of broken blue
limestone and shale; but sometimes the dolomite and the solid shale come
very close together, with practically no intervening breccia. The dip of
the fault diminishes markedly upward, and increases with depth. This is
shown by the Iowa incline, which, at the point near the bottom of the

Towa shaft, is in solid shale, but soon runs into dolomite going down. .

Where the incline runs into the Cowenhoven tunnel there are exposed
some of the shaly and dolomitic beds of the Parting Quartzite, which strike
with the tunnel and dip steeply west. At this point, however, the tunnel
turns so as to run upward across the formations, reaching tlie solid shale
again in a short distance.

There is no continuous sheet of porphyry running parallel to the
Silver fault in the Park-Regent, although there are occasional bowlders of
it in the fault breccia. The dike which was noted in the Bushwhacker
continues steadily across the Regent, and is last seen on the .first or
uppermost level.

Regent fault The Regent fault is marked in the tunnel by an offset to the
west on the north side, the offset appearing to be about 30 feet. The main
line of faulting is marked by a continuous open watercourse, traceable
from the top to the bottom of the mine. From this main break south there
is a series of parallel fractures, which are also often watercourses. The
Regent fault appears to be nearly vertical in dip, and therefore to belong
to a slightly different system from that of the Della fault.

a

SMUGGLER MOUNTAIN. 195

Iowa fault— Just east of the bottom of the Iowa shaft a vertical fault is
well exposed, which thrusts up the Silver fault on the east side from 40 to
60 feet. This fault is probably a continuation of the Clark fault, which is
shown in the Smuggler and the Mollie Gibson, or at least belongs to the
same system.

Other faults —At various places in the workings of this mine there is noticed
a series of abrupt rolls in the Silver fault, which cause local flattenings, or
benches, and these rolls may be developed in places into slight faults.
The Della fault is exposed in the southern part of the upper workings, and
the Parting Quartzite is seen running into the fault on the lower side.

Occurrence of ore —The great Thompson stopes of the Park-Regent evidently
lie near the intersection of the Della fault with the Silver fault above, and
from the Della fault plane the ore was taken out up to the glacial drift.
These stopes are now caved in so as to be inaccessible.

The ore now being taken out in the lower workings also lies in a
decided shoot, which is marked by a continuous stope, extending at the
time of examination from the tenth to the seventeenth level, a distance of
about 400 feet. ‘The long axis of this shoot is northwest and southeast,
corresponding to the trend of the small faults belonging to the Regent sys-
tem. Its width, taken in a northeast-southwest direction, appears to be
about 150 or 200 feet, and the ore averages 5 or 6 feet in thickness. The
general plane of this shoot is parallel to the Silver fault, but most of the ore
lies in the dolomite, often with several feet of solid barren dolomite between
it and the fault breccia. It is therefore formed along a slip parallel to the
Silver fault. Throughout Smuggler Mountain these slips, which are often
50 or 60 feet away from the main fault, are frequently highly mineralized.
The slip which hes close to the Silver fault in the dolomite is generally most
productive, and is often more highly mineralized than the fault plane itself.

The two chief ore shoots of the Buskwhacker are continuous into the
Park-Regent, converging toward the north, so that they probably meet near
the Iowa incline. Where these shoots come together they are connected
by no fewer than four distinct parallel northeast-southwest shoots, which
carry a large amount of very rich ore. Along most of these shoots there
are fractures or watercourses. The two slight faults which give rise to
the main Bushwhacker ore shoots come together and end in a bench in the
Park-Regent.

196 GEOLOGY OF ASPEN MINING DISTRICT, COLORADO.

The section PI. XLII, C, which passes through the Bushwhacker, also
passes through the Park-Regent higher up. Near the upper part of the
section the ore which was found in the Thompson stopes is seen resting
on the Della fault and running up until cut off by the glacial drift. The
occurrence of the other chief ore bodies in the mine is also shown, slightly
generalized. Pl. XLIII, A, is a section of the northern end of the mine,
taken through the Iowa shaft and the Iowa incline. The ore along this
plane of section occurs, as usual, at the intersection of slight faults with the.
Silver fault. The upper shoot shown is that which lies at the point where
the two main Bushwhacker shoots come together. The lower shoots are
developed at the intersection of the Regent system of slight faults with
the Silver fault, and show the ore as occurring im the dolomite and along
the Silver fault at these intersections. The fractures of the Regent system
are cut obliquely by the plane of this section.

MINERAL FARM MINE.

The Mineral Farm mine shows essentially the same peculiarities as its
neighbors. Ore occurs in the immediate vicinity of the Silver fault, some-
times in the dolomite and sometimes in the breccia above. It follows
certain nearly continuous north-south shoots, which probably mark some
slight displacement or fracture. The ore is very high in baryta, the average
being nearly 50 per cent. There is very little lead. Much of the barite
is entirely barren of values, and from its nature seems to be a filling of
preexisting fissures or cavities. These veins are often 2 or 3 to 10 or 12

feet thick.
ALTA ARGENT MINE.

The Alta Argent mine was the northernmost working mine along the
Cowenhoven tunnel at the time of examination. The tunnel runs from the
Mineral Farm into the Alta Argent in Leadville dolomite, with the Silver
fault close by on the west side. It soon encounters a fault which runs
directly across the tunnel, and is probably nearly vertical, having an offset
to the west on the north side of 20 or 30 feet. A short distance farther on
another fault is encountered, having a similar displacement, and between
these are vertical open fractures and watercourses, which increase in number
toward the north. The maximum amount of fracturing is encountered still
farther north, where in a space 30 or 40 feet wide the watercourses are

SMUGGLER MOUNTAIN. IS)

closely set together, so that the tunnel had to be lagged in order to stand.
Just before reaching this highly fractured zone, the uppermost beds of the
Parting Quartzite come into the tunnel. On the other side of this zone,
however, no Parting Quartzite is found, but only hard blue dolomite.
Since this fault has probably, like the others, an offset to the west on the
north side, the dolomite is Silurian; and this is confirmed by a crosscut to
the west on the north side of the fractured zone, which shows the Parting
Quartzite, considerably altered, abutting against the shale on the other side
of the Silver fault. The horizontal shift along this fractured zone, which is
called the Alta fault, may be approximated at 100 feet. From this point
north for some distance the Silver fault separates the Weber shale from the
Silurian dolomite.

The ore in the Alta Argent appears to lie between two of the north-
west-southeast faults which have been described as existing in the southern
part of the mine, and is found both in the dolomite and in the shale. It
contains considerable barite, and crisscross spar is frequent. There is also
much native silver. .

SMUGGLER MOUNTAIN MINING. MAP.

The Smuggler Mountain map presents no areas of complication except
along a narrow zone in the vicinity of the Silver fault. The Della and the
Smuggler faults outcrop only in the northeastern corner of the district, but
their dip is very slightly steeper than the slope of the hill, and they are
found, therefore, in all the workings from the Regent to the Mollie Gibson.
In the southern part of the district the Clark fault causes complications.
According to the explanation which has already been presented, the Clark
fault faults the Della 5S. system so that the Della and Smuggler faults are
upthrust on the east side. Thus the Gibson fault, which belongs to the
Della system, is brought close to the surface and locally outcrops, but as
its dip is still slightly steeper than the slope of the hill this outcrop is
extremely limited, being cut off both to the north and to the south by the
Clark fault. The Gibson fault, on the other hand, cuts off the Silver fault,
as do all the faults of this system. For some distance north of the Smug-
gler mine the Silver fault does not appear in outcrop, being cut off by the
Clark fault. As the throw of the Clark fault diminishes, the line of junc-
tion with the Silver fault comes nearer the surface, until it crops, as shown

198 GEOLOGY OF ASPEN MINING DISTRICT, COLORADO.

in Section C, Atlas Sheet XXVIII. From this point north the two faults
crop very close together and parallel, and probably unite soon after leaving
the area of the map. The displacement of the porphyry sheet in the center
of the area is due to the action of the Silver fault and not to any subse-
quent movement. The geological features shown in the cross sections have
been already described and do not require further mention. In studying
the longitudinal section E, Atlas Sheet XXIX, however, it must be
remembered that the various faults and other formation planes are cut by
the section at varying angles, and so give varying lines of intersection,
which are apt to mislead unless properly understood. In the center of the
section the Clark fault is shown cuttmg the Della and Smuggler faults and
upthrusting these faults, with the inclosing strata, to the southeast. It
should also be noticed in this section how the Contact fault comes in at the
extreme southern end, but soon runs into the Silver fault and disappears,
leaving only a thin wedge of blue limestone between the dolomite and the
shale.
RESUME OF SMUGGLER MOUNTAIN GEOLOGY.

The structure of Smuggler Mountain is marked by uniform steep tilt-
ing, which has been disturbed at successive periods by faults. The first of
these disturbing movements is represented by the Silver fault, which has
cut out the blue limestone and part of the Leadville dolomite throughout
the whole of the mountain, and also the thick sheet of quartz-porphyry
which is intercalated in the Weber shales. Subsequent to the formation of
this fault there arose a system of east-west breaks, of which the Della and
the Alta faults are representatives. The Della fault has an east-west trend
and a comparatively flat southerly dip, while the Alta fault, which also has
an east-west trend, is nearly vertical. So far as can be judged from the
phenomenon of ore deposition, however, these two faults were practically
contemporaneous in origin. Subsequent to the formation of these faults
there again took place a slipping along the general plane of the Silver fault,
which locally deviated from this plane and so constituted an independent
fault. his is called the Clark fault. The various stages in the deforma-
tion of the rocks on Smuggler Mountain are shown in the accompanying
diagrams (fig. 8), A representing the original condition of the beds after the
intrusion of the porphyry and the tiltg away from the the granite axis,
B representing the beds after the movement of the Silver fault, C showing

‘OGVNAT

ABZAYNS 191901039 *s "nN
IAXX “Id IxXX HdVYSONOW

LENADO. 199

the effects of the Della fault, and D the structure resulting from the Clark
fault, which is that existing at the present day. In determining the relative
ages of these different fault systems the fact of the late ones cutting and
faulting the earlier ones, as shown in the figures, is important. Valuable
information is also obtained from the ore deposition, for the period of miner-
alization seems to have been restricted as compared with that of faulting.
Thus the Silver fault was mainly premineral; the Della and the Alta faults
began to form previous to the ore deposition, but continued after it, and the

if} rs i!
i Wii,

Fia. 8.—Successive stages of faulting in Smuggler and Mollie Gibson mines.

Clark fault is almost entirely postmineral, only secondary deposits of ore
having formed along it.

LENADO.

Northward from the Alta Argent mine in Smuggler Mountain no
ore has been found for several miles. Following along the metalliferous
zone, the first productive locality is in Lenado Canyon, where the
mining village of Lenado is situated. Pl. X XVII gives a general view of
this village, now in a rather dilapidated condition. This view is taken,

200 GEOLOGY OF ASPEN MINING DISTRICT, COLORADO.

looking across Lenado Canyon and up Silver Creek, from the hillside west
of the creek, just above the Leadville mine.

ASPEN CONTACT MINE.

The Aspen Contact mine has its workings along the Lenado fault,
which traverses the Lenado district from northeast to southwest. (See
Pl. XXVIII.) The tunnel starts in Weber shales on the northwest side
of the fault and runs southeast to meet it. On approaching the fault the
shale becomes soft and decomposed, and the dip varies constantly from
horizontal to vertical and pitches steeply in both directions, showing that
the shale is crumpled into a series of complicated folds. From the
shale the tunnel cuts into brown dolomite, which is probably Silurian.
The contact of shale and dolomite is nearly vertical, and constitutes one
of the parallel sips which make up the Lenado fault. The dolomite near
the fault is much broken up, containing fragments of ore and of limestone.
Near the fault workings run through the dolomite on a vein of rich blende,
which was in places very high in silver and in lead. On the edges of the
vein the sulphide has altered to zine carbonate, with some lead carbonate.
This vein was traced continuously for about 200 feet, trending with the
shale-dolomite contact and only a short distance from it. In places its
walls are smooth and straight, but they are slickensided, and are probably
slip walls. In other places the vein is broken and interrupted by breccias
and by faulted-in blocks of dolomite. It is probable that this ore was not
formed in place, but existed prior to the faulting. A short distance south-
east of the fault between the shale and the dolomite comes another fault,
which separates the dolomite from the Cambrian quartzite. The two
faults have the same general movement, but the displacement of the fault
between the shale and the dolomite is greater. The zone between the
dolomite and the quartzite, however, is greatly brecciated for many feet,
and the quartzite is softened and decomposed. The ground-up rock is
called “tale” by the miners, and is distinguished as ‘‘gray tale,” “brown
talc,” or “blue tale,” according as the quartzitic, dolomitic, or shaly
material predominates. In this ‘‘tale” the richest ore in the mine has
been found, lying directly under the quartzite, for here the fault dips
steeply to the southeast, so that quartzite forms the hanging wall. The
main ore body extended from the tunnel up to about 40 feet from the

‘OGYN37 ‘ANIN LOVLNOOD Nadsv

—eE
WAXX “Id 1XXX HdVHSONOW ASAYNS 1V9IDOIO3RS “Ss "nN

LENADO. 201

surface, making about 200 feet. In places the ore was 40 feet thick, and
laterally it ran along under the fault for as much as 300 feet. This ore
contained much lead, a moderate amount of silver, and not much zine.

The ore in the Aspen Contact mine, therefore, occurs in two chief
zones, which are also fault zones; one at the contact of dolomite and
shale, and one at the contact of dolomite and quartzite. Along both of
these zones the ore is excessively broken up, and some of the very richest
is in the finely ground fault material. Thus the ore does not seem to have
formed in place, but to have existed previous to the fault; and as the
faulting has been very extensive, the ore may have been carried a consid-
erable distance. Pl. XLIII, B, is a cross section of the Aspen Contact
mine, showing the occurrence of the ore and the various geological
features which have been described.

The average ore is very high in zinc, generally containing much lead
and a comparatively large amount of silver. Barite, on the other hand,
which is such a common gangue mineral in other ores of the district, is
very rare.

LEADVILLE MINE.

The geological features exposed in the Leadville mine are substan-
tially the same as those in the Aspen Contact. The two branches of the
main Lenado fault are cut in this mine, the first being between the shale
and the dolomite, and the second between the dolomite and the quartzite. In
the northwestern part of the mine, however, the steeply dipping Cambrian
quartzite on the south side of the fault is overlain conformably by the
Silurian beds, so that west of this point there is Silurian dolomite on both
sides of this fault, and it becomes hard to trace.

In the Leadville mine there have been two chief ore bodies developed,
both being, as in the Aspen Contact mine, in fault zones. One body was
continuous with the main body of the Aspen Contact, lying between
quartzite and dolomite in the more southern fault; and, as in the Aspen
Contact, the ore was a lead and zine sulphide, with some carbonate. The
other main ore body lay in dolomite not far from its contact with the shale,
and had a maximum width of 8 feet, from which it pinched in places down
to a mere seam. In appearance this ore is like a soft mud, being blue-
black, or more generally brownish blue, in color. As the so-called “tale”
of the miners is often a triturated limestone, so this soft mud ore seems to

202 GEOLOGY OF ASPEN MINING DISTRICT, COLORADO.

be derived from the trituration of sulphides. When richest it is nearly
black, and is probably, in part at least, sulphide of silver with galena.
The brown color is given by an admixture of yellow clay, which occurs in
bunches and seams, and is of later origin. An assay of this yellow mud
showed only 25 ounces of silver to the ton, while one of the blue-black
material associated with it assayed 3,000 ounces. On both sides of the
ore is brown altered limestone, which in places is brecciated and has frag-
ments of soft black ore embedded in it. This ore, then, presents the char-
acteristics of having been dragged into its present position.

BIMETALLIC TUNNEL.

The Bimetallic tunnel starts near the base of the Maroon sandstones
and runs southeast across the Weber formation to the Lenado fault, which
it crosses into the Leadville dolomite; farther on it goes through the Part-
ing Quartzite into the Silurian dolomite. The information furnished by
this tunnel is valuable chiefly as showing: that there has at least been no
general mineralization along the Lenado fault. The fault has been thor-
oughly explored in drifts from this tunnel and in raises and crosscuts, but
was found to be absolutely barren, offering not even a trace of the precious
metals in most places. It is well marked by a breccia of shale and
dolomite.

TILLY SHAFT.

The Tilly shaft is situated in the gulch east of Silver Creek, which
runs southwestward into Lenado Creek near the village. This shaft cuts
the Silver fault, which here, as on Smuggler Mountain, separates the
Weber shale from the Leadville dolomite. In this shaft some ore was
encountered in hard blue dolomite. This contained considerable galena,
but ran only about 5 or 6 ounces in silver. No ore was shipped from this
mine, but the fact of its occurrence in this vicinity on the Silver fault is
highly significant, especially as it seems to have formed in place. PI.
XXIX is a view of the gulch up which the Silver fault runs, with the
dump of the Tilly shaft near the center.

RESUME OF LENADO GEOLOGY.
In this district the beds have a generally westerly dip, which varies

considerably in different localities. The chief displacement subsequent to
the folding is that of the Lenado fault, which runs northeast and southwest,

PL. XXIX

MONOGRAPH XxXxX1

U. S. GEOLOGICAL SURVEY

SCORN aa ama
<a

ee

GULCH ALONG SILVER FAULT, LENADO

QUEENS GULCH. 203

is well determined by underground workings and by outcrops, and has a
heavy downthrow on the northwest side. As is usually the case in faults,
it does not necessarily consist of a single plane of movement, but of sev-
eral, which include between them narrow slices of rock that distribute
the total displacement. In the Aspen Contact and Leadville mines, for
example, two of these interdependent faults are well exposed.

A large part of the fault is entirely barren of ore, the explorations in
the Bimetallic tunnel being especially significant. In the Aspen Contact
and Leadville mines, however, large quantities of rich ore have been taken
out. Every characteristic of this ore shows that it was not formed in place,
but was dragged into its present position by the faulting. The movement
along the fault was nearly vertical, so that the rocks on the southeast side
have probably dragged up this ore from some point almost directly below.
Where this point is it is not possible to prove, but the fact that ore occurs
in place along the Silver fault in the Tilly shaft is significant.

Section A of the 300-foot map (Atlas Sheet XXX) shows the probable
depth of the Silver fault between the shales and the Leadville dolomite on
the northwest side of the Lenado fault, in the region of the Aspen Contact
mine, and it is very probable that the ore may have actually been dragged
up aloug the Lenado fault from this lower horizon. The Silver fault, which
is displaced by the Lenado fault, is shown only on the northeast corner of
the map as it runs down into Woody Creek. Its continuation on the
southeast side of the Lenado fault is not shown, since it runs: into this
fault a short distance beyond the southern edge of the mapped area.

Section A is taken through the Aspen Contact tunnel; Section B
through the Bimetallic tunnel. The geology shown in both these sections
has already been described.

QUEENS GULCH.

On the west side of the Castle Creek fault, and southwest of Tourte-
lotte Park, there is considerable mineralization in a strip beginning in Ophir
Gulch and extending southward. In many places small quantities of rich
ore have been discovered, and it is possible that in the future the district
may become a heavy producer. One of the best opportunities for studying
this mineralization is in Queens Gulch. Pl. XXX is a view of Queens
Gulch taken from the west side of Castle Creek and looking across the

204 GEOLOGY OF ASPEN MINING DISTRICT, COLORADO.

intervening valley. The Castle Creek fault crosses the gulch near the
point where it appears to branch, not far from the center of the plate, and
here is situated the Dubuque tunnel. The ore in this district is found along
the Castle Creek and its dependent faults.

Dubuque tunne—The Dubuque tunnel (see Pl. XLIII, (@) starts in the
yellow and brown sandstones of the Maroon formation on the west side of
the Castle Creek fault, and runs east through the gray siliceous limestone
which forms the base of the Maroon. At some distance in, it enters Weber
shales, much broken up, which soon change to a veritable breccia, in which
shale and porphyry are commingled. On the east side of this comes solid
porphyry, which is considerably softened and decomposed, and beyond
this again is shale and porphyry-breccia nearly to the Castle Creek fault.
On the west side of the fault the rock is hard black chert, evidently a
silicified limestone. On passing through this granite is reached. The dip
of the Maroon beds near the mouth of the tunnel is about 60 degrees
to the northeast. The sequence of beds shown from west to east is the
normal succession, consisting, after the sandstone and gray limestone at
the base of the Maroon, of shale, then porphyry, then shale again, and
finally the silicified limestone next the fault, which may be the blue Lead-
ville limestone. The thicknesses of these formations, however, are much
less than normal, and the nature of the contacts show that they are fault
‘contacts, so that there is probably some displacement. These faults are
nearly vertical, being mainly parallel with the Castle Creek fault, and so
do not diverge much from the bedding, which is also very steep. On both
sides of the porphyry, to the east and to the west, are especially well-
marked zones of crushing. That to the east has been called the Dubuque
fault, while that to the west, which is also found in the Little Annie mine,
is called the Annie fault. There are, however, many smaller slips parallel
to these.

The chief ore in the Dubuque tunnel is the zone of silicified limestone
which lies next the granite. This silicified rock contains pockets of
copper pyrite and galena, which do not appear to have great continuity.
There is often a good deal of barite. At the contact of Weber and Maroon
there is another mineralized zone which dips steeply to the east with the
formations, but it does not appear to be very rich. There is a similar zone
farther west, in the Maroon limestones.

WASYO 3ILSVO JO GIS 1SSM WOYS ‘'HOINS SNASINO

XXX “Id [XXX HdvHSONOW ASAYNS 1V9I9N01039 °S “nH

my

LITTLE ANNIE MINE. 205

Centennial tunnel— The Centennial tunnel started in porphyry above the
Dubuque and crossed eastward through the Castle Creek fault into the
Cambrian quartzite. At the end of the tunnel a raise was made up to the
Silurian dolomite.

Gray Carbonate tunnel —On the hill above the Centennial and Dubuque tun-
nels the Gray Carbonate tunnel runs into Silurian dolomite, and there
exposes a small amount of ore, some of which has been shipped.

Yopsie tunnel— The Yopsie tunnel starts on the crest between Queens and
Yopsie gulches. It runs in gray grits and in the pure gray limestone
belonging to the base of the Maroon formation for a considerable distance,
following a perfectly distinct vertical vein. This vein is of barite, often
copper stained, and in the rock on both sides there are many parallel
fractures. Both vein and fractures trend northwest, parallel to the Castle
Creek fault. The heavy spar, however, is practically barren of valuable
minerals, and thus affords another proof that the barite and the metallic
sulphides were not necessarily deposited at the same time.

LITTLE ANNIE MINE.

The Little Annie mine is located on the Castle Creek fault, a short
distance from the southern end of the area mapped. Its workings are in
porphyry and shale on the west side of the fault, and it also crosses the
fault into the Silurian dolomite. West of the main fault a series of just
such dependent breaks as were noticed in the Dubuque tunnel exist and
are shown in the cross section on Pl. XLIII, D. The fault between
porphyry and shale has been called throughout the district the Annie.
The shales on the west side of the porphyry are generally disturbed,
especially close to the fault, being bent and squeezed between the minor
slips, but farther away their attitude becomes more uniform.

In the lower levels of this mine the ore is a sulphide of lead, zinc, and
silver, with a considerable amount of barite. The galena is sometimes
beautifully crystallized, and the silver is often found native. The ore
occurs chiefly in the immediate vicinity of the Castle Creek fault, but on
the west side of it, being developed along many of the slight faults and
fractures in the shale and porphyry. Some was also found in the dolomite
on the east side, but these deposits were apparently not so extensive. In
the upper levels the ore is oxidized.

CH AE ip Live

CHEMICAL GEOLOGY.

In this chapter the various chemical changes which have occurred in
the rocks of the Aspen district since their -consolidation will be discussed.
Nearly all of these changes have come about since the beginning of deforma-
tion in the beds, and they have apparently an intimate connection with the
physical changes, such as faulting and folding, which have been described
in Chapter II. From an economic point of view the most important of the
chemical changes was that resulting in the deposition of the precious metals,
but certain other changes are much more widespread, and thus are more
important geologically. These latter changes consist in the alteration of
limestone to dolomite by a process of replacement, and, by other processes
of replacement, in the alteration of limestone and dolomite, but chiefly the
former, to quartz and tc iror. These processes of dolomization, silicifica-
tion, and ferration are all intimately connected with the deposition of the
precious metals, but are more widespread, as might be expected from the
great amount of magnesia, silica, and iron throughout the crust of the earth
as compared with the smaller amount of the rarer metals. All these chem-
ical changes have occurred mainly at the same period and apparently
through the same agents, but the process of ore deposition requires more
peculiar and unusual conditions than do the others, and therefore probably
acted during a shorter period than they.

DOLOMIZATION.

As seen under the microscope, all the dolomites of Aspen have essen-
tially the same structure, and this structure is clearly not that of a sedimen-
tary deposit. The dolomite crystals which make up the larger part of the
rock are all apparently crystals of the double carbonate and occur mostly
in nearly perfect interlocking rhombohedra, and associated with these are

invariably small grains of quartz whose character and shape show that they
206

DOLOMIZATION, 207

are chemical segregations and not detrital. This structure is sufficient evi-
dence that the dolomite is not a simple sediment, such as most limestones
are, but has crystallized through the influence of solutions. There are only
two possible methods, broadly speaking, by which such solutions could
have acted to bring about this result. First, the dolomite crystals may
have been precipitated originally as such from sea water highly charged
with salts of magnesium and calcium; and, second, the process may have
been metasomatic, the solutions having acted subsequently to the deposition
of the rock and thus produced the crystalline dolomite which now exists.
The idea that dolomites are formed by direct chemical precipitation by
sea water has been somewhat advocated,’ but is not largely held at the
present day. Bischof” has shown that when a solution containing carbon-
ates of lime and of magnesia becomes so highly saturated that precipitation
begins, the lime carbonate will nearly all precipitate before the deposition
of magnesia carbonate begins, owing to the difference in solubility between
the two salts, and that there would thus result a lower layer of nearly pure
carbonate of lime and an upper layer of nearly pure carbonate of magnesia.
From the mingling of the two layers some small amount of dolomite might
be formed, but no thick and continuous bed could thus be precipitated.
In addition to this theoretical evidence against the direct chemical precipi-
tation of dolomite is the practical evidence that no such precipitation is now
known to be going on.

The second possible way for the formation of dolomite, namely, by
metasomatic interchange between the materials of an already deposited rock
and other materials brought by permeating solutions, is the one which has
seemed most probable to recent writers. This secondary origin is in many
cases actually proved, and the rock from which dolomite is formed by
alteration is always limestone. Dana® has described the interesting case of
the elevated coral island of Metia, north of Tahiti. On analysis the white
compact coral limestone of this island was found to be nearly a true dolo-
mite. From the general character of this rock it appeared to have been
deposited in the shallowimg lagoon of the small coral island, and to have
been derived from ar abrasion of the coral. Deposits of mud are frequent

17. Sterry Hunt, Chemical and Geological Essays, p. 92.
* Chemical and Physical Geology, English translation, London, 1859, Vol. III, p. 170.
’ Manual of Geology, 4th edition, New York and London, 1895, p. 133.

208 GEOLOGY OF ASPEN MINING DISTRICT, COLORADO.

under such circumstances. The ordinary reef-forming corals, however,
contain. very little magnesia, and therefore the formation of this dolomite
seems to be connected with the peculiarities of the lagoon in which it is
deposited. Such a landlocked lagoon is a very favorable place for the
evaporation of water and the concentration of the salts which it contains,
and these concentrated salts of magnesia are supposed to have acted upon
the coral so as to form dolomite. In the same way dolomite may be formed
over wide areas where a previously deposited limestone is covered by the
shallow waters of a landlocked and evaporating sea.

On a more local scale the alteration of limestone to dolomite has been
observed by various writers. Such alteration along joints in the Carbonif-
erous and Devonian limestones near Cork, in Ireland, has been described
by Professor Harkness.!

The nature of the exact chemical process in this alteration has not been
definitely agreed upon, the chloride, the carbonate, and the sulphate being
variously considered as the possible magnesian salt which has reacted upon
the carbonate of lime. More recent investigations, however, seem to show
that any or all of these salts may have this effect. The general chemical
reason for the formation of dolomite seems to be the tendency of the car-
bonates of magnesia and lime to unite to form a double carbonate.

ASPEN DOLOMITES.

In Aspen there is evidence of two distinct periods at which dolomite
was formed. The main body of dolomite, consisting of the whole of the
Silurian beds and the lower part of the Leadville formation, existed previous
to the deformation of the rocks by faulting and folding, since the dolomite
beds are faulted in the same proportion as the rest of the strata. Along
these main faults and fractures, however, the blue limestone at the top of
the Leadville formation has been altered irregularly for varying distances
on each side of the fractures into dolomite, microscopically identical with
that formed at the earlier period. This later dolomite forms wherever -the
rock has been open to circulating waters. Thus it follows faults and frac-
tures which cut directly across stratification, and also slip planes and porous
zones conforming with the stratification. In the latter case the dolomite
forms apparent beds in the blue limestone, as is especially well seen in the

1Quart. Jour. Geol. Soc. London, Vol. XV, 1859, p. 101.

DOLOMIZATION. 209

neighborhood of the Contact fault as it outcrops on Aspen Mountain, where,
in the blue limestone cliffs above the fault, dolomite has formed in zones
parallel to the bedding along slips of the same nature as the Contact fault
itself.

The origin of the dolomite belonging to the earlier period has been
discussed in the first chapter. It is there shown that both the Silurian dolo-
mite and that constituting the base of the Leadville formation are contin-
uous over wide areas, with an almost uniform chemical composition. The
structure of the rock, as observed, is indicative of the fact that the dolomi-
zation came about through the action of solutions, but the great extent of
these beds shows that these solutions could not have been local or depend-
ent upon any local cause. The agents which produced the alteration of
the original calcareous sediments to dolomite must have operated equally
over the whole area in which we now find these beds dolomized. Such
widespread solutions would be afforded by the presence of a great lake or
inland sea in which the usual amount of magnesia in sea water was concen-
trated by evaporation.

The origin of the dolomite belonging to the later period, however,
was evidently distinct from that which has been suggested for the extensive
beds. As before, the microscopic structure shows that the rock was
produced by the action of solutions which exchanged carbonate of mag-
nesia for part of the original carbonate of lime, but in this case the
solutions have been comparatively scanty and short-lived, for they have
not affected the whole rock, but only zones along watercourses. In the
extensive beds of dolomite belonging to the earlier period the change is
practically uniform and complete. This has been proved in the case of the
Leadville dolomite by a number of analyses, such as are given in Chapter
I, p. 25. These analyses show a comparative uniformity throughout the
rock, and show that the whole formation is nearly a true dolomite, having
a slight excess of lime. This dolomite, as also that which originated later,
always contains some iron and silica, which were introduced probably at
the same time as the magnesia. On the other hand, analyses of the locally
dolomized zones which traverse the blue limestone show all transitions
from a pure dolomite into a pure limestone, the dolomization growing less
as the distance from the fracture along which the dolomizing solutions

apparently flowed increases. To test this fact, analyses were made of rock
MON XXXI——14

210 GEOLOGY OF ASPEN MINING DISTRICT, COLORADO.

from a locality on the top of Aspen Mountain, on the divide between Keno
Gulch and the broad depression on the north side of the mountain. Across
this divide the Saddle Rock fault runs, having blue limestone on the east
side and granite on the west. Four samples were selected trom this vicinity
for analysis, being taken out of tunnels which cross the fault and penetrate
the blue limestone below. Nos. 1 and 2 are of samples taken along the
main fault zone. Nos. 3 and 4 are from different points about 100 feet
east of the fault, where the limestone was only partially altered.

Analyses of rock from dolomized zones of Aspen Mountaan.

No. SiOz. Cao. MgO. Fe.0,. FeO. |
1 1.02 33.74 16.76 2.10 .06 |
2 13.68 35.98 8.25 1.88 64 |
3 31.12 37.28 54 .36 .19 |
4 7.78 38.85 9.97 .88 22

Study of these analyses shows that they represent four distinct transi-
tional stages in the passage of limestone to dolomite, and that the dolomi-
zation is also accompanied by a corresponding ferration, while the amount
of silica varies. Thus No. 3 is nearly pure siliceous limestone, while No. 1
is not far from the composition of the average dolomite.

This local dolomization almost invariably accompanies the ore. Even
when the latter is in blue limestone there is usually a sort of envelope of
dolomite around it, which in turn is surrounded by the limestone. In rare
cases, when the ore is directly inclosed in blue limestone without such an
envelope, its analysis shows the presence of magnesia, while the limestone
is almost entirely pure.

The microscope affords means to trace the alteration of the blue
foraminiferal limestone into dolomite in its various stages. In this process
the coarse calcite becomes broken up into smaller crystals, which assume
the rhombohedral form and the yellowish tinge distinctive of dolomite.
The characteristic structure of the blue limestone persists for a time during
this alteration, but becomes fainter as the crystallization proceeds. The
coarsely crystalline calcite and the cryptocrystalline variety which form
the two distinct phases of the blue limestone both become finely crystallme
dolomite, but the texture of the two varieties continues different for some

DOLOMIZATION. ale

time. The dolomite often incloses small grains of pyrite, or is stained by
disseminated limonite.

A peculiar structural feature which evidences the secondary origin of
the dolomite, both that in the extensive beds and that of the later period, is
the prevalence of many closely set jomts, which characterize the rock in its
fresh condition. Furthermore, most of the dolomite belonging to the later
period seems to have formed in the vicinity of watercourses, and since its
formation it has been peculiarly liable to oxidation from surface waters,
which have flowed continually along these courses, even up to the present
time. The result of this has been the alteration of a certain amount of
carbonate in the rock, with possibly the removal of some carbonate in
solution. This has brought about a marked reduction in bulk, so that this
dolomite is always very close jointed, or, as called by the miners, “short.”
A part of the carbonate in the fresh dolomite is iron carbonate, and on
oxidation the yellow limonite resulting from this stains the rock, thus
giving rise to the name “brown lime,” by which, also, the dolomite is

known at Aspen.
AGENTS OF DOLOMIZATION.

From the distribution of the dolomite belonging to the later epoch
along the fault zones and other channels where water has for a long time
circulated freely, it is evident that waters have been the agents of change.
It may now be well to inquire what was the nature of this circulating
water. Harkness, who has been quoted as describing similar dolomiza-
tion along joints in limestone near Cork, in Ireland, attributes the change
to sea water which penetrated downward along these channels. Bischof?
mentions dolomite as accompanying ore deposits in limestone in France,
and Adolph Schmidt” also finds that in the large lead and zine deposits of
Missouri the limestone has been dolomized along fissures and in the neigh-
borhood of the ores. Both these latter writers refer the change to the
action of solutions of magnesium bicarbonate.

Leaving out of the question the chemical changes which the waters
that circulated along these faults and fractures have wrought in the rock,
their more ordinary effects are strikingly like those of the water which still
circulates through these channels at the present day. From the Castle

Chemical and Physical Geology, English translation, London, 1859, p. 179.
* Trans. St. Louis Academy, 1875.

212 GEOLOGY OF ASPEN MINING DISTRICT, COLORADO.

Creek fault in Queens Gulch a copious spring, which indeed is really the
outbreak of an underground stream, rises between the Weber shales on the
one side and the quartzite and dolomite on the other. In the Aspen mine
the water which circulates along the Aspen and other faults comes down
into the main Durant tunnel in a veritable waterfall, the roar of which can
be heard a long distance away. These waters, which evidently come
mainly from the surface, do not appear to exercise any dolomizing
influence on the limestone which they traverse, and the phenomena of
dolomization, silicification, and ore deposition along the faults show that
the waters which produced them were in some way more potent than the
cold waters which now circulate underground.

DOLOMIZATION AT GLENWOOD SPRINGS.

In this connection the waters at Glenwood Springs, which is 40 miles
from Aspen, at the junction of the Roaring Fork and the Grand River, are
highly interesting. The formations at the junction of the Roaring Fork
and the Grand are the same as those exposed at Aspen. A short distance
above the town of Glenwood Springs is the Archean granite, over which
comes Cambrian quartzite, and then dolomite. The section was not care-
fully measured, so that an accurate description of the deformation which it
has evidently experienced can not be given. The Parting Quartzite, how-
ever, was not found, and it is probably obscured by faulting. At the main
springs, close to the town, the rock is pure blue limestone, like that at
Aspen, and undoubtedly belongs to the same formation. The faulting
which has been referred to is evidenced by many parallel vertical fissures,
which are well exposed on the canyon walls. These become prominent a
short distance down the river from the point where the granite outcrops;
and are progressively more pronounced farther down. In the blue lime-
stone on the walls of the canyon are great, vertical, irregular, open cham-
bers, whose rounded walls show that they have been watercourses. In the
immediate vicinity of the principal spring the disturbance has developed
into a sheeting so prominent as to obscure the stratification. Along the
fractures, for half a mile above the main spring, small springs of hot water,
giving off sulphurous fumes, gush out at intervals. The one noted farthest
up the river is in Cambrian quartzite. The open watercourses in the
higher rocks have evidently been occupied by springs similar to these at a

DOLOMIZATION. 213

very recent period. The existing springs follow by preference the vertical
fractures, along which they appear originally to rise, but also follow porous
zones in the bedding. At the main spring, which is called the Yampa, the
water apparently rises in the strongly fractured zone which has been men-
tioned. According to the prospectus of the Colorado Hotel, which is built
near this spring, the Yampa spring has a flow of 2,000 gallons per minute,
and has a temperature of 120° F. The following analysis of the waters of
this spring by Dr. Charles F. Chandler, of New York, is taken from this
prospectus:

Analysis of water from Yampa Spring, Glenwood Springs, Colorado.

[In one United States gallon (281 inches). ]

Grains.

Chloride of sodium_______.-___..---___---| 1,089. 8307
Chloride of magnesium_...___._.._-_-___- 13. 0994
iBromidejorsoditmmipes ss oes eae eee 0. 5635
Nodidexofysoditiamee eens Trace.
Mivoridelofscal cium pss === Trace.
Sulphate of potassium. ____-__----------.- 24. 0484
Sulphatetofelim ees ese reee sane aee 92. 3861
Bicarbonatelonlithian=---42222-4-- 5-2 0. 2209
Bicarbonate of magnesia ____---___._____- 13. 5532
Bicarbonate of lime ___________.___._.___. 24. 3727
Bicarbonate of iron__.__.__-----_---__-_.- Trace.
Bicarbonate of soda._ ___________-.-.___- Trace.
Phosphate of soda___ -__--__-_., ---____._- Trace.
PNlkpbadubayre ees Se ees a ae eee aoe Trace.
Sil C alee pester et eee) eee Re I ot 1.9712
Organicematterjassesee nee eee eee Trace.

Total -____ J egseee ese H ee eee eee 1, 250. 0411

Besides the salts mentioned in the analysis, the water gives off various
gases, among which sulphureted hydrogen and carbon dioxide are par-
ticularly noticeable. At the time of examination an artificial cave was
being constructed along one of the small feeders to the main spring for the
purpose of furnishing Turkish baths. When visited, the temperature in
this cave with entrance open was 110°. With the entrance closed it is said
to be 130° or 182°. In the bottom of this artificial cave hot sulphur water

214 GEOLOGY OF ASPEN MINING DISTRICT, COLORADO.

bubbles up through fractures in the limestone. Most of these fractures
are yellow, and apparently somewhat altered, while the rock a short distance
away is perfectly blue and fresh. Four samples were selected for analysis,
and the results are given below. No. 1 is the analysis of a specimen taken
several feet from any fissure, which apparently had not been affected by
circulating water. Nos. 2 and 3 were from the walls of different fissures
along which water had flowed previous to the opening of the cave. No. 4
consisted of broken fragments lying in the bottom of a cavity formed by
the rising hot water.

Analyses of rock from a cave near the Yampa Spring, Glenwood Springs, Colorado.

No. SiOs. CaO. MgO. Fe,03. FeO.
il . 06 55. 81 Trace. None. None.
2 .28 55. 49 24 0.9
3 222 55.17 21 Trace.

4 21. 45 40. 64 73 .97 .23

These analyses show a progressive change from the first, through the
second and third, to the fourth, consisting in an abstraction of part of
the carbonate of lime and its replacement by silica, carbonate of magnesia,
and iron. This change is, then, a partial silicification, dolomization, and
ferration now actually going on in the limestone at Glenwood Springs
under the influence of ascending hot waters.

A number of other analyses were made from samples selected from
this locality, which all lead to ‘the same conclusion. In the Cloud Cave,
which is a cavern in limestone some distance away from the springs, one
sample was taken of the blue limestone forming its walls, and another of
the limestone at the surface, a short distance away from the cave, but
on the same horizon. No. 1 is the analysis of the sample from the cave,
and No. 2 of the specimen taken from the outside.

Analyses of limestone from and near the Cloud Cave, Glenwood Springs, Colorado.

No. Si0b. CaO. Mego. FeO. FeO. |

1 ~22 55. 45 24 . 10 . 10
2 .11 | 55.68 Trace. .03 07

DOLOMIZATION. Palsy

The change shown by these analyses is an increase in silica,
magnesia, and iron in the limestone which forms the walls of the cave,
and the inference is that this change has been brought about by the
waters which have formed the cave. A number of analyses were made
in other places, especially along fractures in the blue limestone on the
walls of the canyon, where hot springs had evidently recently circulated.
These all led to the same result as above, and only two more analyses will
be cited. Of these, the first was taken from a watercourse in the blue
limestone where the rock was close jointed and had the appearance of the
Leadville dolomite at Aspen, while the second was taken 10 feet away
from the first, in hard and unaltered rock.

Analyses of close-jointed and of hard and unaltered rock from near Glenwood
Springs, Colorado.

No. SiO». CaO. Mego. Fe.03. FeO. |
1 1.96 32.14 18.72 . 03 5833)
2 2.27 53. 79 - 46 .14 |

The change in this case is very striking, since the first specimen is
nearly a true dolomite, while the second is nearly a pure limestone.

On inspecting the analysis of the water of these hot springs it is seen
how capable they are of producing the effects of dolomization, silicification,
and to a less extent of ferration. A noteworthy feature is the presence of
a large amount of magnesia, which is supposed by Dr. Chandler to occur
as chloride and as carbonate in nearly equal amounts. It is interesting to
note, also, that the lime is precipitated mostly in the condition of sulphate,
although there is also a great deal of carbonate. Both the chloride and the
carbonate of magnesium are capable of replacing carbonate of lime to form
dolomite, as has been shown by different chemists, and it is very likely that
both act together here.

The phenomena along faults and fractures at Aspen are exactly the
same as those along similar channels at Glenwood Springs, and the infer-
ence is that both were accomplished by the same agents. In Corundum
Gulch, 14 miles from Aspen up Castle Creek, and thus in a nearly opposite
direction from Glenwood Springs, there are said to be hot sulphur springs.
In Aspen there are no hot springs, but in the Mollie Gibson mine there are

216 GEOLOGY OF ASPEN MINING DISTRICT, COLORADO.

cold springs which carry a large amount of sulphureted hydrogen and
which are apparently ascending. We may conclude, then, that the later
period of dolomization at Aspen was probably due to the effects of hot
springs rising along faults and fractures. These altered the limestone to
dolomite by means of the carbonate and chloride of magnesia which they
they held in solution.

SILICIFICATION.

Among the chemical changes which have taken place in the Aspen
rocks since their formation the deposition of silica has been one of the most
noteworthy. The processes of silicification may be divided into three.
First, the conversion of sandstones to quartzite by filling of the interstitial
spaces; second, the deposition of silica at the same time with carbonate of
magnesia from oceanic or lake waters; third, the deposition of silica along
fault and fracture zones and other watercourses subsequent to the disturb-
ance in the rocks produced by faulting.

As an example of the process first named, the Cambrian quartzite is
prominent. This has been formed from original sandstone by growth of
the detrital grains of which the sandstone was formed, after the manner
of crystals, the silica to supply this development being furnished by waters
which penetrated the porous rock. In the Parting Quartzite series the same
process has gone on, although not always completely. Inthe Dakota sand-
stone there are certain interesting phenomena attending the early stages in
the change of the sandstone to quartzite. This formation is mostly sand-
stone, but contains thin intermittent bands of true quartzite. Often the
quartzite is not even banded, but is in irregular nodules distributed along
‘certain zones. The extension and consolidation of these bands and nodules
would make the whole formation a quartzite similar to the Cambrian.

The second process of silicification is illustrated in the dolomite of the
Silurian and the Lower Carboniferous. These dolomites are always some-
what siliceous, and the microscopic examination reveals the presence of
quartz, which is generally evenly disseminated in small grains of varying
size. On casual examination these grains appear detrital, but when care-
fully observed, instead of being rounded or even regularly angular, they
are seen to be irregular and sinuous, presenting reentrant angles and sudden
bays, such as could not possibly appear in grains which had suffered any

“NIVLNMOW N3dSV LSSM ‘SLINOTOG NI SANV1d LNIOf GNV NOILVOlsILVaLs

Les

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SILICIFICATION. 217

friction. The appearance, moreover, is not like that of detrital quartz, the
grains being perfectly clear and free from any break or crack. These
grains seem to have formed at the same time as the dolomite in which they
are embedded, for one is often entirely inclosed in a single dolomite crystal.
The intimate and invariable association of quartz and dolomite indicates
that the two had a common and contemporaneous origin, and that the
quartz grains resulted, like the dolomite which incloses them, from the
replacement of an original calcareous sediment by silica, this silica being
introduced into the calcareous beds by the same solution which brought
the magnesia and produced dolomization. The theory which has been
advanced in the case of the dolomization is that such solutions were the
waters of a great shallow evaporating sea.

The third process of silicification has had by far the most widespread
effects. This silicification has come about subsequent to the formation of
faults and fracture zones in the rocks, and is localized alone these and
other watercourses. It is therefore distinctly later than the process which
has formed the quartz grains in the extensive dolomite beds, by the same
proof which shows two distinct periods of dolomization, namely, that the
siliceous dolomite of the first period has been traversed and faulted by
the fractures along which the dolomite and silica have subsequently been
deposited, replacing the limestone which lies above the Leadville dolomite.
In the earlier-formed Silurian and Carboniferous dolomites the effects of
this later silicification are seen, although not nearly so prominent as in the
Leadville limestone. In these dolomites there have formed, along fractures
developed at the main period of disturbance, bands and nodules of chert.
Such bands and nodules often follow the stratification, having been formed
along channels parallel to the bedding. In some places there are two sets
of chert bands developed, one following the stratification and another
cutting across it. Such is the case in certain parts of West Aspen Moun-
tain. Pl. XXXI is a view of a cliff of dolomite near the point of the
mountain. The stratification planes of the dolomite dip steeply down
toward the right-hand corner of the picture, while there is a strong vertical
jointing running nearly at right angles to the bedding. In places this joint-
ing becomes so prominent as to obscure the stratification. In this rock
the chert nodules sometimes follow by preference the bedding planes and
sometimes the joint planes. Where the jointing obscures the bedding

218 GEOLOGY OF ASPEN MINING DISTRICT, COLORADO.

and the chert seams follow the fractures the plane of jointing may easily
be mistaken for that of stratification. Under the microscope the process of
formation of this chert is seen to be an introduction of many tiny quartz
erains along slight areas of shearing or fracturing, such areas being
usually marked by microscopic zones of brecciation. When this process
has gone on sufficiently far a chert band results. This chert is made up of
cryptocrystallme or chalcedonie silica, and usually contains many small
bodies of carbonate. Some of the larger bodies are irregular and evidently
residual, while the smaller ones are mostly concentrated into rhombohedra,
which commonly show a zonal structure, indicating growth by successive
additions.

It is m the Leadville blue limestone, however, that the process of
silicification along fracture zones is best shown. The various stages
of change by which a rock consisting almost entirely of carbonate of lime
is transformed mto one made up chiefly of quartz have been carefully
observed under the microscope. Often in a single section a change from
typical foraminiferal limestone to quartz is illustrated in all stages, one part
of the section contaiming only quartz, while another shows no change from
its original condition. Usually, however, the process takes place grad-
ually, and its beginning is signalized by the appearance in the limestone of
many small, irregular quartz grains. Scattered here and there is also
encountered a long and slender crystal of quartz which lies entirely sur-
rounded by the fresh limestone, like a porphyritic crystal in an igneous
rock. As the process of silicification progresses these slender crystals
multiply, so that they finally jom and form a peculiar and characteristic
netlike or retiform structure. This network of imperfect quartz prisms
incloses areas of calcite which are sprinkled with small, irregular quartz
grains, varying in size down to the very smallest dimensions. Many of
these small grains may be cross sections of prisms; they have not,
however, hexagonal outlines, and their forms are irregular and often
angular, recalling the universally distributed tiny quartz grains in the
bedded dolomites. The final result of this silicification is the formation of
a rock made up almost entirely of crystalline quartz grains of various
sizes and shapes, in which the retiform structure is still predominant.
There are also occasional small areas of crystalline calcite, which are
probably residual. Accompanying the silicification is almost invariably a

SILICIFICATION. 219

small amount of ferration, the result of which is seen in the appearance of
oceasional hexagonal crystals of specular iron and, almost invariably,
disseminated limonite. Often limonite occurs i numerous small rhombo-
hedra, which are probably pseudomorphous after siderite, the siderite
having probably formed from alteration of the original calcite.

The first stage of silicification is, as before noted, the appearance of
isolated crystals of quartz in the limestone. A similar phenomenon has
been noticed in most of the other metasomatic changes, such as ferration
and ore deposition in general. The initiation of these processes is signal-
ized by the occurrence of isolated, perfect crystals in unaltered rock, and
these crystals enlarge or multiply until they jom, and thus accomplish a
complete replacement.

The rock that results from the complete silicification of limestone or
dolomite sometimes resembles in the hand specimen a chert, but more
often a fine-grained and altered quartzite. It is generally somewhat
porous, its porosity arising from the leaching out of residual calcite areas,
and it is usually drusy, with coatings of crystalline and chalcedonic
quartz. Its color is usually red or yellow from the iron which it contains.
This rock is one which is often found developed on a large scale in many
mining districts, and has been studied by the writer at Leadville, where
it occurs extensively in connection with the ore deposits. Its structure,
appearance, and general method of origin are practically identical with
the famous jasper of the Lake Superior iron regions.

During a study of the iron-bearing rocks of the Mesabi range in Min-
nesota’ the writer pointed out that the word “jasper” was not a strictly
correct name for this peculiar quartz rock, but concluded to retain it for the
iron-bearing series. Since that time, however, he has become impressed
with the widespread occurrence of this variety of quartz, which arises from
the replacement of some original rock, ordinarily limestone or dolomite, by
silica from circulating waters; and there seems to be need of some term
which may specifically dicate it. For this use the word ‘‘jasperoid”? is
suggested. Jasperoid may then be defined as a rock consisting essentially
of cryptocrystalline, chalcedonic, or phenoerystalline silica, which has
formed by the replacement of some other material, ordinarily calcite or

1 The Mesabi iron-bearing rocks: Bull. Minnesota Geol. Survey No. 10, p. 135.
» Meaning a jasperlike rock.

220 GEOLOGY OF ASPEN MINING DISTRICT, COLORADO.

dolomite. This jasperoid: may be white or various shades of red, gray,
brown, or black, the colors resulting from different forms of iron in varying
proportions. This term covers in part what is known among the Western
miners as flint, chert, quartz, etc., and also includes the so-called “jasper”
of the Lake Superior regions.

So great has been the silicification along certain fault zones that these
faults may be traced continuously by the blocks of jasperoid which outcrop
or lie on the surface, for the jasperoid forms a dikelike body in the lime-
stone. These zones are especially well developed in the southern part of
Tourtelotte Park. Pl. XXXII shows in the center such an outcrop of jas-
peroid which has been left above the surrounding surface by differential
erosion.

Silicification is always an accompaniment of ore deposition, both
occurring under the same conditions. The former process, however, is
more widespread, and hence has occurred not only in places favorable to
ore deposition but along zones where there has been no mineralization of
importance. Quartz formed by the replacement of the limestone is always
present in the ores as a gangue. Some ores are especially high in silica,
that of the Dubuque in Queens Gulch on the Castle Creek fault containing
40 or 50 per cent. This quartz occurs in the ore itself and extends from it
out into the surrounding limestone, showing its great abundance and the
easy conditions under which it is deposited. The phenomena accompany-
ing the development of quartz in ore bodies are similar to those along frac-
tures where there is no great mineralization. Where, as is often the case,
it occurs in company with other gangue minerals, among the most promi-
nent of which are barite and dolomite, the relation of all these shows that
they have crystallized at about the same time and under the same condi-
tions. All have evidently replaced the limestone, in which they generally
form idiomorphic crystals which are often quite isolated.

From the association of jasperoid with dolomite belonging to the
second period, as well as from the evidence which microscopic study
affords, it is clear that the quartz was deposited at the same time and
under the same conditions as the magnesia. In the case of the dolomite
the conclusion has been arrived at that the change from limestone has been
brought about by ascending magnesia-bearing waters, and it has been
shown that such a change is now going on at Glenwood Springs. The

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FERRATION. 221

comparative analyses which were cited to prove this phenomenon at Glen-
wood Springs also show an accompanying silicification, which is actually
being brought about by the ascending hot waters.

The effect of silicification along fault planes is seen not only in dolo-
mite and limestone, but to less extent in other rocks. In the calcareous
Maroon sandstone at the Yopsie tunnel, in Queens Gulch, the chief altera-
tion accompanying the formation of barite and other gangue materials
appeared, under the microscope, to be the accession of silica. This silica
sometimes penetrates the rock along porous zones, where the original frag-
ments are cemented by secondary silica, as in quartzite; or, in the more
altered portion, the rock is recrystallized so as to resemble jasperoid. In
granite lying against the Castle Creek fault in Queens Gulch the original
quartz grains have been enlarged by secondary silica so as to present
hexagonal idiomorphic outlines. These enlarged crystals have zonal

structure, showing their method of growth. i

FERRATION.

Another widespread chemical change in the rocks is the deposition of
iron. This is frequent in limestone, where the alteration into iron has
taken place along water channels, thus. showing the secondary nature of
the mineral. Almost invariably the ferration is only partial, and often
extremely slight, accompanying dolomization and _ silicification. Along
zones where these processes occurred the iron seems to have been origi-
nally deposited chiefly as carbonate, which crystallized together with the
dolomite. Often, however, the microscope shows small crystals of pyrite
embedded in ferriferous dolomite, and their relation is such as to indicate
that sulphide and carbonate of iron have erystallized at about the same
time, for the sulphide is confined to those areas where the calcium car-
bonate has been replaced by magnesium and iron carbonate. On oxidation
the iron carbonate changes to oxide, thus giving the brown color which all
oxidized dolomite has in this district. This oxidation brings out the iron
in the rock more plainly under the microscope than when it is in the form
of carbonate; and all the stages of change can be seen in partially altered
specimens. After oxidation the iron shows a tendency to segregate, and so
form nodules, and in the process of formation the iron of these nodules

222 GEOLOGY OF ASPEN MINING DISTRICT, COLORADO.

actually replaces the original minerals. Where, as in sandy dolomite, the
original rock consisted of dolomite and quartz grains, the iron replaces the
dolomite first, and thus cross sections of the nodules show quartz grains
embedded in iron oxide. hese grains, however, have corroded outlines,
and bit by bit they entirely disappear, showing that the iron also replaces
them, although more slowly. The replacement of quartz by iron oxide in
the process of concentration is best shown in the Cambrian quartzite lying
close to the Castle Creek fault in Queens Gulch. Here is formed what
appears to the eye to be a nearly solid iron ore, inclosing occasional small,
irregular, residual portions of fine-grained, gray quartzite, which become
stained yellow and brown and so grade off into iron. The structure of the
rock is porous, with many small irregular cavities, the walls of which are
lined with botryoidal or stalactitic brown limonite. Under the microscope
the section is about nime-tenths pure iron oxide, mainly opaque, noncrystal-
line, specular iron, having a nearly black color, with a tinge of red, and a
metallic luster. This oxide incloses many small irregular areas of crystal-
line quartz. Sometimes such an area is a small fragment of the quartzite,
consisting of a number of grains, and upon the borders of this fragment the
hematite is encroaching. The iron replaces first the secondary quartz
which cements the grains, and so tends to surround and isolate them; but
the irregular outlines of these separated grains show that the iron has
affected them also, and it is evident that in course of time they disappear
completely. This is a very satisfactory case of actual replacement. On
the other hand, there are certain areas which are made up entirely of iron
oxide, with no residual quartz. Instead of hematite only, there are here
both specular iron and crystalline limonite. The limonite is translucent,
with arich golden-brown color, and is made up of many small crystalline
fibers or elongated plates. The specular iron and the limonite are arranged
in beautiful concentric rings, like those of agate or Mexican onyx. These
concentric deposits often leave an irregular cavity in the center, the out-
lines of whose walls correspond to the shape of the concentric zones. The
covering next these walls is generally a comparatively thick one of limonite,
which is botryoidal in the hand specimen, and under the microscope is
seen to be made up of long, slender, radiating crystals with spherulitic
arrangement. This is a clear case of a filling of preexisting cavities.

FERRATION. DADS}

Wherever there has been any rearrangement of the materials in the
rock by circulating waters, with or without deposition of precious metals,
a varying amount of iron has almost invariably been deposited. The
Maroon calcareous sandstone in the Yopsie tunnel, in Queens Gulch,
which has been cited as showing silicification, shows also an accompanying
ferration. The granite which les next the Castle Creek fault below the
quartzite in Queens Gulch shows, among the new minerals introduced by
waters which have circulated along this fault zone, veins and idiomorphic
crystals of a carbonate which turns brown on oxidation and is probably
ferriferous dolomite. In localities where precious metals have been
deposited iron is always present as a metallic gangue. Often this iron
is in the form of sulphide, but ferriferous dolomite or ankerite is also very
common. This latter mineral is generally in the form of idiomorphic
crystals, and occurs closely associated with barite and other gangue
minerals, and from this association it appears that they were all formed
at one time.

It appears from these facts that carbonate of iron crystallized at the
same time and under the same conditions as quartz and dolomite, as well
as certain other rarer minerals. On the evidence afforded by small areas
of ferriferous dolomite containing pyrite crystals surrounded by unaltered
limestone free from sulphide, it appears that iron carbonate and iron
sulphide were probably at times deposited simultaneously. The alteration
observed in the blue limestone at Glenwood Springs, which resulted from
the action of ascending hot springs, and which has been discussed in
connection with the question of dolomization, was characterized also by
deposition of iron. In the unaltered rock iron is practically absent, while,
as the process of alteration goes on, the amount of iron becomes very
noticeable. This iron is doubtless deposited as carbonate, but, on oxida-
tion, changes to ferric oxide, and so stains the rock brown. The fractures
along which hot waters have formerly circulated at Glenwood Springs, but
which are now dry, are prominent on account of this bright-colored oxide.
It is possible, also, that some of the iron may at this place be deposited as
sulphide, but this could not be determined accurately by analysis, on
account of the sulphur which exists in the rock as sulphate, and no
microscopic study was made.

224 GEOLOGY OF ASPEN MINING DISTRICT, COLORADO.

ORE DEPOSITION.

NATURE OF ORES.

Near the surface the ores of the Aspen district occur as oxides, sul-
phates, and carbonates, mixed with sulphides, from which they are evidently
derived. With increase in distance from the surface the oxides, sulphates,
and carbonates disappear and give place to pure sulphides, showing that the
latter was probably the universal condition previous to the action of surface
agencies. ‘The most important and common of these sulphides is argentif-
erous galena. Blende is also very abundant, especially in certain locali-
ties, and other sulphides are of less frequent occurrence. Pyrite and
chalcopyrite, with occasional bornite, are also found. The sulphide ore in
Dubuque tunnel in Queens Gulch contains a considerable amount of these.
In the Mary B. tunnel on West Aspen Mountain the ore contains large, per-
fect crystals of iron pyrite, which carries small amounts of arsenic, lead,
copper, zine, cadmium, cobalt, and nickel. Tetrahedrite and tennantite are
also very common. These minerals are called ‘‘gray copper” by the
miners, and always form valuable ore, since they contain a large propor-
tion of silver sulphide. An analysis of tennantite from the Mollie Gibson
mine, by 8. L. Penfield, is as follows:*

Analysis of tennantite from Mollie Gibson mine.

Per cent.

Sulphare2 5355252 e ae oe eee eee re St 25.04
HAT SOTIIG ia eee re Oey ra ea ence Seem hee 17.18
ONG alieih coYoy aly gaeeanipe ea Ne eA an Sear oe .13
Copper ie sere ee ee ees eren Ee Be een 35. 72
Silver 202528 ols WS eee I Dee Pelee ee ee a Ee wa 13.65
TANG EOE Re ah aie ae ee ee Sis eee aay 6.90
Tromso tier Sout ea pa aetna ce teeta i ere perenare at 42
Dee die oh Se A ee eet erect ce ar ae 86

Total 2h eee eee ten ee eer 99. 90

In the Mollie Gibson and Smuggler mines there is much polybasite,
which generally occurs in flesh-colored barite. Two analyses of this poly-

1 Am. Jour. Sci., July, 1892, 3d series, Vol. XLIV, p. 18.

ORE DEPOSITION. 225

basite from the Mollie Gibson, by 8. H. Pearce and 8. L. Penfield, gave
the following results when corrected :

Analyses of polybasite from Mollie Gibson mine.

| | Percent. | Per cent.

| FS eU AG) clyy Fein Sete Se SR a RUA eg OY Set iiss 18.13
PAT SOT Caner seers eee oe oes Deena 6. 29 7.01
PAIN OM Ye Aen ee cere eee eo .18 30
Silversea ss oe ae pe 59. 73 56. 90
Coppers serene eens e eee pee een 12.91 14. 85
ZAIN GP ee Na Na eS LO i tiie es 3.16 2.81

TR ONS eee a a oer ate ee 100. 00 100. 00

This polybasite ore in the Smuggler and Mollie Gibson is reduced
along watercourses to native silver, so that the ore consists of pink or gray
barite bound together by irregular wires and masses of silver. As this
process is attended by some loss of bulk, the ore also becomes much jointed
and loses cohesion. The process of change is not completely understood, but
it seems probable that the organic material in the Weber shales which lie
around and against this ore has been active in the reduction. The gradual
change of polybasite to silver around the edges and along crevices can be
seen under the microscope..

Near the surface these sulphides are altered, there being a gradual
transition between pure sulphides in the deep mines and pure oxidized
minerals in the highest mines, such as those in Tourtelotte Park. The
principal ore in these upper zones consists of earthy carbonates and sul-
phates, chiefly of lead (cerusite and anglesite) ; among the oxides hematite
and limonite are very common, and the red oxides of copper and lead
(cuprite and minium) occur in blotches in the oxidized ores, usually
indicating the presence of silver. The black oxide of copper, melaconite,
has been observed in thin coatings.

GANGUE MINERALS.

The gangues which accompany these sulphides consist chiefly of
quartz in small crystals and crystalline aggregates ; of crystallized dolomite,
usually ferriferous; and of barite or heavy spar. In the Mollie Gibson
and Smuggler mines the barite connected with the polybasite ore has often
a flesh or pink color, which is due to a small amount of iron oxide.

MON XXXI 15

226 GEOLOGY OF ASPEN MINING DISTRICT, COLORADO.

Calcite is very common, and in many low-grade ores the dolomite of the
unreplaced country rock forms the chief gangue material.

COMPOSITION OF ORES.

In order to get at the average composition of the ores of Aspen,
nearly four hundred assays of shipments were obtained, representing ores
from nearly every mine in the district. Hach of these assays is a compar-
atively exact average of many tons of ore, this average being obtained
before analysis by a mechanical process at the sampler. These different
analyses were again added together and averaged. Since the ores have a
wide range in point of elevation, varying from 10,800 feet and over in
Tourtelotte Park to 7,400 feet or lower in the deep workings of the Mollie
Gibson and Smuggler, the different analyses were tabulated and arranged
according to elevation, in eighteen distinct zones, each zone being 200 feet
in thickness. Thus the average analysis given for 7,400 feet includes all
the ores from between 7,300 and 7,500 feet; that given for 7,600 feet
included the ores from 7,500 to 7,700 feet, and so on,

Table showing average composition of Aspen ores, arranged according to elevation.

Elevation.| @i03. | (Gads. | CFes0s). | (Bas0). | Gay. | "B" | Gb): aay
Feet. Per cent. Per cent. Per cent. Per cent. Per cent. | Per cent. | Per cent. | Oz. per ton.
7, 400 23.2 13.1 1.8 12.6 ae | Ie rae 17.5 460.0
7, 600 19.7 17.3 2.7 13.3 2.6 2.6 5.6 234. 6
7, 800 92 13.2 4.3 20.8 1.9 3.5 16.3 39.5
8, 000 17.4 17.5 5.5 25.6 1.8 5.2 1.8 59.3
8, 200 9.9 10.3 4.5 14.5 3.2 5.2 Beil 56.6
8, 400 |. 10.1 28. 4 2.4 3.5 1.5 1.0 3.8 25.38
8, 600 12.8 28.3 3.3 2.0 1.0 3.0 2.4 52.0 -
8, 800 17.1 23.5 6.4 11.9 1.3 1.8 10.8 36.5
9, 000 10.3 23.8 4.5 1.3 4 7 4.5 26.5
9, 200 19.8 21.4 6.2 5.5 BON ae Wetec 10.4 51.3
9, 400 33. 1 12.7 6.4 Te 3.7 5.7 3.0 26.0
9, 600 22.6 8.7 10.1 28.7 1.9 3.90 2.9 49.8
9, 800 382.8 10.8 6.5 23.2 1.4 2.1 8 71.9
10, 000 23.0 11.1 8.9 24.2 2.1 8 4.4 51.0
10, 200 37.6 14.8 4.9 16.4 1.5 9 2.4 35.6
10, 400 27.3 7.5 10.3 21.8 3.2 6.6 6.7 62.5
10, 600 BY) |jeceseoeeas|Facccorase SOND Se Seek Sea tally eee | meee rea 27.3
10, 800 28.5 12.8 4.4 31.0 | Trace. 1.0 6.0 36.7

ORE DEPOSITION. 227

This table was primarily worked out with the idea that some definite
order in the deposition of different minerals at different depths might be
found, but the writer is unable to see any definite law. he table is valu-
able, however, for showing the average composition of the ores as derived
trom the tests of many hundreds of thousands of tons.

PARAGENESIS OF VEIN MATERIALS.

Microscopic examination shows that while the dolomite of the earlier
period existed before the mineralization, yet among the vein materials
ferriferous dolomite, quartz, and barite have ordinarily crystallized simul-
taneously. These minerals form large idiomorphic crystals, which are
_ intergrown. Some of the sulphides seem to have been deposited at the
same time with these gangue minerals, as is the case where crystals of
pyrite are found interbedded in small dolomized areas which are surrounded
by pure limestone, free from both magnesia and iron.

In perhaps the majority of cases, however, the sulphides seem to have
crystallized at a very slightly later period than the barite. While the
barite generally accompanies the ore, its presence is no indication of more
valuable minerals, for many large and solid barite veins are found which
are practically barren. This is the case, for example, with the large barite
vein at the end of Yopsie tunnel. In Tourtelotte Park and in Smuggler
Mountain, especially in the Mineral Farm mine, there are great masses of
barite which contain very little valuable ore. Under the microscope the
rich polybasite ore of the Mollie Gibson is seen to be composed partly of
barite in interlocking, tubular crystals, among which are scattered bunches
of polybasite, which are irregular in shape and have no suggestion of
crystalline form. The polybasite does not follow definite zones, but is
deposited between and around the barite crystals, showing that it erystal-
lized at a slightly later period than did the barite. On Smuggler Mountain
one of the chief ores is the so-called ‘“ crisscross spar,” which is a barite in
which is deposited tetrahedrite or tennantite in narrow seams. ‘These seams
are usually nonpersistent, and typically they form small isolated crosses,
which give the ore its name. The arms of the crosses have the appearance
of belonging to definite fracture systems, which have traversed the barite
in directions independent of the planes of crystallization and cleavage, and
therefore have opened at a period subsequent to the formation of the

228 GEOLOGY OF ASPEN MINING DISTRICT, COLORADO.

mineral. Along these crevices it is apparent that the metallic sulphides
have been introduced by circulating waters and have there been deposited.
The analysis on page 224 of tennantite from the Mollie Gibson mine shows
that it contains a large amount of silver sulphide, and explains why this
crisscross spar invariably forms pay ore. The slight greenish stain which
arises from the alteration of the sulphide is taken by miners as indicating
the richness of ore throughout the district. Fig. 9 is a photograph of a
particularly good specimen of } this crisscross spar, kindly made by Mr.
D. W. Brunton, of Aspen.

It seems evident that these crosses were ‘formed along fractures made

Fig. 9.—Crisscross spar.

in the barite since its formation. But as they are typically nonpersistent,
the question arises as to whether the fractures themselves were nonpersist-
ent or whether the sulphides have been deposited only at the intersection
of two or more fractures. The writer at first was inclined toward the latter
belief, but some phenomena of fracturing which point to the former alterna-
tive have been observed in the granites of Smuggler Mountain, not far from
the place where the crisscross spar occurred. Certain zones of this granite
have developed a gneissoid or slightly banded structure. Microscopic study
shows that this change is due to shearing, and one effect of this shearing
has been to bring about the formation of tiny fractures in the quartz grains.
These fractures are intermittent, like the sulphide seams in crisscross spar.

ORE DEPOSITION. 229

They often form isolated crosses, and are most frequent in the center of the
grain, from which they diminish toward the edges. Fig. 10 is a drawing of
such a grain magnified 100 diameters.

Besides the gangue minerals which have already been mentioned cal-
cite in its crystallized form is common in many ores. In every case where
this has been studied microscopically it is found to be later than any of the
ordinary gangue materials, and also later than the accompanying sulphides.

Fra. 10.—Microscopic fractures in granitic quartz.

Where it occurs in connection with barite, ferriferous dolomite, and quartz,
it follows irregular spaces which are inclosed by the idiomorphic crystals ot
these minerals, and where, as in the Late Acquisition mine, galena occurs
as a crust on the fragments of a breccia, this crust is covered with coarsely
crystalline calcite which forms the immediate wall of the cavity.

LOCUS OF ORE DEPOSITION.

With scarcely a single exception the ore in the Aspen district is found
along faults or faulted and fractured zones. Thus, for example, on Aspen

230 GEOLOGY OF ASPEN MINING DISTRICT, COLORADO.

Mountain the ore occurs along the Contact, Aspen, Chloride, Bonnybel,
Schiller, Pride, Mary B., and other faults. In Tourtelotte Park the chief
mineralization has taken place along the Contact and Silver faults, but the
ore shoots follow east-west and north-south fractures which cut these flat
faults. On Smugeler Mountain ore is found along the Silver fault, but
chiefly at its intersection with other faults and fractures which belong for
the most part to the Della system; and in Queens Gulch and southward to
the Little Annie mine, ore is found on the Castle Creek and its dependent
faults. In all these cases the ore has evidently formed in place and has
been deposited since the fault movement, for the breccia which was formed
by this movement has been replaced and cemented by metallic minerals
and by gangues, so that it very often forms the chief ore. In other faults
ore is found broken by the movement along the fault in which it occurs,
showing that the displacement took place, partly at least, subsequent to
the ore deposition. Often, again, ore bodies which have formed in place
along a fault have been disturbed by some subsequent movement, whose
plane intersected the plane of the first.

The Silver and Contact faults, which lie close to the bedding, have
been most important in determining the deposition of ore. These have
been followed throughout the district as the most likely localities for
discovering ore bodies, and thus the most productive zones run very close
to them. It is not everywhere, however, that they are sufficiently mineral-
ized to form ore. Indeed, this is not generally the case. The actual ore
bodies are usually found at the intersection of these faults with some fault
belonging to a different system. Along such a line of intersection the
mineralization has taken place in continuous and definite shoots. The case
of Smugeler Mountain may be cited, where nearly all the ore bodies which
are extensive and rich have been formed at the intersection of the Silver
fault with crosscutting faults, chiefly those which belong to the Della
system. Along these intersections the shoots are extensive and continuous
for long distances, while elsewhere both the Silver fault and the cross-
cutting breaks are ordinarily barren. In Aspen Mountain the best ore is
found, both in dolomite and in blue limestone, at the intersection of small
cross faults with the Aspen and Contact faults. In Tourtelotte Park the
richest ore has been found in certain nearly vertical shoots which cut the
Contact fault and run up continuously, in many cases, through the whole

a eS

ORE DEPOSITION. 231

thickness of blue limestone to the overlying shale, being highly mineral-
ized, so as toform good ore throughout their whole extent. The Contact
fault, away from the immediate vicinity of these fracture zones, also shows
evidence of great mineralization, but the ore is generally low grade and
can not be profitably worked.

EXTENT OF ORE DEPOSITION.

The surface extent of the district which has been actually largely pro-
ductive of ore is practically identical with that of the faulted and uplifted
region which is centralized in Tourtelotte Park and Aspen Mountain. With
the disappearance of the faults and the appearance of comparatively
unbroken strata the ore disappears, as might be expected from the fact
which has just been pointed out, that ore invariably occurs along these
faults. in the Hunter Park district, where there has been no faulting, there
-is also no mineralization, while in the Lenado district, where there are indi-
cations of a considerable amount of ore, the sections show a local uplift,
apparently corresponding in nature with that of Tourtelotte Park. The
main mineralization, however, is restricted to a small surface area, whose
center is approximately in Aspen Mountain and Tourtelotte Park, and
on whose borders are Smuggler Mountain on the one side and the
deposits along the Castle Creek fault in Queens Gulch and southward on
the other.

Within this uplifted and broken area ore has formed with an unknown
vertical extent. he already existing mine workings have a great range in
point of elevation, extending from the top of Tourtelotte Park down to the
lowest levels of the Mollie Gibson and Smuggler, which extend nearly
1,000 feet below the bottom of the Roaring Fork Valley. This gives a
vertical range of about 3,500 feet, and between these two points the ore is
practically continuous. At the highest point the ore is found up to the
grass roots, and at the bottom of the lowest workings there is still the same
amount of mineralization. The table of analyses given on page 226
shows that in all this great range there is no important or persistent change
in the composition or value of the ore, which indicates that it must extend
downward tor an indefinite but comparatively long distance, and that the
original ore deposits extended far above the present surface, where they are

232 GEOLOGY OF ASPEN MINING DISTRICT, COLORADO.

now revealed by erosion. It seems very probable, therefore, that this chief
ore-bearing district has a greater vertical than lateral extent.

AGENTS OF MINERALIZATION.

From an economic point of view the deposition of metallic sulphides is
the most important change which has come about in the rocks, but from a
strictly scientific standpoint the formation of sulphides is only a minor
phase in the general alteration which produced chiefly dolomite, quartz.
and barite. Sulphides of the metals, where present, are always closely
associated with these gangue materials, are generally inclosed by them,
and occur along the same zones, these zones following faults and fractures
which have evidently been watercourses. Microscopic study has shown
that in places some of the sulphide was probably contemporaneous in for-
mation with the magnesium and iron carbonate which replaced the lime-
stone, forming ferriferous dolomite. The dolomite, quartz, and iron have
been shown to be derived probably from heated and ascending waters, and
this origin, therefore, is the one which, is most applicable to the associated
sulphides.

INFLUENCE OF DIFFERENT ROCKS ON ORE DEPOSITION.

The chief ore deposits occur in limestone or dolomite, in the majority
of cases close to the Silver and Contact faults. There is some deposition
of the precious metals in the lower formations, but not to any great extent.
In Queens Gulch some ore has been shipped from the Silurian dolomite,
and in the Princess Louise shaft in Spar Gulch a small amount was taken
from the Cambrian quartzite. Near the Castle Creek fault in Queens Gulch
even the granite shows evidence of mineralization, being altered and partly
filled with gangue materials, such as quartz and ferriferous dolomite. Above
the Leadville limestone some mineralization has been noticed in the red
Maroon beds on Red Mountain, these beds being impregnated to a small
extent with copper and silver, but not sufficiently to form ore bodies.
Within the chiefly mimeralized zone ore has been found extending through
the whole thickness of the blue limestone, as in the Aspen, Durant, Camp
Bird, Justice, and other mines, and in places nearly the whole thickness of
Leadville dolomite is mineralized, as is the case in the Bonnybel mine

ORE DEPOSITION. 233

The generalization may be safely made, however, that most of the ore
occurs throughout the district in the vicinity of the Weber shales, near the
contact of these shales with the underlying rocks, and much of it actually
occurs in this contact, which is formed by the Silver fault.

PROCESS OF MINERALIZATION.

The ore which occurs along faults and fractures extends into the
apparently solid rock on both sides irregularly for a short distance. Micro-
scopic study shows the process by which the metallic sulphides have
replaced the original rock in these cases, for most of the ore is only a
partially or even a slightly altered limestone or dolomite. In every case
where examination was made of such ore the rock was found to be
traversed by numerous reticulated fractures, along some of which micro-
scopic faulting has taken place, all this show-
ing the effects of great strain consequent upon
the fault movement. Along these crevices the
ores are in every case first introduced, and
often this is the sole method of mineralization.
Where the alteration has been greater, how-
ever, the metallic minerals penetrate from the
fractures into the rock on both sides. The
solutions seem first to travel between adja-
cent crystals of calcite or dolomite, and also

Fia. 11.—Fossil changed to native silver.

along the cleavage planes of these minerals, this cleavage being espe-
cially well developed in consequence of the straining. In this way a
still finer network is formed, which, by spreading and widening, has,
in extreme cases, finally consolidated and formed a continuous mass of
sulphide. There is no doubt that this is an actual process of replacement,
the calcite or dolomite being taken up molecule by molecule and replaced
by metallic minerals.

A further evidence of this process. of replacement is the finding of
fossils which are completely interbedded in the ore, or have been so changed
as to forma part of the ore. Fig. 11 shows a mass of pure native silver,
just as it was taken from the ore at the sampler in Aspen. In this silver
part of a perfect fossil gasteropod is firmly embedded, and it is somewhat

234 GEOLOGY OF ASPEN MINING DISTRICT, COLORADO.

remarkable that the shell is still made up of the aragonite of which it was
originally composed. In the open cut near the Smuggler shaft the writer
found a similar fossil gasteropod in hard ore. Both this fossil and the
inclosing rock are largely made up of zine and lead sulphides and carbon-
ates, the composition of the fossil being exactly like that of the rock. The
base of the fossil was embedded in hard ore like itself, but around the
remainder the ore had been softened and so had fallen away, leaving
the fossil projecting from the walls of the cut.

On the other hand, some of the metallic sulphides were deposited in
preexisting cavities. In some of the ores on West Aspen Mountain, which
occur along north-south faults, the galena is found as a crust which covers
the fragments of a breccia, and often the mineralization has been so partial
that irregular cavities are still left unfilled, the walls of which are coated
with galena. In solid dolomite and limestone the sulphide often occurs in
small nonpersistent seams, which have the aspect of veins, and the
occurrence of argentiferous tetrahedrite or tennantite along crevices in
heavy spar, forming the so-called crisscross spar, has already been
described.

CAUSE OF THE PRECIPITATION OF ORES.

One of the most significant facts in regard to the occurrence of ore
bodies is that they are generally found at the intersection of two faults, one
of these faults usually dipping steeply, while the other is much flatter. If,
as we have supposed, the solutions which brought the minerals were ascend-
ing hot springs, we may further suppose that these springs rose along the
more steeply dipping or nearly vertical faults. If this is the case, the
metallic sulphides were not deposited to any extent except at the intersec-
tion of these steep channels with others which lay flatter; but at such
intersections there was some. strong motive for precipitation, so that contin-
uous and rich ore shoots were formed. The flatter-lying fault must also
have been the channel of solutions, and the explanation is offered that by
the mingling of solutions which had previously flowed along different chan-
nels the precipitation of metallic sulphides was brought about. It is not
possible to decide without more careful study than has been made what the
exact chemical processes may have been which brought about this result.

ORE DEPOSITION. 235

The most common method, however, by which sulphides are formed in
nature and in the arts is by the addition of sulphureted hydrogen to sol-
uble salts of the metals. If we suppose that the ascending solutions con-
tained the metals in the form of these soluble salts, and that on reaching
points where the channel along which they had risen was intersected by
some different channel these solutions were mingled with others carrying
an excess of sulphureted hydrogen, the ores would be precipitated just
as we find them. These sulphureted waters, since they flowed along
flatter faults, may have been derived more nearly from the surface. The
proximity of most of the ore deposits to the Weber shales has already been
mentioned. ‘These shales contain much organic matter, the decomposition
of which might readily have produced sulphureted hydrogen, which would
be taken up by waters flowing through them. The occurrence of pyrite in
shales is quite general, and often apparently results from the precipitation of
iron brought in in the form of soluble salts by sulphur given off from decay-
ing organic matter. In the Mollie Gibson mine water flowing from the
shales contains much sulphureted hydrogen, and deposits native sulphur.
This, however, may be in part derived from the oxidation of pyrite and
other already existing sulphides.

ORIGINAL SOURCE OF METALS.

The beginning of the series of changes, of which the deposition of
precious metals was one, consisted in the uplifting of the rocks over a
limited area. This was accompanied by faulting, and along the channels
afforded by these faults there arose mineral-bearing solutions which depos-
ited their burden under the conditions which have been described. The
cause of the peculiar, domelike uplift has been suggested to be possibly a
body of eruptive rock which for some reason accumulated immediately
below this area. The connection of eruptive rocks with ore deposits, not
only in Colorado but throughout the world, is well known, and does not
need any comment. In accordance with the generally accepted views of
hot-spring action, we may suppose that surface waters, on sinking, came in
contact with a body of heated rock which underlay the uplifted area, and
that in this way the water itself became heated and dissolved some of the
rock materials. Eruptive rocks usually contain barium, although this

236 GEOLOGY OF ASPEN MINING DISTRICT, COLORADO.

element is rare in sedimentary beds. It is often found in the feldspars,
and forms an essential constituent in one variety—hyalophane. Sand-
berger’ has shown that most of the metals found in veins as sulphides are
present in eruptive rocks, probably as original constituents, especially in
the dark-colored silicates, such as biotite, hornblende, and olivine. The
heated waters would then be propelled upward, as is actually the case in
all hot springs, and, finding their readiest channels along the faults which
traverse the uplifted area, would follow them and deposit their contents
where conditions were favorable.

CHANGES IN ORE SINCE DEPOSITION.
MECHANICAL CHANGES.

Since the deposition of the ore many of the faults have continued
moving and some new ones have come into existence. In this way ore
which has been formed in place along a fault has often been broken, and
even triturated, by subsequent movement along the same plane. This phe-
nomenon is continually shown along the Silver fault in Smuggler Mountain
and many other mineral-bearing faults Where new faults have developed
since the ore deposition the ore bodies have often been displaced and their
parts more or less widely separated. The displacement by the Clark fault
in the Smuggler and Mollie Gibson mines is an example of this. Along
such faults the ore occurs in the breccia, having been dragged up from the
solid mass. The ore at Lenado is supposed to be a larger example of this
same process, the broken-up condition showing that it has been subjected
to great movement since its deposition

CHEMICAL CHANGES.

Formation of native silver _—Native silver is of very common occurrence in the
ores immediately below the oxidized zone. In the rich polybasite ore of
the Mollie Gibson and Smuggler it often forms a very important constitu-
ent. This native silver is generally associated with the carbonaceous Weber

shale. It is sometimes solid and massive, but very often spun into wires

1¥. Sandberger, Untersuchungen itiber Erzgiinge, 1882.

CHANGES IN ORE SINCE DEPOSITION. Dail

and delicate threads, which occur in crevices and vues. In one case in the
Mollie Gibson such a vug was a foot or two in diameter and was completely
and closely festooned with threadlike silver in so large an amount that
several small ore bags were filled with it.

The rich ore, consisting of barite and polybasite, with tennantite,
undergoes a change by which the sulphides disappear, their places being
taken by native silver. This process is accompanied by a reduction, so
that the ore becomes crumbling and consists essentially of barite held
together by silver. It is along fractured zones and watercourses that this
ordinarily takes place, and usually also in the neighborhood of the carbo-
naceous Weber shales. Along the Clark fault in the Mollie Gibson some
of the breccia has been cemented by native silver which is apparently com-
paratively recent in deposition. The process is not clearly understood, but
it is probable that the organic matter in the shales has operated in the
reduction, and it is clear also that circulating waters. have probably been
instrumental. In the concentrating works at Aspen, where ore is crushed
and separated by means of ordinary cold water, certain iron parts of the
apparatus become coated with native silver precipitated from the water
which flows over them. ‘This shows that ordinary surface waters have
power to dissolve and carry away silver, which they deposit under favor-
able circumstances. In the highly oxidized ores near the surface, however,
silver is not usually found native, but is apparently altered to one of its
salts.

Oxidation of ores —H or a variable distance below the surface the sulphide
ores have been altered by the effects of surface action, and assume other
forms. In the highest mines in the district—in Tourtelotte Park—the ore
is all oxidized, while in the workings of Aspen and Smuggler mountains
the transitional stages of oxidation are all seen, and in the lower workings
of the deep mines the original sulphide condition prevails. On oxidation,
the ore loses cohesion and becomes brittle or crumbling, the altered
minerals generally assuming a pulverulent form. All the sulphides thus
disappear and are replaced by oxides, sulphates, and carbonates. The
barite, however, does not change. An analysis of the typical oxidized barite
ore from the Buckhorn No. 2 mine, in Tourtelotte Park, was made by
Dr. H. N. Stokes, of the Survey, with the following result:

238 GEOLOGY OF ASPEN MINING DISTRICT, COLORADO.

Analysis of oxidized ore from Buckhorn No. 2 mine, Tourtelotte Park.

Per cent.

Silica((S1Os)s eee Cee sere ek ee ars ee 1.90
Ditaninmycioxid ey (Ch1O)) esse ee Trace.
Carbon dioxide (CO) 2292225222 seen ee eee 10. 69
Sulphur trioxide (SO,) ..-..---------.-.----- 16. 96
Sulphuni(S)i sess eer ee ee eee -30

Silvenioxide! GAs: @) sae renee e ee eee .29 (=.27 Ag, silver).

Copper oxide (CuO) .____.----.---.-_.---__- . 18 (=.14 Cu, copper).

eadioxide!(Pb@) igs. 55 sos sass eee eee 38.46 (=85.71 Pb, lead).
‘Alumina ((AVO)) oes es wee ee ene ae 48
(Hernicioxid ey Hic! ©) Sass tee eee aa 43
Manganese oxide (MnO) _-____--.-_---_--_-- Trace.
(Baryitia (a. ©) keen seta Se ENE ellen ay eee 22.11
Strontiah (SiO) pases ope ee eee ee . 46
Mime (CaO) Ree Lee ee ee ea es, 7.74
PaMaonesian(Ma@)asesesse sate ee ee .16
Belowaldl 0 caaee saan . 05
WEEN D) oc3) iis trie 33
100. 49
hess! @ = S aoa a ann sea ee are ee .15
100. 34

The following table represents the approximate composition of the ore
under the assumption that barium and strontium are present as sulphates
only, that the small amount of sulphur exists as sulphide of silver and lead,
that the remaining sulphur trioxide is in lead sulphate, and the rest of the
lead exists as carbonate. The carbon dioxide left over just suffices to form
calcium carbonate from the lime:

Approximate composition of the ore.

Per cent.

IBeyruhen, Sllonene) (IBHNSKO),)) =. senesceseo condo s5e seeoee nsedenasmeccer 33.7
Strombinmay slate (STS Oy) pee eee eee .8
Lead sulphate (PbSO,)..-. --.-.- pe eho R pee eN Ae aa) heaps a 19.1
Meadicanbonater((hbDCO, as ast seo ees ee ee 0 ee eae ei eae 26.7
head sulphider(PRbS) pute sa nase seem e es Oe ne eed epee ae 2.2
@alciumycarponatiecy (Ca O)) meme eee ae enema ee 14.3
Silverssulp hi eVect aee se chee ee .3
97.1

Othericonstituents. ose sc 2 Gas. eee a ee 2 eee 3.5
100.6

CHANGES IN ORE SINCE DEPOSITION. 239

This analysis shows that the lead at least, which is the most conspicu-
ous metallic constituent, is contained in the oxidized form both as sulphate
and as carbonate, chiefly the latter.

Sulphate of magnesia——)n the walls of abandoned drifts in the mines there
form under favorable circumstances long, silky, and hairlike masses of
crystals, sometimes several inches long. These are in places very abundant
and beautiful. They have a bitter taste, and analysis shows them to be
composed essentially of hydrous sulphate of magnesia, probably epsomite.
On the walls of quarries or open cuts in the ore a drier white coating forms,
which is composed of sulphates, chiefly the sulphate of magnesia. This
sulphate probably originates from the decomposition of sulphides, the
products of which form sulphate with magnesium solutions.

Sulphur—At Lenado, on the dump of the Leadville mine, a thin crust
of yellow sulphur was noted forming on the outside of the sulphide ores.
There was also a noticeable smell of sulphur dioxide given off, and at the
same place certain white sulphates were found.

Bog manganese in caves —In the Best Friend mine, in Tourtelotte Park, there
is evidence of a fissure which at some recent time existed along the Contact
fault, and which locally opened out into considerable caves. In one of
these caves, which was originally over 20 feet high, and which was subse-
quently filled by cave sediments, the lowest layer of material is very fine
grained and black, and a sample gave on analysis 45.86 per cent of
manganese oxide, with 12.83 per cent of iron oxide. This manganese was
evidently introduced by surface waters, and was precipitated by essentially
the same process as that which forms manganese in bogs at the surface.
The ores of silver and lead contain small amounts of manganese, the
analysis of polybasite ore by 8. H. Pearce’ showing an average of
1.03 per cent of manganese carbonate, while that of the oxidized ores
in Tourtelotte Park by Dr. Stokes gives only a trace. It is probable,
therefore, that the manganese is leached out of the ores in the pro-
cess of oxidation, and that it may be precipitated in a concentrated
form under favorable conditions, such as the bottom of this cave
presented.

Formation of gypsum—Qn the northeast side of West Aspen Mountain there
is an extensive alteration of the Weber limestone to gypsum. Tunnels

1Am. Jour. Sci., July. 1892, 3d series, Vol. XLIV, p. 17.

240 GEOLOGY OF ASPEN MINING DISTRICT, COLORADO.

which run into the hill in this vicinity show the Weber rocks to be much
broken up between the glacial drift and the Pride fault. Ordinarily the
brecciation is greatest close to the fault and at the other end close to the
surface, while in the middle the rock is not so much broken. This seems to
show that the brecciation was due partly to the fault movement and partly
to the overriding of the glacier. Throughout the whole rock the main
feature is the extraordinary alteration to eypsum. Vein gypsum (selenite)
forms in every crevice and chink, and many of the limestone bowlders are
also completely altered to eypsum while still preserving the structure of
limestone. Such bowlders show ordinarily under the microscope that the
gypsum has actually resulted from the alteration of calcite. Thin sections
show mainly gypsum in coarse, interlocking crystals, while scattered
throughout is considerable calcite in coarsely granular aggregates or
interlocking crystals. The calcite forms small, irregular masses with well-
defined boundaries, or occurs in small grains more or less thickly dissemi-
nated in the gypsum; or, not infrequently, it is concentrated into isolated
rhombohedra, recalling the phenomena attendant upon the silicification of
limestone. The alteration of the carbonate to sulphate is thus shown in
its various stages. The Castle Creek fault, from the point where it crosses
Woody Creek after traversing Red Mountain, is continuously marked for
several miles down the valley by a zone composed largely of gypsum.
From a thick deposit which outcrops near Woody Creek along this fault a
sample was taken, which was a fine, white powder consisting almost
entirely of gypsum, as seen by the following analysis:

Analysis of sample from deposit along Castle Oreek fault, near Woody Creek.

Per cent.
Silica (SiOy yarns nek eee ee eee LO OSS oe Soe nae eee a net 1.46
Carbonidioxiden(COs)i ese) seo eee eens jo See eee ee anes eee 2.29
Siallalanwee twenopat6ls) (SO))) asee sadsaseaosneesenas ossceceacuass Saad Seas 40.74
Timoe\(Ca@) eo asseee ee wee ae tae eee Hee Le Eels eto stars 31.86
sMiaonesiay (Mie @)) ie ene we ae Berry ae eee etl eens eee ee 44

The gypsum on Aspen Mountain is evidently post-Glacial, since it has
altered and cemented a glacial breccia. Along Woody Creek its distribu-

——

CHANGES IN ORE SINCE DEPOSITION. 241

tion shows that the change has been brought about by waters which ci: cu-
lated along the Castle Creek fault. It is likely that soluble sulphates,
brought up by hot-spring or other waters, were precipitated when coming
in contact with carbonate of lime, as gypsum, and thus a true replacement
was effected.

Leaching of rocks—Along the underground channels the effects of circulat-
ing waters are seen in the softening of the rocks through which they pass.
The process consists in the leaching out of the more soluble constituents
and in the reduction of the comparatively insoluble portions, by removal of
the cement, to a clayey form. Thus in the vicinity of the Castle Creek
fault in Keno Gulch granite is altered to a kaolin which contains grains of
residual quartz. Along the Lenado fault in the Aspen Contact and Lead-
ville mines the Cambrian quartzite is softened for some distance so as to
form a white clay, which grows coarser and more solid as the distance from
the fault increases. This clay is often called by the miners “ porphyry,”
- but the process of its formation seems to be the removal of some of the
silica, especially the secondary cement between the quartz grains, by circu-
lating waters. When the cement is removed the rock disintegrates and
forms a clay.

The alteration of limestone and dolomite by surface waters along
faults and fracture zones is seen throughout the mineral-bearing district.
Thus along the Silver fault in certain mines the limestone becomes altered,
so as to be mistaken for Weber shales, although the Weber rocks them-
selves are not soft and claylike except where they have been acted upon
by these surface waters. At one locality in the Argentum-Juniata mine
the dolomite along watercourses was observed to be altered completely for
some distance to a soft clay, which is sometimes bleached to a yellow color,
and goes among the miners by the name of “tale” or “shale.” The stages
of transition between the solid dolomite and the clay show sufficiently
the origin of the latter.

In the hard Weber limestones in several places the same phenomena
were observed. In the Clark tunnel at Lenado two samples were taken for
analysis from the Weber rocks, one being of limestone which was partially
softened and the other of limestone which was completely softened and

also bleached. These analyses are given as Nos. 2 and 3 in the following
MON XXxI——16

242 GEOLOGY OF ASPEN MINING DISTRICT, COLORADO.

table. No.1 is the partial analysis of a fresh Weber rock, which chances to
be a nearly typical dolomite:

Analyses of limestones from Weber formation in Clark tunnel at Lenado.

1 2. 3
SiO Nee Se a ree 12.12 | 18.67 | 55.98
AUO RES OA SEE amen 3.97 8.31 | 20.22
Ral Oy Gaveny une Mae Wear 2.06 2.60 7.46
CaO pee Seok ais Saeioue 25.63 | 36.98 3.05
MipOR ei, 55 Rene edd eal ieanl5eo7 72 1.01

From these analyses it appears that the process of disintegration is a
removal of the soluble material, chiefly calcium and magnesium carbonates,
and the consequent concentration of the silica and alumina, the result being
an impure clay.

LIST OF MINERALS.

Following is a list of minerals thus far recognized megascopically in
the immediate vicinity of Aspen:

Sulphides: Galenite, sphalerite, pyrite, polybasite, tetrahedrite, tennantite,
chalcopyrite, argentite, bornite, pyrargyrite.

Sulphates: Barite, gypsum, anglesite, epsomite.

Carbonates: Calcite, aragonite, dolomite, siderite, cerussite, smithsonite, azu-
rite, malachite. i

Oxides: Hematite, limonite, wad, minium (?), melaconite (?), cuprite (?).

Silicates: Calamine (?), chrysocolla.

CHAPTER V.
SURFACE CHANGES SINCE ORE DEPOSITION.

AMOUNT OF EROSION.

Since the beginning of the period of deformation in the Aspen district,
which gave rise to various physical and chemical changes, of which ore
deposition is among the most interesting, an enormous amount of erosion
has taken place. Previous to the Cretaceous uplift there extended over
the whole of this district a thickness of at least 15,000 feet of sediments
overlying the granite. That this is true is shown by the fact that these
sediments still actually exist in that part of the district which hes west of
the Castle Creek fault. East of the fault, however, in the metalliferous
district, the rate of uplifting was vastly greater than farther west, bringing
the granite and the lower sedimentary beds to the position they now occupy
on Aspen Mountain and Tourtelotte Park; and the relief resulting from this
uplift caused accelerated erosion, which from that time to the present has
removed the sedimentary beds down to the granite, a thickness, as stated,
of over 15,000 feet.

DIFFERENTIAL EROSION.

Most of the topographical features of the district have been largely
influenced in their formation by the structure of the underlying rock. Thus
it is noticeable everywhere that erosion of shales and sandstones has been
greater than that of the more resistant granite, quartzite, and solid lime-
stones. For this reason the valleys of Roaring Fork and Woody Creek
widen immediately after emerging from the granite upon the softer sedimen-
tary beds; and Aspen Mountain, where an uplift has produced a peculiar
underground structure differing from the rest of the district, stands out also
as a peculiar topographical form, the ridges of East Aspen and West Aspen
.mountains being formed by the resistant granite, quartzite, and dolomite,

and the broad depression between them resulting from the greater erosion
243

244 GEOLOGY OF ASPEN MINING DISTRICT, COLORADO.

of the shales and porphyry which are contained in the Aspen Mountain
syncline. Erosion of shales under the same conditions has formed the
shallow basin of Tourtelotte Park.

INFLUENCE OF FAULTS.

The faults also, as well as the folds, have greatly influenced the topog-
raphy. Gulches following the outcrops of faults are very common—tor
example, the upper part of Queens and Spar gulches, and Copper Gulch. »
The reason for the formation of gulches along fault lines appears to lie
partly in the fact that fault zones are in brecciated material, which is more
easily eroded than the surrounding rocks. It is notable, however, that in
Spar Gulch and Queens Gulch, only the upper part of the gulch lies in the
fault, the lower part diverging from it to jom some larger channel. These
fault zones are channels of underground water, which occasionally rises to
the surface as springs, and in Queens Gulch such a spring, which is really
a small underground stream, rises along the Castle Creek fault, and it is
from the erosion of this water that the gulch appears to have been chiefly

formed.
GLACIATION.

Most of the topographical forms have been influenced by glacial action.
Glacial drift is found over the whole district, although often locally stripped
off by more recent erosion. In the river beds the glacial deposits are
somewhat modified, and this rearranged drift forms the floor of the larger
valleys, such as Roaring Fork and Hunter Creek. On the high hills,
however, the drift exists as unmodified moraine. On Ajax Hill, which lies
between Roaring Fork and Castle Creek, and above Aspen Mountain and
Tourtelotte Park, there is found all along the southwest side, near the
summit, a broad bench, of glacial origin, carved in the bed rock. This
bench is ordinarily covered with morainal material, so that there are no
outcrops. The material consists of a granitic matrix containing quartzite
and granite bowlders, none of which are of very great dimensions, and is
comparatively uniform, even when the underlying rock is dolomite and
limestone. At intervals, however, this bench has been cut through by
post-Glacial erosion, and the covering of drift has been stripped away.
Thus strongly marked gulches are formed with bare rock on both sides.
Toward the south the bench widens out, and the topography of the whole

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GLACIATION. 245

country suggests profound glaciation. Pl. XX XIII is a view looking south
from this hill toward Difficult Creek and the headwaters of the Roaring
Fork. In the foreground is a broad, gently sloping bench, which, at the
point from which this picture was taken, has an altitude of nearly 11,000
feet, and thus is 2,500 feet above the bottom of the Roaring Fork Valley,
a short distance away. The details of topography of this bench present
a typically glaciated aspect. From a favorable point of view it presents a
rude resemblance to a plowed field, being marked by straight and parallel
furrows set a short distance apart, so that ridges and furrows alternate.
The ridges are sometimes composed of bed rock, but more commonly of
loose morainal material; and the higher ones are often carved into lenticular
forms, suggesting roches moutonnées.

On the opposite side of Roaring Fork Valley there is also continued
evidence of glaciation. The granite hills which rise east of Smuggler
Mountain, between Hunter Creek and Roaring Fork, have all been planed
down by glacial action, and frequently carry morainal material. These
mountains are over 11,000 feet high, and therefore more than 3,000 feet
above Roaring Fork Valley. On the top of Smuggler Mountain proper,
which is 10,000 feet high, the thickness of moraine, as shown in the Park-
Regent and Bushwhacker shafts, is about 400 feet, but this drift is perhaps
the moraine of the Hunter Creek glacier, which was smaller and of later
date than the general ice sheet.

Red Mountain appears from the southeast and southwest sides, from
which it is best seen, as a hill of bare rock, the outcrops of which can be
seen continuously all the way from the top to the bottom. Around the
base of this mountain is morainal material, the upper limit of which is very
strongly marked. The top of the mountain, however, which is compara-
tively flat, presents no outcrops, but is heavily covered with morainal
material, which is chiefly of granite, with some quartzite. On the very top
of the hill, also, there exists a well-marked stream bed, with terraces on its
sides, which have been cut partly in the drift and partly in the bed rock,
and evidently resulted from the action of some swift glacial torrent. There
does not appear to be a trace of this stream bed or of the morainal material
on the mountain side.

Between Hunter and Woody creeks all the highest country is carved
into typical glaciated forms. The topography, as seen on the map, is

246 GEOLOGY OF ASPEN MINING DISTRICT, COLORADO.

comparatively smooth, showing long, low ridges or drumlinoidal hills, with
gently curved or straight furrowlike depressions, which run in a general
east-west direction. Over this surface there is a heavy morainal covering,
consisting chiefly of granite and quartzite, none of the bowlders being very
large. In places there are well-marked lines of moraine, with larger
bowlders, and in these places the drift is often as much as 100 feet thick.
Pl. XXXIV shows this glaciated topography, with the valley of Hunter
Creek on the right and the summits of the Sawatch Range in the distance.

DIRECTION OF ICE MOVEMENT.

Judging from the transportation of material and from the direction of
the furrows which the ice has impressed upon the topography, the glacier
had a general movement toward the west, away from the Sawatch. On Red
Mountain the drift consists mainly of granite and quartzite, which must
have been carried in a westerly direction across the intervening Hunter
Creek Valley. In the Roaring Fork Valley there are large quantities of
granite in the moraine, and granite bowlders are especially frequent below
Red Butte on the flanks of Red Mountain.

DIMENSIONS OF ICE SHEET.

The ice sheet overrode all the hills and valleys in this district, and its
movement was apparently not influenced by the topography. The hills
over which it moved now rise 3,000 feet above the broad Roaring Fork
Valley, and the transportation of material as illustrated on Red Mountain
shows that the ice did not move down into the valley, but along the moun-
tain tops parallel to it. If this valley were as deep at the time when this
great glacier existed as at present, the thickness of ice must have been at
least 3,000 feet. This ice sheet, however, disappeared at a comparatively
ancient period, as is shown by the great effects of subsequent erosion, for
on Red Mountain and other localities the drift has been completely stripped
away from the mountain sides, leaving a bare and apparently unglaciated

surface.
ROARING FORK GLACIER.

In the last stages of the Glacial period the ice shrunk to comparatively
small dimensions, and existed only in local glaciers, which ran in the pres-

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GLACIATION. 247

ent river valleys. Valleys in granite show best the effects of the carving
of these local glaciers, since granite is resistant and homogeneous, and these
valleys present a uniform U-shaped structure. For this reason the valleys
of Hunter Creek and Roaring Fork offer most complete records.

About 10 miles above Aspen, and not far from the summit of the
Sawatch, the valley of the Roaring Fork is wide and shallow, with gently
sloping walls of granite and a granite floor, polished and carved into irreg-
ular, rounded forms. Through the middle of this broad glacial valley there
winds a steep, narrow gorge or canyon, which in places is almost obliterated
and in other places has steep walls which reach probably 200 feet in height.
The tops of these canyon walls form part of the general floor of the glacial
valley. In places this canyon is wanting, the broader valley being locally
deeper and removing all traces of it, while in other places it becomes quite
conspicuous. It becomes progressively fainter, however, as the distance
from the head waters and the depth of the broad glacial valley increase, and
entirely disappears 9 or 10 miles above Aspen. This gorge is evidently the
remains of a pre-Glacial canyon of the Roaring Fork, of which only traces
are left, below the plane of glacial action. Pl. XX XV gives a general view
of the broad, shallow glacial valley, with the pre-Glacial canyon represented
by the V-shaped depression on the right.

Downstream from this bare granite area there is an increasing amount
of ground moraine, the bowlders being very large, and about 5 or 6
miles above Aspen comes a frontal moraine which crosses and fills up the
valley. Just back of this moraine is a little level space, composed of fine
lake sediments, and capable of some cultivation, and in the middle of this
is a small pond, about 200 feet across. his is evidently the bed of a
small lake which was dammed up by the frontal moraine until the stream
cut through and drained it.

Below this moraine the bottom of the valley is remarkably smooth
and level to about a mile above Aspen, where there occurs the rear wall of
a strongly marked terminal moraine, whose front wall comes quite down
to Aspen. Between this moraine and the one last described there is
evidence of a glacial lake which existed immediately after the disappear-
ance of the Roaring Fork glacier. The valley bottom is a series of broad,
flat meadows, with patches and islands of coarse morainal material. Most
of these meadows are wet, and there are also extensive swamps. In

248 GEOLOGY OF ASPEN MINING DISTRICT, COLORADO.

several of these there are small ponds of standing water, which are being
rapidly converted by encroaching vegetation into swamps. Throughout
this soft lake sediment the river has carved very beautiful meanders, as
may be seen in the accompanying plate (Pl. XXXVI). These meanders
have met and cut off repeatedly, some of the cut-offs being complex,
double, or triple, and in the plain on the opposite side from that where the
river now is can be seen the scars of old meanders, showing that the
stream has swung across the whole valley and worked over the sediments
pretty thoroughly since the Glacial era.

Below the terminal moraine which is found just above Aspen the valley
widens out into a broad, level plain, through which the streams of Roaring
Fork, Castle, and Maroon creeks have cut post-Glacial gorges. The glacial
material in the bottom of this valley is probably in places several hundred
feet thick, and is composed of coarse morainal material, which has been
worked over by water action so as to possess a rude stratification. In some
localities there is also a deposit of fier, sandy material, more perfectly —
stratified. On the sides of this valley, as is best seen on Red Mountain,
are broad terraces carved in the bed rock, but sometimes strewn with glacial
material. On Red Mountain these terraces are chiefly two in number, and
on the upper one some agriculture has been carried on. Here the terraces
are carved in the red Maroon sandstones, but farther down the valley, on
the west side of Castle Creek fault, they are well marked in the soft Cre-
taceous rocks. These terraces must have formed since the disappearance
of the main ice sheet, for if they had existed previously they would have
been scored away by the glacier. The highest and most strongly marked
terrace on Red Mountain is 400 or 500 feet above the present valley, and
so can not be accounted for by ordinary stream action. ‘The terraces, there-
fore, probably indicate the shores of a long, narrow lake, which filled up the
Aspen Valley near the close of the Glacial period. The same broad valley
is continuous for several miles downstream below Woody Station. Near
this point a prominent hill, capped with basalt, juts out into the valley, so
as to reduce it to comparatively narrow dimensions. This hill must have
constituted a continual barrier to glaciers, and here toward the close of the
Glacial period there may have accumulated a wall of ice or a moraine
which backed up water so as to form alake. The terraces on Red Mountain

are shown in Pl. XX XVII.

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GLACIATION. 249
HUNTER CREEK GLACIER.

The local glacier which occupied the Hunter Creek Valley has left its
traces in the lateral moraine which lies at the base of Red Mountain. PI.
XXXVIII is a view of the southeast side of this mountain, taken from across
the Hunter Creek Valley. At the base is the lateral moraine of the Hunter
Creek glacier, containing many huge bowlders, which are chiefly of granite.
The upper limit of this morainal material is sharply defined, and above
this there is no evidence of glacial action until the top of the moun-
tain is reached, the rocks being all comparatively bare. On the very
top, however, is the ground moraine of the earlier and more extensive ice
sheet.

The Hunter Creek glacier carved for itself a typical U-shaped valley,
which may be seen in Pl. XXXIX. This view is up the valley, with the
summits of the Sawatch in the distance. At some distance up the valley
is seen a cliff projecting boldly and precipitously into the valley, and this
seems to be a remnant of the pre-Glacial canyon. The valley does not
extend westward farther than the highest terrace on Red Mountain, which
is 400 or 500 feet above the Roaring Fork Valley, where it stops suddenly.
This may be best seen by consulting the special topographical map of
Aspen. The ending of the valley at this level’ shows that the Hunter
Creek glacier flowed into the lake which covered the Roaring Fork Valley
at a time when the latter stood at its highest level, as marked by the upper-
most terrace. When the waters were drawn off from this lake, Hunter
Creek found its way into the waters of Roaring Fork, turning at right
angles to its normal course, and rushing down precipitously over the sides
of the deeper Roaring Fork Valley. In this way it actually descends about
500 feet in a horizontal distance of 2,500 feet, while above this turning
point its course in its east-west glacial valley is very sluggish. In this rapid
descent it has carved a rocky and often precipitous gorge in the Maroon
sandstones and in the drift. The existence of remnants of pre-Glacial can-
yons, both in Roaring Fork and in Hunter Creek, shows that these were both
stream channels previous to the advent of the ice sheet, and it is probable
that their pre-Glacial streams ran at approximately the same level. In the
case of Roaring Fork, however, the local glacier has carved out a valley at
least 500 feet deeper at Aspen than that of Hunter Creek.

250 GEOLOGY OF ASPEN MINING DISTRICT, COLORADO.
RESUME OF GLACIAL ACTION.

The evidence goes to show that at a relatively remote period the Aspen
district was covered by a great ice sheet, which moved west, away from the
Sawatch range, over hill and valley. This glacier carved the surface into
typical glaciated, rounded, and drumlinoid forms, and excavated the softer
shales and sandstones more than the resistant granite. The débris of this
ereat glacier is found on top of the highest mountains in the district:
Subsequently this ice sheet shrank into separate glaciers, which followed the
valleys of preexisting streams and in large measure carved them into their
present forms. ‘These valley glaciers, by erosion along their sides, caused
a steepening of the mountain slopes, and so brought about the removal
of most of the previously accumulated drift. It thus happens that at
present the sides of the mountain often appear bare and unglaciated, and
the drift of the earlier glaciation is found only on the summit. At a still
later stage in the glaciation the valley of Roaring Fork was occupied by a
long, narrow glacial lake, which probably resulted from some temporary
dam. During most of its existence the surface of this lake was 400 or 500
feet above the present town of Aspen, and into it the dying glacier of
Hunter Creek and its waters emptied.

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APPENDIX.

MEASUREMENT OF FAULTS.

According to the definition given by Dana, “faults are displacements
along fractures.” Whenever the rocks of the earth’s crust are subjected
to strain, fractures take place in them as they would in any other body
under similar conditions, and the different parts of the rock tend to move
past one another along these fractured planes, seeking relief from the
strain and accommodating themselves to new conditions. In this move-
ment one part of the fractured rock mass may move upon the other in any
direction—up, down, sidewise, or obliquely—according to the conditions,
which are different in each instance. There is, so far as I know, no law
governing the direction of movement in faults which is of any use in
geological diagnosis. Naturally when there is any preexisting plane of
weakness of the rock which is subjected to strain the movement generally
takes place along this plane, and hence in sedimentary beds it is probable
that movements along the bedding planes constitute the commonest variety
of faults. Inasmuch, however, as the beds in disturbed districts lie in
every conceivable position, the probability just stated does not give any
clue to the average attitude of faults.

The amount of movement in faults can be completely ascertained only
by the aid of independent and accidental phenomena. In homogeneous
rock masses (leaving out of consideration fault scarps, fault gulehes, and
other topographical phenomena, and treating the faulted mass as a solid
without boundaries) the amount of movement can not be ascertained or
even approximately estimated. The existence of a movement can be
determined by the records left on the slipping surface or surfaces in the
shape of ground-up rock or fault breccia, in polished and striated rock
faces, and so on. It is certain, however, that the amount of friction as

displayed by trituration and polishing is not necessarily proportionate to
251

252 GEOLOGY OF ASPEN MINING DISTRICT, COLORADO.

the amount of movement, since faults with slight displacement are often
accompanied by zones showing profound trituration, while others of far
greater movement show to a much less degree the effects of friction.
The friction in each case seems to depend upon the angle of the chief
stress to the sliding plane, rather than on the amount of movement along
this plane. In heterogeneous rocks the amount of movement of a fault
can ordinarily be estimated with more or less accuracy, the degree of
closeness depending upon the nature of difference in the composition of the
rock mass. In such heterogeneous rocks the amount and direction of a
fault movement must be judged by any available phenomenon or phe-
nomena. By far the commonest variations m rock masses which are
constant enough to be reliable as data are in sedimentary beds, and
therefore the commonest means of measuring a fault movement is the
separation of the two parts of an originally continuous stratum. On this
account it is easy to fall into the error of considering faults simply as
dislocations of strata. In careful geological work, however, such as
mining work must necessarily be, it is important to cultivate a more
correct conception, and to regard sedimentary beds as phenomena acci-
dentally associated with faulting, whose dislocation must be associated
with all other available criteria, each one as valuable as the other, to
determine the amount and direction of the total movement or displacement.
Any fault, for example, in which the direction of movement is parallel
with the plane of sedimentation will not cause any apparent displacement
in a sedimentary bed, whatever may be the attitude of the fault plane in
relation to the plane of the stratum; and this may be the case im faults
having any conceivable attitude, since the sedimentary beds themselves
may be folded so as to stand in every conceivable attitude with reference
to any fixed plane, such as the earth’s surface.

When the direction of movement in a fault lies at a slight angle to the
plane of sedimentation, the apparent displacement of a stratum resulting
from this fault will be only a slight part of the actual fault movement; and
it is only when the direction of movement is perpendicular to the plane
of sedimentation that the separation of the parts of the faulted stratum is
an accurate measurement of the movement. Theoretically speaking, the
chances are infinitely against any such coincidence, and in actual practice
it is rare that the movement may be even approximately estimated in this

MEASUREMENT OF FAULTS. 253

way. In mining geology it has been found that the most valuable criteria
for measuring faults are, besides sedimentary beds: igneous bodies, such as
dikes; bodies of ore; strize on the fault plane, showing the direction of move-
ment; and the composition of the fault breccia, which may show, in some
degree, the amount of movement. By taking several of these criteria
together it is often possible actually to ascertain the movement of a fault.

It is sometimes possible to find out the amount and direction of move-
ment immediately; but more often it must be indirectly calculated, and to
do this it is important to have clearly in mind the nature and value of some
of the principal functions of a fault movement, and to have specific terms
by which to designate them. The terms already in use are of a rather
vague and general character, resulting from the usual conception of a fault
as a dislocation of strata. The four terms generally employed are displace-
ment, throw, heave, and offset. The words displacement and throw are used
interchangeably, and commonly refer to the separation of beds by a fault
as seen in a vertical section. Each of these terms is used by some to indi-
cate the distance along the fault plane between the broken ends of the bed
as seen in the section, and sometimes the perpendicular distance between
the parts of such beds, projected if necessary. There is no agreement,
however, which definitely assigns the terms to separate measurements, and
indeed it is very common for a writer to use the terms interchangeably for
one or the other function. Heave and offset are also used interchangeably,
and are usually held to signify the perpendicular distance measured on a
horizontal plane, such as the earth’s surface, between portions—projected
if necessary—of a bed separated by a fault.

In mining work it is generally necessary to differentiate clearly the
different functions of a fault movement, and I have adopted the following
terms descriptive of the most important of these. These terms include
nothing very novel in the way of nomenclature, but are intended simply
to affix definite names to definite things.

Dislocation and displacement are general terms, applicable to any part
or the whole of a fault movement. Lach of the functions defined below,
and to which specific names are given, may be called simply a dislocation
or displacement.

Total displacement is the distance which two points originally adjacent
are separated by the fault movement. The line connecting these two

254 GEOLOGY OF ASPEN MINING DISTRICT, COLORADO.

points lies in the fault plane in all straight faults. It is occasionally possi-
ble to determine the total displacement directly by such criteria as the
separation of the parts of an ore body, the intersection of a given dike with
a given stratum when found on both sides of the fault, and in other ways;
but ordinarily it can only be calculated or approximately estimated from
some of its more easily measured functions.

The lateral separation is the perpendicular or shortest distance between
the two parts of any continuous zonal body, such as a sedimentary bed,
which has been separated by a fault, the distance being measured along
the fault plane. The lateral separation may be measured in a vertical,
horizontal, or oblique line, according to the attitude of the bodies between
which it is measured, and in any fault it may vary from zero to the total
displacement. In the case of dikes cutting sedimentary beds, of marked
unconformity, of abrupt folds, and so on, it may be possible to measure
two or more lateral separations in a single fault. In this case, and ina
number of others which are possible, the total displacement may often be
calculated from the lateral separation, since the latter is always the side of
a right triangle of which the former is the hypotenuse.

The perpendicular separation is the perpendicular distance between
corresponding planes in the two parts of any single body available as crite-
- rion (such as a sedimentary bed), when this body has been separated by a
fault, the planes on each side of the fault bemg projected for the purpose
of measuring, if necessary. The perpendicular separation thus has a cer-
tain relation to the lateral separation; for it constitutes the side of a right
triangle, the hypotenuse of which is the lateral separation, except in the
possible case where the perpendicular and lateral separations coimeide.

This mathematical relation makes it often*possible to estimate the
lateral separation from the perpendicular separation, and from the latter
the total displacement. Of these three functions, the perpendicular separa-
tion is most easy of measurement, and its value may vary from zero to the
full amount of lateral separation. The lateral separation is easier to ascer-
tain than.the total displacement, and its value may vary from zero to the
total displacement.

The measurements which have been defined have no constant direc-
tion, since they refer to fault movements which are capable of infinite
variation. In general geological work, however, it is often only possible

MEASUREMENT OF FAULTS. 255

to measure fault movements along certain arbitrary planes. The most
valuable of these planes are the earth’s surface, which may be considered
a horizontal plane, and vertical sections, into which available data are put,
with the gaps in the chain of information often theoretically filled out. In
such cases, where some dislocation is evident, but the information is so
meager that it is not possible to know the fault so accurately as to estimate
even approximately its total displacement or lateral or perpendicular sepa-
ration, it is necessary to employ specific terms to designate the known or
estimated dislocations, although the relations of these dislocations to the
total displacement may be unknown. For this purpose the terms heave or
offset, throw, and vertical separation may be used. The terms throw and
vertical separation are applied to the dislocations of a fault as seen in a
vertical section; the terms heave and offset, to the dislocation as seen in
a horizontal section, such as the earth’s surface may be considered.

The throw may be defined as the distance between the two parts of
any body available as a criterion (such as a sedimentary bed), when these
parts have been separated by a fault, the distance being measured along
the fault plane as shown in a vertical section.

The vertical separation is the perpendicular distance between the
intersection of the two parts of any body available as a criterion, such
as a sedimentary bed, with the plane of a vertical section, the lines of
intersection being projected, if necessary, for the purpose of measurement.
In perpendicular faults the vertical separation is identical with the throw.
In all others it is less than the throw, but sustains a certain relationship
to it, being one side of a right triangle of which the throw is the
hypotenuse. Thus the vertical separation may vary from zero to the full
amount of the throw. The throw is always a part of the total displace-
ment, although with no definite relationship to it, and varies from zero to
the full total displacement.

The terms heave and offset may be used interchangeably to designate
the perpendicular distance between the intersections of corresponding
planes in the two parts of any body available as a criterion, such as a
sedimentary bed, with a horizontal plane, such as the earth’s surface may
be considered. Like the throw, the heave or offset is a part of the total
displacement, but it has no definite relationship to it.

256 GEOLOGY OF ASPEN MINING DISTRICT, COLORADO.

To sum up, there are six terms proposed to designate different parts
of a fault movement, each term applying to a measurement which varies
in accuracy and proximity to the total displacement in proportion to the
available amount of information. For general outline work, where accu-
rate data are not obtainable, the terms throw and vertical separation,
referrmg to the measurements of a fault at its intersection with a vertical
plane, and the term heave or offset, indicating a measurement of a fault at
its intersection with a horizontal plane, are adopted. The throw and
offset are parts of the actual fault movement, but of unknown value, while
the vertical displacement sustains a certain relationship to the throw.
Where more complete data are obtainable, the terms total displacement,
lateral separation, and perpendicular separation are adopted. The perpen-
dicular separation sustains a certain relationship to the lateral separation,
as the lateral separation does to the total displacement.

IN De

A.
Page.
Adelaide shaft, features of------------------------- 178-179
Alta Argent mine, description of- .-- 196-197
Alta fault, age of ------------------- ------------------ 130
Analyses, chemical--.-..-. -.-------------------------- 25-26,

210, 213, 214, 215, 224, 225, 226, 288, 240, 242
159

Argentum-Juniata mine, features of----.---.-------
Asheroft, mines at ---------------------
Aspen, development of mines near---

discovery of ore deposits at----

XIX

first shipment of ore from.----------------------- xx
history of mining suits at -------.---------- XXI-XXV
railroads to KXL
situation of XVIL
Aspen Contact mine, description of - 200-201
Aspen fault, features of _----------------------------- 65-67
Aspen mine, features of ----.----------- Ue narsaeare 155-157
Aspen Mining and Drainage tunnel, features of-.-. 166
Aspen Mining and Smelting Company’s mine, fea-
(MEO —~ ee Seoeacieeenee ose meseessse Sa 157-158
Aspen mining district, cause of uplift ine sees eae, 147-148
description of sections shown on map of - . 137-143
development of--...--------------------------- XX-XXI
exploitation of __- XXVI-XXVII
fault systems in -------------------~------------ 146-147
features shown on map of ----------------~---- 132-150

XXX-XXXI

geological investigations in

literature of nace 2O-OMGL
litigation in -..------------------------------- XXI-XXV
metals produced in ---:-~--.-.------------ XXVIII-XXIX
mineralization in 146

railroads in__--------------------------- XXI
rate of faulting in--
résumé of structure in
silver product of_.--------------------------.---. XXIX
Aspen Mountain, description of -_-- - 151-167
description of section of
faulting on------------- =
apy WONATS) Ol a oes esses sce es See XVII1, 56-74
folding on----------------------------------------- 56-58
résumé of structure of_-----------
tunnels and shafts on west side of _-... -.-----. 160-161
Aspen Mountain mining map, features shown on. 161-164

Aspen special map, features shown on-------------- 54-84
résumé of structure shown on -------..--. ------ 82-84
B.

Bagg, R. M., fossils identified by--
Baltic tunnel, features of----------
Bay State shaft, features of------------.---.--------- 168
Benton shales, thickness of ---------------------------
POSST] St tees ee ee eee
Best Friend mine, features of ---
probable history of rocks in

MON XXXT 17

Spricerooereeseas mao 202

11, 207, 211

Bimetallic tunnel, features of -
IBISCHOPCHIS tava C1LOG Seen eerste aes

Blue limestone, character, fossils,and age of ---.-.- 28-30
Bob Ingersoll mine, features of--..-.---------------- 170-171
Bonnybel fault, features of --- -.. 67-69

Bonnybel mine, features of -------.-------------- . 151-153
Brunton, D. W., acknowledgments to... XVI, XXII, 17, 22!
quoted on present movement along fault

PIBNeS her eee ae eee eee - 148-149
Buckhorn No. 2 mine, features of------- ees
Bushwhacker mine, description of ----..----------- 193-194
Butte fault system, features of .--...-.--.---------- 98-100

C.
Calcium oxide in Leadville dolomite, occurrence of - 25
Cambrian sediments, character of--.-.-------------- 49
Camp Bird shaft, features of.-..-.---.------------- 172173
Carboniferous formations, description of -- =... 22-37
Castle Creek fault, features of ---------- 58-60, 89-93,
Celeste shaft, features of -......------- ---- 174175
Centennial tunnel, features of___.--.---------------- 205

Chandler, C. F., analyses of water by--------------- 213
Chemical analyses ._---.---------.----
210, 213, 234, 215, 224, 225, 238, 240, 242

Chemical changes in ore since deposition --------- 236-242,
Chemical geology, discussion of---.-.-------~------- 206-242
Chert nodules and bands, occurrence of -_----------- 25

Chloride fault, features of

. Clark fault, features of----...------------

Colorado formation, character of. ...---------------- 41-42
Contact fault) deseription) of 22-2 -s- 2-2-5 seen 74, 106
Copper fault. features Of2 22-22-59 sesso ne ene 95-96
Copperopolis tunnel, features of -- 166
Cowenhoven tunnel, features of------.------ ------ 188-189
Cretaceous rocks, description of_--.--------.--.---.. 4-43
Cretaceous-Tertiary unconformity, description of.. 44-45
Crisscross spar, figure of -- ee 228
Gross;swihibmany ciied essa eeeese cee teen eee een eos Oe
D.
Dakota formation, character of .....----------------- 41

IDEA) dlp ID Cheol os eas --- 1112526, 207
Della fault, features of ___----__- 75, 130, 182, 186
Della system of faults, features of. .-..-.---------- 146-147

iDYeVllbey (SY, veabaKey BENE UN IS TMS, ie agains eee aseena=ns0 190
features of -.-..-.-.---- -. 189-192
nature of ores of See eee ol 192:
occurnencelomorennes--esease= === sna -- 190-191

Della S. Mining Company, litigation by---..-.--..-- XXIV

Millers dt Ss icltedieecsesn rena = eee ena eee ee 27

Diorite-porphyry, occurrence, character, and source

OL ae are Seno oN Une soe Qos eeeerees sete O48

Dixon shabty teauuresl Olas =a ses aeeee eae eee 1

258 INDEX
Page. Page.
Dolomite nae Ol sansa ence ental seein eee ees 10-11 | Gray copper of miners, character of-.-......--...-.- 224.
analyses Obj sed eca cetes 22 see cose eee 25-26,210 | Great Western tunnel, features of 160
calcium and magnesium oxides in-_-....--..--..- 25 | Gunnison formation, position and character of..--. 39-41

chert nodulesin..--...---.-.-----
conditions of deposition of--......-.---.--.-------
Apure SHOWING 2-2. s2e- ee eee eee nee
figure showing nodule of

figure showing zones of reduction in ._..___--.-- 18
origin and character of..-.-...-_-..- 9-13, 22-28, 208-211
SandStonenvel ng aieese a esee ease eee 26-28
(Gandy) occurrencelofessnes =e eeee eee eens 7-8
thickness: of,*-Jcgo255-so nee tee feicenee Ree scan feeeere 10

28

Dolomitice quartzite, age of 8
OCCULrTENCO! Of tee sedeswseniseec ee foceameeseeesees 5-6, 8

thickness of
Dolomization, agents of

detailed description of-.--.---.-.-.--.--------- 206-216
Dubuque tunnel, features of _.._.--_.-.-._---__-..--- 204
Durant mine, features of._...-......--.----------- 152-155
Durant mining claim, litigation by -----..-. XxXIII-XxIVv
Durant tunnel, features of ---.-.......-..----------- 158

E.

East Aspen Mountain fault, features of__....__.--- 69

Edison No.1 shaft, features of ............-------- 174-175

Hldnide ey Grape cite dessa 7, 20, 23, 34, 37, 40

Elk Mountain region, topography of -.---.-- XVII-XVIII

Emma fault, features of -_.....---....--..--... 181-182, 186

Emmons, S. F., cited .....--.-.---..-._- 8, 10, 20, 22, 32, 34, 53
introduction by XVII-XXXII
letter of transmittal by ..........-..-.----.------ XIIT

Enterprise tunnel, features of_...........------------ 159

Erosion, character and amount of........---.--.-. 243-244

F.

Faulting, Aspen district. .--..---.--..-.------------ 145-146
Aspen Mountain i
Hunter Park district -.--.-.-....-...----------. 128-130
Menad olanrewet was ese os a ane ee ee 120-125
present
Tourtelotte Park area__-----_--.--_..______. 84-107, 117

Waullts, Apel tte ease te OS mwa a 100-105
character and measurement of -_-
present movement along-_.....-.....-.---..--_- 148-149
topographic effect of .-.....--..-.---...---------. 244.

Ferration, detailed description of
Folding, Aspen Mountain __...__.........-------.---—
EuntenParkagistricteee spec e cease eases

Menadoiareatace te ate ee eee eee ecen ee ee ates 117-120
Fossil changed to native silver, figure showing.____ 233
Fractures in granitic quartz.....--....--....--.----- 229)

G.
Galena tunnel, features of _.._....-...-------.----- 160-161
Gangue minerals, character of --..-..--....---.--- 225-226

Gibson fault, features of 181
Girty, G. H., quoted on fossils of Parting Quartzite. 21

Glaciation; descmipbionto fesse aeae eee 244-250)
Glauconitic grit, occurrence of .-..-.-.___._-__-______ 6-7
Glenwood Springs, Colo., analysis of waterfrom_._ 213

Wolomizationyate sess nets see ae ae ee eee 212-216
Good Thunder mine, features of __ 175
Granites chanacter Ole masse sesame 13

OTIS INO LS ees a cee eee ee et eee EN 4
Granitic quartz, microscopic fractures in_-
Gray Carbonate tunnel, course of

Gypsum, analysis of
formation of £:-------------

H.
Hannibal shaft, features of-......-.---....----.------ 178
Harkness, Robert, cited__....--..-.--- -- 11,208
Hidd2n Treasure shaft, features of _-- = i)
Highland Light shaft, course of __._- mee lr
Homestake shaft, features of ._- . 158, 167
Hunt, T. Sterry, cited__..__-_.__ 207
Hunter Creek glacier, description of -...----..--.--- 249

Hunter Park district, description of sections taken

Lal bins iy 2. saat ease eecaaee ees
features of -

Rio} Co bbay =p eem ee noc Seo Sate ea eee Soe bey
TesimMelot structure nee ye ee 130-131
Hunter Park special map, description of features
show Ones 3) Sere errant eee 126-182
description of sections shown on 131-132

I.

Ice movement, direction of
Ice sheet, dimensions of
intrusive rocks; areiof sa - see eee eee eee ee

description of -.-.....-....-
Iowa Chief mine, features of

Towa fault, features of ----- 22 e-o- nc ceepne ceonne eee
J.
dasperoid, definition of_--...-----..-..-..---------- 219-220
Jay Gould mine, features of - 1i8
Justice fault, features of. ---.--.--2-..2-_---.-e- nn. 94-95
J ustice mine, features of ............-_.----------- 175-176
L.
Laramie formation, position, character, and thick-
ness of

Last Dollar mine, features of__.___-
Late Acquisition mine, features of -
Leaching of rocks, deseription of _____
Leadville dolomite, calcium oxide in --_-
CharacteroOfs2 2.0.25 sao eee een
chemical composition of ----.
chert nodules and bands in---_.-.
magnesium oxide in-__...-____
OnifiniOfaese ees ae ane
sandstone veins in-.-
WOLEaAY UENO WS TN ceocaanbeceonoeccs Senenoe & oe
Leadville limestone, position and character of ._-... 22
Leadville mine, description of ..-.-_-.---...------- 201-202

Lenado, analyses of limestones from_.___.-...._...-- 242
aU GIN Ola tie aeeec eee eee eae eee -- 120-125
foldingiat= 2.2: acseess eee caer eee --- 117-121
mines and workings at and near_--. --- 199-203
résumé of geology of district near -- --- 202-203

Lenado fault, features of __......-.--_._....-------- 128-130

Lenado special map, description of sections shown

eee RR ERE rE Boon aHBee eens am con ssaccc cate 125-126
features shown on--- enc pata ee 117-126
Limestone, analyses of_.-.-...-------------._.- 214, 215, 242

Limestone above Leadville dolomite, character,
Tossils yan dice clo heen ae eee eee 28-30

INDEX. 259

Page. Page.

Lithographic dolomite, character of--......--------- 15-16 | Penfield, S. L., chemical analyses by-----..-------- 224, 225
Litigation, history of---------------- XxXI-xxv | Pioneer tunnel, features of__-..-.--- = 10)
Little Annie mine, description of.---..-.------------ ZODn EOlybasitesanalySesOl sass ese eee ne eee eae raeeane 225
Little Cloud tunnel, features of__-------.------------ 166 | Porphyry dikes, occurrence of---..--.--.------------ 47

Little Lottie mine, features of --
Little Percy mine, features of-.-.---.------------- 168-169

Little Rule tunnel, features of -----..---------------- Viz
Long John shaft, features of-.--..--.----------------- 178
M.

Magnesia sulphate, deposits of--....--.---- tie Sees 239

Magnesium oxide in Leadville dolomite, occur-

MON CO Ofswacse aor ceiee sone eo oae a= see nas eeesan
Manganese, deposits of_-.--...------------------------
Maroon beds, conditions of deposition of

Maroon dolomite, character of ...._..----------------

Maroon formation, position and character of------- 33-37
Marvine, A. R., cited 39
Mary B. fault, features of -_.....--.-.---.-.---------- 69-70
Mary B. mine, features of--......---..------------- 166-167

Mayflower tunnel, features of-

Metals, original source of__._..---.----...---------

Mineral Farm mine, description of .--.-----..--------

Mineralization, agents of
ON@ LOGS) O bees eee te se eine oleae

Minerals lis tho fepesse esse ase eseae teen ae ee

Mines and productive localities, descriptions of-- 151-205

Mining suits, history of...----..-.-------------- XXII-XXV

Minnie Moore mine, features of-.-.--.-------------

Mollie Gibson mine, description of --
diagram showing ore body of--..-------..--------

diagrams showing successive stages of faulting
UTS eee ee esate «Getta Sete aataaeres 199
mode of occurrence of ore in-_--.-------------- 184-185
summary of geology of.-----.------------------- 187-188
Montana formation, character and fossils of ----..-- 42-43,
N.
New York tunnel, features of -----..--..------------ 160
Niobrara limestone, position, thickness, and char-
EICUEDP Ose ae cam nas cone See OC EERE SSO CACO DSRS 41-42
oO.
OK: mine} features of-----.--- 2-22 enna ne eenn nnn
Ontario fault, features of 5
Ore deposition, detailed description of. -..--..---- 224-236
OxLentio lp sees e a eaten as lo eee eee eee 231-232
influence of different rocks on.----.-.--------- 232-233
Woes) Os acca ssc case neeeats 0 oc aa CoS aSnSonaaabeso
Ores, cause of precipitation of
changesyine eae nee nea canes

chemical composition of--..-------.---.----
OIG AIONN OLE eee ane mene e ene e ee eee

Te,
Paragenesis of vein materials, discussion of ------ 221-229
Park-Regent mine, description of -.--.-.------.--- 194-196,

OCCULLENCC OL OLe nis sss ae se ae ee
Parting Quartzite series, age of -
character and occurrence of -.-.---.-------------
conditions of deposition of --.-..----..-----------
section of

13-14

Peale, A. C., cited 7,10, 34
Pearce, S. H., chemical analysis by 225
CLL Cees eee te eat ee os seen eee ne we ee eee 239

Precipitation of ores, cause of --
Pride fault, description of

Pride of Aspen mine, features of _----..--.-.---.---- 165
Princess Louise shaft, features of .......-.------.--- 160
Q.

Quartzite (dolomitic), age of -.....-.----------------- 8
occurrence of 5-6
thicknessiofjessa e222 Sess s2e eee tes ee eee eee 8

Quartz-porphyry, character, occurrence, and source f

OE se ae Gane nee Moe na SE HO eee Pet 48-53
Queen’s Gulch, mines and workings in-......-...- 203-205
R.

Red Mountain, description of --....-----.---------.--

Red sandstones, character of---

conditions of deposition of .--.-.--.-
Red Spruce shaft, features of
Regent fault, features of
Roaring Fork glacier, description of
Roaring Fork River, course of
Rohlfing, D., acknowledgments to XVI
Royalties paid by mine lessees, table showing. --. XXVIII

Ruby mine, features of_-_-_.-.------.--..------------ 168
Ss.

Saddle Rock fault, description of ....--..--....------ 62-63

foatures of ---..--.---.-------- -- 93-94
Saddle Rock shaft, features of- -- 171-172
Sam Houston shaft, features of _. 171
Sandberger, F.., cited_-----.----.---.- 236
Sandstone (red), character and age of- ---- 37-38

conditions of deposition of .__.-.-._____..-- =. 38-39
Sandstone veins in dolomite, occurrence of--- 26-28
San Jacinto shaft, features of ....---.-..------------- 171
Sarah Jane fault, description of--_-...._-.-.---.--__-- 63-64

features Ole ss Stenson eee eee 94,177
Schillerfaultsteatures Ofses nesses eee nee 64-65
Schiller mine, features of----------..---....--------- 157

Schmidt, Adolph, cited 211

Sections shown on atlas sheets, description of 79-82,

108-117, 162-164, 125-126, 131-182, 137-143
240,

Selenite, formation of .*_-.--. -<-.-- -- 22 eo enee one ===
Silicification, detailed description of
Silurian beds, character of_-_-.-..-.-------..__--.___.-
Silver (native), formation of -
Silver fault, features of .-_..-......... 71-72, 74, 120-122, 128
Silver fault system, features of_.-.-.---- 88-89, 106, 144-145
Smuggler fault, features of

Smuggler mine, description of_---.-.--..--..-.---- 185-187

diagram showing ore body of.--.-.-----. -------- 183
liagram showing successive stages of faulting
ed Tn A ae eee eater a te A eee reece ON 199
MabUTOlohOres|OLas-s ee eee eee eee een 186-187
OCCULTENCEIOh OLS Mens ese es nae eee 187
summary of geology of_-..-..-.--.----.-------- 187-188
Smuggler Mountain, description of --.__.--.-.-_..-. 74-78
description of section across._-.---------.----.-- 79-80
mines and workings in -.....---------..-.------ 180-197
TEsumMé) oLse colon yaOleesesseeeee eee bene eee eee 198-199

TESUME|OMS PLU CLULO) Oleeees eee ee sete ae ae eee 17-78

260 INDEX.
Page. (Di,
Smuggler Mountain mining map, features shown Uasonror uly Orseacsone mentee Page.
OUNS a ON a se ne aren a Ree ete a 197-198 Ur F = - 44-45
Sorby nb Oi cited 2.5 2 onan eee ae 12 pre-Cretaceous ---.-.------------ 45-4
Spar mine, mining suits of -_..--..-.----------- xxm-_xxry | Upham, Warren, cited --.....--.---.-----------+------ 149
Standard Mining Company, litigation by ---------- XXIV Vv.
os eeape F 23¢
Sinllaeie oe magnesia Glsjawsntis Hes soses seen seo eses eu Vein materials paragenesis of 227-229
Sulphur, deposits of---------- --. ~~ =e 239 4 PAs
: an,
< F Walcott; Cy Dr cited. ccc cec ces cet eoe eee eens 8, 22
erat é aes oe NCRED CAI UROL Se ats es quoted on Devonian bedsof Kanab Valley, Utah. 21
Se eee ee ee oe siguR NL ~ | Washington claim, mining suit of__..-.---.-- XXII-XXIV
Tourtelotte Park area, age of faults in--....------ 100-105 s yi 5

descriptions of sections in
mines and working sin 2226-2. 2. cee nce eee eee eee
post-Glacial movement in

résumé of faulting in-...-.- sz Lily
résumé of structure in_--._-.-..--.------------ 105-107
Tourtelotte Park mining map, features shown
Oe 179-180
Tourtelotte Park special map, features shown on_- 84-117
Tourtelotte Park uplift, features of---....---------- 145
Triassic formations, description of-.-......---... eos Sreil

o)

Weber formation, analyses of limestones from 242

character of sas
conditions of deposition of
thickness! of 2-232 -soss ibe ee eee
Weber limestone, figure showing fractures in

145

West Aspen Mountain, description of features of. 165-167

Worm tracks in dolomite, occurrence of.--.-------- 28
aYe

Yampa Spring, analyses of water from____-____---.- 213

Yopsie tunnel, features of......... weno sees wanes oo Bx

ADV ERTISHMENT.

[Monograph XXXI.]

The statute approved March 3, 1879, establishing the United States Geological Survey, contains
the following provisions:

“The publications of the Geological Survey shall consist of the annual report of operations, geo-
logical and economic maps illustrating the resources and classification of the lands, and reports upon
general and economic geology and paleontology. The annual report of operations of the Geological
Survey shall accompany the annual report of the Secretary of the Interior. All special memoirs and
reports of said Survey shall be issued in uniform quarto series if deemed necessary by the Director, but
otherwise in ordinary octayos. Three thousand copies of each shall be published for scientific exchanges
and for sale at the price of publication; and all literary and cartographic materials received in exchange
shall be the property of the United States and form a part of the library of the organization: And the
money resulting from the sale of such publications shall be covered into the Treasury of the United
States.”

Except in those cases in which an extra number of any special memoir or report has been sup-
plied to the Survey by special resolution of Congress or has been ordered by the Secretary of the
Interior, this office has no copies for gratuitous distribution.

ANNUAL REPORTS.

J. First Annual Report of the United States Geological Survey, by Clarence King. 1880. 8°. 79
pp. 1map.—A preliminary report describing plan of organization and publications. —

II. Second Annual Report of the United States Geological Survey, 1880-81, by J. W. Powell.
1882. 8°. lv, 588 pp. 62 pl. 1 map.

Ill. Third Annual Report of the United States Geological Survey, 188182, by J. W. Powell.
1883. 8°. xviii, 564 pp. 67 pl. and maps.

IV. Fourth Annual Report of the United States Geological Survey, 1882~’83, by J. W. Powell.
1884. 8°. xxxii,473 pp. 85 pl. and maps.

VY, Fifth Annual Report of the United States Geological Survey, 1883-84, by J. W. Powell.
1885. 8°. xxxvi,469 pp. 58 pl. and maps.

VI. Sixth Annual Report of the United States Geological Survey, 188485, by J. W. Powell.
1885. 8°. xxix, 570 pp. 65 pl. and maps.

VII. Seventh Annual Report of the United States Geological Survey, 1885-86, by J. W, Powell.
1888. 8°. xx,656 pp. 71 pl. and maps.

VIII. Eighth Annual Report of the United States Geological Survey, 1886-87, by J. W. Powell.
1889. 8°. 2pt. xix, 474, xii pp., 53 pl. and maps; 1 prel: leaf, 475-1063 pp., 54-76 pl. and maps.

TX. Ninth Annual Report of the United States Geological Survey, 1887~88, by J. W. Powell.
1889. 8°. xiii,717 pp. 88 pl. and maps.

X. Tenth Annual Report of the United States Geological Survey, 1888~’89, by J. W. Powell.
1890. 8°. 2pt. xv, 774 pp., 98 pl. and maps; viii, 123 pp.

XI. Eleventh Annual Report of the United States Geological Survey, 1889-90, by J. W. Powell.
1891. 8°. 2pt. xv, 757 pp., 66 pl. and maps; ix, 351 pp., 30 pl. and maps.

XII. Twelfth Annual Report of the United States Geological Survey, 1890-91, by J. W. Powell.
1891. 8°. 2pt., xiii, 675 pp., 53 pl. and maps; xviii, 576 pp., 146 pl. and maps.

XIII. Thirteenth Annual Report of the United States Geological Survey, 1891-92, by J. W.
Powell. 1893. 8°. 3 pt. vii, 240 pp., 2 maps; x, 372 pp., 105 pl. and maps; xi, 486 pp., 77 pl. and
maps.

2 XIV. Fourteenth Annual Report of the United States Geological Survey, 1892-93, by J. W.
Powell. 1893. 8°. 2pt. vi, 321 pp., 1 pl.; xx, 597 pp., 74 pl. and maps.

XV. Fifteenth Annual Report of the United States Geological Survey, 189394, by J. W. Powell.
1895. 8°. xiv, 755 pp., 48 pl. and maps.

XVI. Sixteenth Annual Report of the United States Geological Survey, 1894~95, Charles D.
Walcott, Director. 1895. (Part I, 1896.) 8°. 4 pt. xxii, 910 pp., 117 pl. and maps; xix, 598 pp., 43
pl. and maps; xv, 646 pp-, 23 pl.; xix, 735 pp., 6 pl.

XVII. Seventeenth Annual Report of the United States Geological Survey, 1895~96, Charles
D. Walcott, Director. 1896. 8°. 3 pt. in4 vol. xxii, 1076 pp.; 67 pl. and maps; xxv, 864 pp., 113 pl.
and inaps; xxiii, 542 pp., 8 pl. and maps; iii, 543-1058 pp., 9-13 pl.

XVIII. Kighteenth Annual Report of the United States Geological Survey, 1896~97, Charles D.
Walcott, Director. 1897, (Parts II and III, 1898.) 8°. 5 pt.in6vol. 1-440 pp.,4 pl. and maps; i-y,

I

II ADVERTISEMENT.

1-653 pp., 105 pl. and maps; i-v, 1-861 pp., 118 pl. and maps; i-x, 1-756 pp., 102 pl. and maps; i-xii,
1-642 pp., 1 pl.; 643-1400 pp.

XIX. Nineteenth Aniual Report of the United States Geological Survey, 1897-98, Charles D.
Walcott, Director. 1898. 8°. 6 pt. in 7 vol.

MONOGRAPHS.

I. Lake Bonneville, by Grove Karl Gilbert. 1890. 4°. xx,438 pp. 51pl. lmap. Price $1.50.

II. Tertiary History ofthe Grand Canon District, with Atlas, by Clarence KE. Dutton, Capt., U.S. A.
1882. 4°. xiv, 264 pp. 42 pl. and atlas of 24 sheets folio. Price $10.00.

Ii. Geology of the Comstock Lode and the Washoe District, with Atlas, hy George F. Becker
1882. 4°. xy, 422 pp. 7 pl. and atlas of 21 sheets folio. Price $11. ‘00.

IV. Comstock Mining and Miners, by Eliot Lord. 1883. 4°. xiv, 451pp. 3pl. Price $1.50.

V. The Copper- Bearing Rocks of Lake Superior, hy Roland Duer Irving. 1883. 4°. xvi, 464
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VI. Contributions to the Knowledge of the Older Mesozoic Flora of Virginia, by William Morris
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VII. Silver-Lead Deposits of Eureka, Nevada, by Joseph Story Curtis. 1884. 4°. xiii, 200 pp.
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VIIT. Paleontology of the Eureka District, by Charles Doolittle Walcott. 1884. 4°. xiii, 298
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IX. Brachiopoda and Lamellibranchiata of the Raritan Clays and Greensand Marls of New
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X. Dinocerata. A Monograph of an Extinct Order of Gigantic Mammals, by Othniel Charles
Marsh. 1886. 4°. xviii, 243 pp. 561. S56 pl. Price $2.70.

XI. Geological History of Lake Lahontan, a Quaternary Lake of Northwestern Nevada, by
Israel Cook Russell. 1885. 4°. xiv, 288 pp. 46 pl. and maps. Price $1.75.

XII. Geology and Mining Industry of Leadville, Colorado, with Atlas, by Samuel Franklin
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XIII. Geology of the Quicksilver Deposits of the Pacific Slope, with Atlas, by George F. Becker.
1888. 4°. xix, 486 pp. 7pl. and atlas of 14 sheets folio. Price $2.00.

XIV. Fossil Fishes and Fossil Plants of the Triassic Rocks of New Jersey and the Connecticut
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XV. The Potomac or Younger Mesozoic Flora, by William Morris Fontaine. 1889. 4°. xiv,
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XVI. The Paleozoic Fishes of North America, by John Strong Newberry. 1889. 4°. 340 pp.
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XVII. The Flora of the Dakota Group, a Posthumous Work, by Leo Lesquereux. Edited by
F. H. Knowlton. 1891. 4°. 400 pp. 66pl. Price $1.10.

XVIII. Gasteropoda and Cephalopoda of the Raritan Clays and Greensand Marls of New Jersey,
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XIX. The Penokee Iron-Bearing Series of Northern Wisconsin and Michigan, by Roland D.
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SOX, Geology of the Hareka District, Nevada, with an GER) by Arnold Hague. 1892. 4°. xvii,
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XXI. The Tertiary Rhynchophorous Coleoptera of the United States, by Samuel Hubbard Scud-
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XXIL A Manual of Topographic Methods, by Henry Gannett, Chief Topographer. 1893. 49.
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XXIII. Geology of the Green Mountains in Massachusetts, by Raphael Pumpelly, T Nelson Dale,
and J. E. Wolff. 1894. 4°. xiv, 206 pp. 23 pl. Price $1.30.

XXIV. Mollusca and Crustacea of the Miocene Formations of New Jersey, by Robert Parr Whit-
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XXV. The Glacial Lake Agassiz, by Warren Upham. 1895. 4°. xxiy,658 pp. 38pl. Price $1.70.

XXVI. Flora of the Amboy Clays, by John Strong Newberry; a P sthumous Work, edited by
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XXVII. Geology of the Denver Basin in Colorado, by Samuel Franklin Emmons, Whitman Cross,
and George Homans Eldridge. 1896. 4°. 556 pp. 31 vl Price $1.50.

XXVIII. The ] Marquette Iron-Bearing District of Michigan, with Atlas, by C. R. Van Hise and
W.S. Bayley, including a Chapter on the Republic Trough, by H. L. Smyth. 1895. 4°. 608 pp. 35
pl. and atlas of 39 sheets folio. Price $5.75.

XXIX. Geology of Old Hampshire County, Massachusetts, comprising I'ranklin, Hampshire, and
Hampden Counties, by Benjamin Kendall Emerson. 1898. 4°. xxi, 790 pp. 35 pl. Price $1.90.

XXX. Fossil Meduse, by Charles Doolittle Walcott. 1898. 40, ix,201pp. 47pl. Price $1.50.

XXXI. Geology of the Aspen Mining District, Colorado, with Atlas, by Josiah Edward Spurr.
1898. 4°. xxxv, 260 pp. 43 pl. and atlas of 30 sheets folio. Price $3.60.

XXXV. The Later Extinct Floras of North America, by John Strong Newberry; edited by
Arthur Hollick. 1898. 4°. xviii, 295 pp. 68pl. Price $1.25.

In press:

XXXII. Geology of the Yellowstone National Park, Part II, Descriptive Geology, Petrography,
and Paleontology. by. Arnold Hague, J. P. Iddings, W. Harvey Weed, Charles D. Walcott, G. H. Girty,
T. W. Stanton, “and F. H. Knowlton.

ADVERTISEMENT. Ill

In preparation:

XXXIII. Geology of the Narragansett Basin, by N. 8. Shaler, J. B. Woodworth, and August F.
Foerste.

XXXIV. The Glacial Gravels of Maine and their Associated Deposits, by George H. Stone.

XXXVI. The Crystal Falls Iron-Bearing District of Michigan, by J. Morgan Clements and
Henry Lloyd Smyth; with a Chapter on the Sturgeon River Tongue, by William Shirley Bayley.

XXXVII. Flora of the Lower Coal Measures of Missouri, by David White.

XXXVIII. The Illinois Glacial Lobe, by Frank Leverett.

—Sauropoda, by O. C. Marsh.

—Stegosauria, by O. C. Marsh.

—Brontotheriide, by O. C. Marsh.

—Flora of the Laramie and Allied Formations, by Frank Hall Knowlton.

BULLETINS.

1. On Hypersthene-Andesite and on Triclinic Pyroxene in Augitic Rocks, by Whitman Cross.
with a Geological Sketch of Buffalo Peaks, Colorado, by S. F. Emmons. 1883. 8°. 42 pp. 2 pl,
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2. Gold and Silver Conversion Tables, giving the Coining Values of Troy Ounces of Fine Metal,
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3. On the Fossil Faunas of the Upper Devonian, along the Meridian of 76° 30’, from Tompkins
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4. On Mesozoic Fossils, by Charles A. White. 1884. 8°. 36 pp. 9pl. Price 5 cents.

5. A Dictionary of Altitudes in the United States, compiled by Henry Gannett. 1884. 8°. 325
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6. Elevations in the Dominion of Canada, by J. W.Spencer. 1884. 8°. 43 pp. Price 5 cents.

7. Mapoteca Geologica Americana. <A Catalogue of Geological Maps of America (North and
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8. On Secondary Enlargements of Mineral Fragments in Certain Rocks, by R. D. Irving and
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9. A Report of Work done in the Washington Laboratory during the Fiscal Year 1883~84. F.W.
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10. On the Cambrian Faunas of North America. Preliminary Studies, by Charles Doolittle
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11. On the Quaternary and Recent Mollusca of the Great Basin; with Description of New
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12. A Crystallographic Study of the Thinolite of Lake Lahontan, by Edward S.Dana. 1884. 8°.
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13. Boundaries of the United States and of the Several States and Territories, with a Historical
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14. The Electrical and Magnetic Properties of the Iron-Carburets, by Carl Barus and Vincent
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15. On the Mesozoic and Cenozoic Paleontology of California, by Charles A. White. 1885. 89°.
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16. On the Higher Deyonian Faunas of Ontario County, New York, by John M.Clarke. 1885. 89.
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‘17. On the Development of Crystallization in the Igneous Rocks of Washoe, Nevada, with Notes
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18. On Marine Eocene, Fresh-Water Miocene, and other Fossil Mollusca of Western North
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20. Contributions to the Mineralogy of the Rocky Mountains, by Whitman Cross and W. F. Hille-
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33. Observations on the Junction between the Eastern Sandstone and the Keweenaw Series on
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24. List of Marine Mollusca, comprising the Quaternary Fossils and Recent Forms from American
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. The Present Technical Condition of the Steel Industry of the United States, by Phineas
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27. Report of W: ork ¢ done i in the Division of Chemistry and Physics, mainly during the Fiseal Year
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28. The Gabbros and Associated Hornblende Rocks occurring in the Neighborhood of Baltimore,
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IV ADVERTISEMENT.

29. On the Fresh-Water Invertebrates of the North American Jurassic, by Charles A. White. 1886.
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30. Second Contribution to the Studies on the Cambrian Faunas of North America, by Charles
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32. Lists and Analyses of the Mineral Springs of the United States; a Preliminary Study, by
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35. Physical Properties of the Iron-Carburets, by Carl Barus and Vincent Strouhal. 1886. 8°.
62 pp. Price 10 cents. -

36. Subsidence of FineSolid Particlesin Liquids, by CarlBarus. 1886. 8°. 58pp. Price10cents.

37. Types of the Laramie Flora, by Lester F. Ward. 1887. 8°. 354pp. 57pl. Price 25 cents.

38. Peridotite of Elliott County, Kentucky, by J.S. Diller. 1887. 8°. 31pp. 1pl. Price5cents.

39. The Upper Beaches and Deltas of the Glacial Lake Agassiz, by Warren Upham. 1887, 8°.
84 pp. Ipl. Price 10 cents.

40. Changes in River Courses in Washington Territory due to Glaciation, by Bailey Willis. 1887.
8°. 10pp. 4pl._ Price 5 cents.

41. On the Fossil Faunas of the Upper Devonian—the Genesee Section, New York, by Henry S.
Williams. 1887. 8°. 121 pp. 4pl. Price 15 cents.

42. Reportof Work done in the Division of Chemistry and Physics, mainly during the Fiscal Year
1885~86. F.W. Clarke, Chief Chemist. 1887. 8°. 152pp. 1pl. Price 15 cents.

43. Tertiary and Cretaceous Strata of the Tuscaloosa, Tombigbee, and Alabama Rivers, by Eugene
A. Smith and Lawrence C. Johnson. 1887. 8°. 189pp. 21pl. Price 15 cents.

44. Bibliography of North American Geology for 1886, by Nelson H. Darton. 1887. 8°. 35 pp.
Price 5 cents.

45. The Present Condition of Knowledge of the Geology of Texas, by Robert T. Hill. 1887. 8°.
94 pp. Price 10 cents.

46. Nature and Origin of Deposits of Phosphate of Lime, by R. A. F. Penrose, jr., with an Intro-
duction by N.S. Shaler. 1888. 8°. 143 pp. Price 15 cents.

47. Analyses of Waters of the Yellowstone National Park, with an Account of the Methods of
Analysis employed, by Frank Austin Gooch and James Edward Whitfield. 1888. 8°. 84 pp. -Price
10 cents.

48. On the Form and Position of the Sea Level, by Robert Simpson Woodward. 1888. 8°. 88
pp. Price 10 cents.

49. Latitudes and Longitudes of Certain Points in Missouri, Kansas, and New Mexico, by Robert
Simpson Woodward. 1889. 8°. 1383 pp. Price 15 cents.

50. Formulas and Tables to Facilitate the Construction and Use of Maps, by Robert Simpson
Woodward. 1889. 8°. 124pp. Price 15 cents.

51. On Invertebrate Fossils from the Pacific Coast, by Charles Abiathar White. 1889. 8°. 102
pp. 14pl. Price 15 cents.

52. Subaérial Decay of Rocks and Origin of the Red Color of Certain Formations, by Israel
Cook Russell. 1889. 8°. 65pp. 5pl. Price 10 cents.

53. The Geology of Nantucket, by Nathaniel Southgate Shaler. 1889. 8°. 55 pp. 10pl. Price
10 cents.

54, On the Thermo-Electric Measurement of High Temperatures, by Carl Barus. 1889. 8°.
313 pp.,incl.1 pl. J1pl. Price 25 cents.

55. Report of Work done in the Division of Chemistry and Physics, mainly during the Fiscal
Year 1886~87. Frank Wigglesworth Clarke, Chief Chemist. 1889. 8°. 96pp. Price 10 cents.

56. Fossil Wood and Lignite of the Potomac Formation, by Frank Hall Knowlton. 1889. 8°.
72 pp. Tpl. Price 10 cents.

57. A Geological Reconnoissance in Southwestern Kansas, by Robert Hay. 1890. 8°. 49 pp.
2pl. Price 5 cents.

58. The Glacial Boundary in Western Pennsylvania, Ohio, Kentucky, Indiana, and Illinois, by
George Frederick Wright, with an Introduction by Thomas Chrowder Chamberlin. 1890. 8°. 112
pp.,inel.l pl. 8pl. Price 15 cents.

59. The Gabbros and Associated Rocks in Delaware, by Frederick D. Chester. 1890. 8°. 45
pp. lpl. Price 10 cents.

60. Report of Work done in the Division of Chemistry and Physics, mainly during the Fiscal
Year 1887-88. F. W. Clarke, Chief Chemist. 1890. 8°. 174 pp. Price 15 cents.

61. Contributions to the Mineralogy of the Pacific Coast, by William Harlow Melville and Wal-
demar Lindgren. 1890. 8°. 40 pp. 3pl. Price 5 cents.

62. The Greenstone Schist Areas of the Menominee and Marquette Regions of Michigan, a Con-
tribution to the Subject of Dynamic Metamorphism in Eruptive Rocks, by George Huntington Williams,
with an Introduction by Roland Duer Irving. 1890. 8°. 241 pp. 16 pl. Price 30 cents.

63. A Bibliography of Paleozoic Crustacea from 1698 to 1889, including a List of North Amer-
ican Species and a Systematic Arrangement of Genera, by Anthony W. Vogdes. 1890. 8°. 177 pp.
Price 15 cents.

64. A Report of Work done in the Division of Chemistry and Physics, mainly during the Fiscal
Year 1888-89. F. W. Clarke, Chief Chemist. 1890. 8°. 60 pp. Price 10 cents.

a a ae

ADVERTISEMENT. 2 V

65. Stratigraphy of the Bituminous Coal Field of Pennsylvania, Ohio, and West Virginia, by
Israel C. White. 1891. 8°. 212pp. l1pl. Price 20 cents.

66. On a Group of Volcanic Rocks from the Tewan Mountains, New Mexico, and on the Occur-
rence of Primary Quartz in Certain Basalts, by Joseph Paxson Iddings. 1890. 8°. 34 pp. Price 5
cents.

67. The Relations of the Traps of the Newark System in the New Jersey Region, by Nelson
Horatio Darton. 1890. 8°. 82pp. Price 10 cents.

68. Karthquakes in California in 1889, by James Edward Keeler. 1890. 8°. 25 pp. Price5
cents.

69. A Classed and Annotated Biography of Fossil Insects, by Samuel Howard Scudder. 1890.
8°. 101 pp _ Price 15 cents.

70. A Report on Astronomical Work of 1889 and 1890, by Robert Simpson Woodward. 1890. 8°.
79 pp. Price 10 cents.

71. Index to the Known Fossil Insects of the World, including Myriapods and Arachnids, by
Samuel Hubbard Scudder. 1891. 8°. 744 pp. Price 50 cents.

72. Altitudes between Lake Superior and the Rocky Mountains, by Warren Upham. 1891. 8°.
229 pp. Price 20 cents.

73. The Viscosity of Solids, by Carl Barus. 1891. 8°. xii, 139 pp. 6 pl. Price 15 cents.

74. The Minerals of North Carolina, by Frederick Augustus Genth. 1891. 8°. 119 pp. Price
15 cents.

75. Record of North American Geology for 1887 to 1889, inclusive, by Nelson Horatio Darton.
1891. 8°. 173 pp. Price 15 cents.

76. A Dictionary of Altitudes in the United States (Second Edition), compiled by Henry Gannett,
Chief Topographer. 1891. 8°. 393 pp. Price 25 cents.

77. The Texan Permian and its Mesozoic Types of Fossils, by Charles A. White. 1891. 8°. 51
pp. 4pl. Price 10 cents. =

78. A Report of Work done in the Division of Chemistry and Physics, mainly during the Fiscal
Year 1889~90. F. W. Clarke, Chief Chemist. 1891. 8°. 131 pp. Price 15 cents.

79. A Late Voleanic Eruption in Northern California and its Peculiar Lava, by J. S. Diller.

80. Correlation Papers—Devonian and Carboniferous, by Henry Shaler Williams. 1891. 8°.
279 pp. Price 20 cents.

81. Correlation Papers—Cambrian, by Charles Doolittle Walcott. 1891. 8°. 547 pp. 3 pl.
Price 25 cents.

82. Correlation Papers—Cretaceous, by Charles A. White. 1891. 8°. 273 pp. 3pl. Price 20
cents. ; :
83. Correlation Papers—Hocene, by William Bullock Clark. 1891. 8°. 173 pp. 2pl. Price
15 cents.

84. Correlation Papers—Neocene, by W. H. Dall and G. D. Harris. 1892. 8°. 349 pp. 3 pl.
Price 25 cents. ; :

85. Correlation Papers—The Newark System, by Israel Cook Russell. 1892. 8°. 344 pp. 13 pl.
Price 25 cents.

86. Correlation Papers—Archean and Algonkian, by C.R. Van Hise. 1892. 8°. 549 pp. 12 pl.
Price 25 ceuts.

87. A Synopsis of American Fossil. Brachiopoda, including Bibliography and Synonymy, by
Charles Schuchert. 1897. 8°. 464 pp. Price 30 cents.

88. The Cretaceous Foraminitera of New Jersey, by Rufus Mather Bagg, Jr. 1898. 8°. 89 pp.
6 pl. Price 10 cents.

89. Some Lava Flows of the Western Slope of the Sierra Nevada, California, by F. Leslie
Ransome. 1898. 8°. 74 pp. i11pl. Price 15 cents.

90. A Report of Work done in the Division of Chemistry and Physics, mainly during the Fiscal
Year 189091. F. W. Clarke, Chief Chemist. 1892. 8°. 77 pp. Price 10 cents.

91. Record of North American Geology for 1890, by Nelson Horatio Darton. 1891. 8°. 88 pp.
Price 10 cents.

92. The Compressibility of Liquids, by Carl Barus. 1892. 8°. 96pp. 29 pl. Price 10 cents.

93. Some Insects of Special Interest from Florissant, Colorado, and Other Points in the Tertiaries
of Colorado and Utah, by Samuel Hubbard Sendder. 1892. 8°. 35 pp. 3pl. Price 5 cents.

94. The Mechanism of Solid Viscosity, by Carl Barus. 1892. 8°. 138 pp. Price 15 cents.

95. Earthquakes in California in 1890 and 1891, by Edward Singleton Holden. 1892. 8°, 31 pp.
Price 5 cents.

96. The Volume Thermodynamics of Liquids, by Carl Barus. 1892. 8°. 100pp. Price 10 cents.

97. The Mesozoic Echinodermata of the United States, by W.B. Clark. 1893. 8°. 207 pp. 50pl.
Price 20 cents.

98. Flora of the Outlying Carboniferous Basins of Southwestern Missouri, by David White.
1893. 8°. 139 pp. dpl. Price 15 cents.

99. Record of North American Geology for 1891, by Nelson Horatio Darton. 1892. 8°. 73 pp.
Price 10 cents. $

100. Bibliography and Index of the Publications of the U. S. Geological Survey, 1879-1892, by
Philip Creveling Warman. 1893. 8°. 495 pp. Price 25 cents.

101. Insect Fauna of the Rhode Island Coal Field, by Samuel Hubbard Scudder. 1893. 8°.
27pp. 2pl. Price 5 cents.

102. A Catalogue and Bibliography of North American Mesozoic Invertebrata, by Cornelius
Breckinridge Boyle. 1892. 8°. 315 pp. Price 25 cents.

VI ADVERTISEMENT.

103. High Temperature Work in Igneous Fusion and Ebullition, chiefly in Relation to Pressure,
by Carl Barus. 1893. 8°. 57 pp. 9 pl. Price 10 cents.

104. Glaciation of the Yellowstone Valley north of the Park, by Walter Harvey Weed. 1893. 8°.
41pp. 4pl. Price 5 cents.

105. The Laramie and the Overlying Livingstone Formation in Montana, by Walter Harvey
Weed, with Report on Flora, by Frank Hall Knowlton. 1893. 8°. 68 pp. 6pl. Price 10 cents.

106. The Colorado Formation and its Invertebrate Fauna, by T. W. Stanton. 1893. 8° 288
pp. 45pl. Price 20 cents.

107. The Trap Dikes of the Lake Champlain Region, by James Furman Kemp and Vernon
Freeman Marsters. 1893. 8°. 62pp. 4 pl. Price 10 cents.

108. A Geological Reconnoissance in Central Washington, hy Israel Cook Russell. 1893. 8.
108 pp. 12 pl. Price 15 cents.

109. The Eruptive and Sedimentary Rocks on Pigeon Point, Minnesota, and their Contact Phe-
nomena, by William Shirley Bayley. 1893. 8°. 121 pp. 16pl. Price 15 cents.

110. The Paleozoic Section in the Vicinity of Three Forks, Montana, by Albert Charles Peale.
893. 8°. 56 pp. 6 pl. Price 10 cents.

111. Geology of the Big Stone Gap Coal Fields of Virginia and Kentucky, by Marius R. Camp-
bell. 1893. 8°. 106pp. 6 pl. Price 15 cents.

112. Earthquakes in California in 1892, by Charles D. Perrine. 1893. 8°. 57 pp. Price 10 cents.

113. A Report of Work done in the Division of Chemistry during the Fiscal Years 1891-92 and
1892-93. E. W. Clarke, Chief Chemist. 1893. 8°. 115 pp. Price 15 cents.

114. Earthquakes in California in 1893, by Charles D. Perrine. 1894. 8°. 23 pp. Price 5 cents.

115. A Geographic Dictionary of Rhode Island, by Henry Gannett. 1894. 8°. 31pp. Price
5 cents. ,
116. A Geographic Dictionary of Massachusetts, by Henry Gannett. 1894. 8°. 126 pp. Price
15 cents.

117. A Geographic Dictionary of Connecticut, by Henry Gannett. 1894. 8°. 67 pp. Price 10
cents.

118. A Geographic Dictionary of New Jersey, by Henry Gannett. 1894. 8°. 131 pp. Price 15
cents.

119. A Geological Reconnoissance in Northwest Wyoming, by George Homans Eldridge. 1894.
8°. 72 pp. Price 10 cents.

120. The Devonian System of Eastern Pennyslvania and New York, by Charles S. Prosser. 1894.
8°. 8lpp. 2pl. Price 10 cents.

121. A Bibliography of North American Paleontology, by Charles Rollin Keyes. 1894. 8°, 251
pp. Price 20 cents.

122. Results of Primary Triangulation, by Henry Gannett. 1894. 8°. 412 pp. 17 pl. Price
25 cents.

123. A Dictionary of Geographic Positions, by Henry Gannett. 1895. 8°. 183 pp. 1pl. Price
15 cents.

124. Revision of North American Fossil Cockroaches, by Samuel Hubbard Scudder. 1895. 8°.
176 pp. 12pl. Price 15 cents.

125. The Constitution of the Silicates, by Frank Wigglesworth Clarke. 1895. 8°. 109 pp.
Price 15 cents.

126. A Mineralogical Lexicon of Franklin, Hampshire, and Hampden counties, Massachusetts,
by Benjamin Kendall Emerson. 1895. 8°. 180 pp. l1pl. Price 15 cents.

127. Catalogue and Index of Contributions to North American Geology, 1732-1891, by Nelson
Horatio Darton. 1896. 8°. 1045 pp. Price 60 cents.

128. The Bear River Formation and its Characteristic Fauna, by Charles A. White. 1895. 8°.
108 pp. 11pl. Price 15 cents.

129. Earthquakes in California in 1894, by Charles D. Perrine. 1895. 8°. 25pp. Price 5 cents.

130. Bibliography and Index of North American Geology, Paleontology, Petrology, and Miner-
alogy for 1892 and 1893, by Fred Boughton Weeks. 1896. 8°. 210 pp. Price 20 cents.

131. Report of Progress of the Division of Hydrography for the Calendar Years 1893 and 1894,
by Frederick Haynes New ell, Topographer in Charge. 1895. 8°. 126 pp. Price 15 cents.

132. The Disseminated Lead Ores of Southeastern Missouri, by Arthur Winslow. 1896. 8°.
31 pp. Price 5 cents.

133. Contributions to the Cretaceous Paleontology of the Pacific Coast: The Fauna of the
Knoxville Beds, by T. W. Stanton. 1895. 8°. 182pp. 20pl. Price 15 cents.

134. The Cambrian Rocks of Pennsylvania, by Charles Doolittle Walcott. 1896. 8°. 43 pp.
15 pl. Price 5 cents.

135. Bibliography and Index of North American Geology, Paleontology, Petrology, and Miner-
alogy for the Year 1894, by F. B. Weeks. 1896. 8°. 141 pp. Price 15 cents.

136. Voleanic Rocks of South Mountain, Pennsylvania, by Florence Bascom. 1896. 8°. 124 pp.
28 pl. Price 15 cents.

137. The Geology of the Fort Riley Military. Reservation and Vicinity, Kansas, by oben Hay.
1896. 8°. 35 pp. 8pl. Price 5 cents.

138. Artesian-Well Prospects in the Atlantic Coastal Plain Region, by N. H. Danita 1896. 8°.

228 pp. 19 pl. Price 20 cents.

139. Geology of the Castle Mountain Mining District, Montana, by W. H. Weed and Lh. V. Pirs-

son. 1896. 8°. 164 pp. 17 pl. Price 15 cents.

ADVERTISEMENT. vil

140. Report of Progress of the Division of Hydrography for the Calendar Year 1895, by Frederick
Haynes Newell, Hydrographer in Charge. 1896. 8°. 356 pp. Price 25 cents.

141. The Eocene Deposits of the Middle Atlantic Slope in Delaware, Maryland, and Virginia,
by William Bullock Clark. 1896. 8°. 167pp. 40pl._ Price 15 cents.

142. A Brief Contribution to the Geology and Paleontology of Northwestern Louisiana, by
T. Wayland Vaughan. 1896. 8°. 65pp. 4 pl. Price 10 cents.

143. A Bibliography of Clays and the Ceramic Arts, by John C. Branner. 1896. 8°. 114 pp.
Price 15 cents.

144. The Moraines of the Missouri Coteau and their Attendant Deposits, by James Edward Todd.
1896. 8°. 71pp. 21 pl. Price 10 cents.

145. The Potomac Formation in Virginia, by W. M. Fontaine. 1896. 8°. 149pp. 2pl. Price
15 cents.

146. Bibliography and Index of North American Geology, Paleontology, Petrology, and Miner-
alogy for the Year 1895, by F. B. Weeks. 1896. 8°. 130 pp. Price 15 cents.

147, Harthquakes in California in 1895, by Charles D. Perrine, Assistant Astronomer in Charge
of Earthquake Observations at the Lick Observatory. 1896. 8°. 23 pp. Price 5 cents.

148. Analyses of Rocks, with a Chapter ow Analytical Methods, Laboratory of the United States
Geological Survey, 1880 to 1896, by F. W. Clarke and W.F. Hillebrand. 1897. 8°. 306 pp. Price
20 cents.

149. Bibliography and Index of North American Geology, Paleontology, Petrology, and Miner-
alogy for the Year 1896, by Fred Boughton Weeks. 1897. 8°. 152 pp. Price 15 cents.

150. The Educational Series of Rock Specimens collected and distributed by the United States
Geological Survey, by Joseph Silas Diller. 1898. 8°. 398pp. 47 pl. Price 25 cents.

151. The Lower Cretaceous Gryphzas of the Texas Region, by R. T. Hill and T. Wayland
Vaughan. 1898. 8°. 139pp. 25pl. Price 15 cents. .

152. A Catalogue of the Cretaceous and Tertiary Plants of North America, by F. H. Knowlton.
1898. 8°. 247 pp. Price 20 cents.

153. A Bibliographic Index of North American Carboniferous Invertebrates, by Stuart Weller.
1898. 8°. 6538 pp. Price 35 cents.

154. A Gazetteer of Kansas, by Henry Gannett. 1898. 8°. 246 pp. 6pl. Price 20 cents.

155. Earthquakes in California in 1896 and 1897, by Charles D. Perrine, Assistant Astronomer
in Charge of Earthquake Observations at the Lick Observatory. 1898. 8°. 47 pp. Price 5 cents.

156. Bibliography and Index of North American Geology, Paleontology, Petrology, and Miner-
alogy for the Year 1897, by Fred Boughton Weeks. 1898. 8°. 130 pp. Price 15 cents.

In preparation:

157. The Gneisses, Gabbro-Schists, and Associated Rocks of Southeastern Minnesota, by C. W.
Hall.

158. The Moraines of South Dakota and their Attendant Deposits, by J. E. Todd.

159. The Geology of Hastern Berkshire County, Massachusetts, by B. Kk. Emerson.

WATER-SUPPLY AND IRRIGATION PAPERS.

By act of Congress approved June 11, 1896, the following provision was made:

“Provided, That hereafter the reports of the Geological Survey in relation to the gauging of
streams and to the methods of utilizing the water resources may be prin ed in octavo form, not to
exceed one hundred pages in length and five thousand copies in number; one thousand copies of which
shall be for the official use of the Geological Survey, one thousand five hundred copies shall be deliv-
ered to the Senate, and two thousand five hundred copies shall be delivered to the House of Repre-
sentatives, for distribution.”

Under this law the following papers have been issued :

. Pumping Water for Irrigation, by Herbert M. Wilson. 1896. 8°. 57 pp. 9 pl.

. Irrigation near Phenix, Arizona, by Arthur P. Davis. 1897. 8°. 97 pp. 31 pl.

. Sewage Irrigation, by George W. Rafter. 1897. 8°. 100pp. 4 pl.

A Reconnoissance in Southeastern Washington, by Israel Cook Russell. 1897. 8°. 96pp. 7pl.
Irrigation Practice on the Great Plains, by Elias Branson Cowgill. 1897. 8°. 39 pp. 12 pl.
Underground Waters of Southwestern Kansas, by Erasmus Haworth. 1897. 8°. 65pp. 12 pl.
. Seepage Waters of Northern Utah, by Samuel Fortier. 1897. 8°. 50pp. 3 pl.

. Windmills for Irrigation, by Edward Charles Murphy. 1897. 8°. 49pp. 8 pl.

. Irrigation near Greeley, Colorado, by David Boyd. 1897, 8°. 90 pp. 21 pl.

10. Irrigation in Mesilla Valley, New Mexico, by F. C. Barker. 1898. 8°. 5lpp. 11pl.

11. River Heights for 1896, by Arthur P. Davis. 1897. 8°. 100 pp.

12. Water Resources of Southeastern Nebraska, by Nelson H. Darton. 1898. 8°. 55 pp. 21 pl.

13. Irrigation Systems in exas, by William Ferguson Hutson. 1898. 8°. 67 pp. 10pl.

14. pay Tests of Certain Pumps and Water-Lifts used in Irrigation, by Ozni P. Hood. 1889. 8°.
91 pp. 1 pl.

- 15. Operations at River Stations, 1897, Part I. 1898. 8°. 100 pp.

16. Operations at River Stations, 1897, Part II. 1898. 8°. 101-200 pp.

17. Irrigation near Bakersfield, California, by C. E. Grunsky. 1898. 8°. 96 pp. 16 pl.

18. Irrigation near Fresno, California, by C. E. Grunsky. 1898. 8°. 94 pp. 14 pl.

COON DUF whe

VIII ADVERTISEMENT.

In preparation:
19. Irrigation near Merced, California, by C. i. Grunsky.
20. Experiments with Windmills, by T. O. Perry.
21. Wells of Indiana, by Frank Leverett.
22. Sewage Irrigation, Part Il, by George W. Rafter.
23. Water-Right Problems of Bighorn Mountains, by Elwood Mead.
24. Water Resources of the State of New York, Part I, by George W. Rafter.

TOPOGRAPHIC MAP OF THE UNITED STATES.

When, in 1882, the Geological Survey was directed by law to make a geologic map of the United
States there was in existence no suitable topographic map to serve as a base for the geologic map.
The preparation of such a topographic map was therefore immediately begun. About one-fifth of the
area of the country, excluding Alaska, has now been thus mapped, The map is published in atlas
sheets, each sheet representing a small quadrangular district, as explained under the following head-
ing. The separate sheets are sold at 5 cents each when fewer than 100 copies are purchased, but when
they are ordered in lots of 100 or more copies, whether of the same sheet or of different sheets, the
price is 2 cents each. The mapped areas are widely scattered, nearly every State being represented.
More than 800 sheets have been engraved and printed; they are tabulated by States in the Survey’s
“List of Publications,” a pamphlet which may be had on application. :

The map sheets represent a great variety of topographic features, and with the aid of descriptive
text they can be used to illustrate topographic forms. This has led to the projection of an educational
series of topographic folios, for use wherever geography is taught in high schools, academies, and
colleges. Of this series the first folio has been issued, viz:

1. Physiographic types, by Henry Gannett, 1898, folio, consisting of the following sheets and 4
pages of descriptive text: Fargo (N. Dak.-Minn.), a region in youth; Charleston (W.Va.), a region in
maturity ; Caldwell (Kans.), aregion in old age; Palmyra (Va.), a rejuvenated region; Mount Shasta,
(Cal.), a young volcanic mountain; Hagle (Wis.), moraines; Sun Prairie (Wis.), drumlins; Donald-
sonville (La.), river flood plains; Boothbay (Me.), a fiord coast; Atlantic City (N.J.), a barrier-beach

coast.
GEOLOGIC ATLAS OF THE UNITED STATES.

The Geologic Atlas of the United States is the final form of publication of the topographic and
geologic maps. The atlas is issued in parts, progressively as the surveys are extended, and is designed
ultimately to cover the entire country.

Under the plan adopted the entire area of the country is divided into small rectangular districts
(designated quadrangles), bounded by certain meridians and parallels. The unit of survey is also the
unit of publication, and the maps and descriptions of each rectangular district are issued as a folio of
the Geologic Atlas.

Each folio contains topographic, geologic, economic, and structural maps, together with textual
descriptions and explanations, and is designated by the name of a principal town or of a prominent
natural feature within the district.

Two forms of issue have been adopted, a “library edition” and a “‘field edition.” In both the
sheets are bound between heavy paper covers, but the library copies are permanently bound, while
the sheets and covers of the field copies are only temporarily wired together.

Under the law a copy of each folio is sent to certain public libraries and educational institu-
tions. The remainder are sold at 25 cents each, except such as contain an unusual amount of matter,
which are priced accordingly. Prepaymentis obligatory. The folios ready for distribution are listed
helow.

Area, in |Price,
No. Name of sheet. State. Limiting meridians. Limiting parallels. square in
miles. |cents.
1 | Livingston --.--.-------------- Montana....---- 1109-1119 45°-46° 3, 354 25
j Georgia. ..- ri 50. Oo U oO 2804 {eo}
2 | Ringgold -....-----.----------- Manncssoal 85°-85° 30 34° 30/-35' 980 25
8 | Placerville..--.----------.-.._- California. - 120° 30/-121° 380 30/-390 932 95
4 | Kingston... ....--- .--| Tennessee 84° 30/-85° 35° 30/360 969 25
5 | Sacramento----.-- -| California 1219-121° 30/ 38° 30/-39° 932 25
6 | Chattanooga..----- ---- Tennessee 85°-85° 30/ 359-35° 30/ 975 25
7 | Pikes Peak (out of stock) - .| Colorado. 1059-1059 30/ 380 30/390 | - 932 25
8 | Sewanee..--.--.-------- -| Tennessee 85° 30/-86° 359-35° 30! 975 25
9 | Anthracite-Crested Butt 4 Colorado: 106° 45/1079 15/ 380 45/390 465 50
irginia - A
10 | Harpers Perry----------------- {west Virginia -. | 77° 30/-78° 390-390 30! 925 25
Maryland.....--
Tal || URGE 5 - seconde ssoscoescecc California. ------ 120° 30/-121° 38°-38° 30/ 938 25
Virginia ...--.--
12'| Estillville --------------------- {entice Soquese 82° 80/830 36° 30/-37° 957 95
Tennessee ------
13 | Fredericksburg......--...----- Heeeoeree eee, 710-179 30! 389-380 30 938 | 25
Vivginia ..------ +
q148) |] Starvin tone eee eee tweet Vue. } 79°-79° 30! 380-38° 30! 938 | 25
15) || assentPeak:------ - es sae= = i= California-....-.- 1219-1229 400410 3, 634 25
16}| Knox villosa eee (North Garolina |} 830 30-840 a5° 30-360 | 925 | 25

ADVERTISEMENT. Ix

| | | Area, in |Price,
No. | Name of sheet. State. Limiting meridians. Limiting parallels. square in
| | | miles. jcents.
Dfe| Many Swill@es a= === California. ...-.- 121° 30/-122° 392-399 30! 925 25
18 | Smartsville ..-.------- saSossone California. 121°-121° 30/ 39°-39° 30/ 925 25
Alabama. - :
TOME Steen sO ness een eee a ae |Georai. : } 85° 30/-86° 34° 30/-35° 980 25
Tennessee -- |
20e@leveland ==ssee ssa eae Tennessee - 84° 30/-85° | © 35°-35° 30! 975 25
21 | Pikeville -- Tennessee - 85°-85° 30/ 35° 30/369 969 25
22 | MeMinnville- Tennessee -- 85° 30/-86° 35° 30'-36° 969 25
BaulNominiecetees tee eee eae nee poe 76° 30'-77° 380-389 30! 938 | 25
ode en hreesHonkShe- cane sea eee Montana. - 1119-1129 45°-46° 3, 354 50
25 | Loudon ...| Tennessee = 84°-81° 30/ 352 30/-36° 969 20.
26 | Pocal Virginia -.-.--.-| 810-810 30/ 379-379 30/ 951 25
26 ocahontas - ------------------- {west Virginia \ = >) 20
27 | Morristown. -.----------..------ Tennessee .----- 839-839 30! 86°-36° 30! | 963 25
Virginia - - -| :
2SuEPied mousse ssnea= ee ee eea ey {atarytand 79°-79° 30’ 392-399 30/ 925 25
West Virginia. .
Nevada City - 121° 00! 25//-121° 03/ 45’ | 39° 13/ 50//-399 17/ 16” 11. 65
29 | Nevada city...| Grass antes} California -.-.--- pe 01! 35-1219 05! 04” | 39° 10’ 22//-39° 13/ 50!” | 12. 09 50
Banner Hill - 120° 57’ 05/'-1219 00’ 25” | 39° 13/ 50//-39° 17’ 16” 11. 65
; x ioe 3 || |
{Yellowstone a- }Canyon..- = ate 04110 ORD : 5)
30:)) © tional Park | Shoshone | Wyoming --.--- 1109-111 44045 3,412 75
Lake ....- ae ee ;
31 | Pyramid Peak CaM ene: SSoees 120°-120° 30/ 38° 30/-39° 932, 25
a irginia . -- F i 2
Gp) || tS co-sadeccoocoseneec ese {west Virginia __|| 792-79° 30 38° 30/-39° 932| 25
GB} [t derseanallllls Sk ao ne poeosocosaseus Tennessee .-.--- 840-849 30! 36°-36° 30’ 963 25
34 | Buckhannon...--.-...--..----- West Virginia - 802-809 30/ 38° 30/-39° 932 25
3Dn| | Gadsden asa — ewan =ae ee eee == Alabama. ..----- 86°-86° 30/ 349-342 30/ 986 25
B18 || MA) - See scone seseessces Colorado 6 104° 30/-105° 382-382 30/ 938 50
Si) | Wowniewillejesaece- eee = Californi as 120° 30/-1219° 39° 30/-40° 919 20
a) |) EMO nese Sosssoscocbeases Jalifornia. ------ 120°2-120° 30/ 39°-39° 30’ 925 25
A On e\Vieutt b Uno ene eee et meee Tennessee 84° 30/-85° 36°-36° 30! 963 25
401 | SOMO. soc teresosascosccos soe California 120°-120° 30’ 37° 30/389 944 25
2D || INV @CGR) pas co-sso- cocassoseset ‘Yexas -..- 100°-100° 30/ 29° 30/-30° 1, 035 25
430|) BidiwelleBauesdaeate cesses. California 121°-121° 30/ 89° 30/-40° 918 25
nes fMirginia..-.. : ; FP i 2
ZU) GIES amacsaoctisosceoosesos VWest Virginia... } 81° 30/-82° 37°-37° 30 950 25
GB) |! IONE) oo sc cosecccncossbesosae NGM). s-Seoccne 116°-116° 30’ 43° 30/-44° 864 25

STATISTICAL PAPERS.

Mineral Resources of the United States [1882], by Albert Williams, jr. 1883. 8°. xvii, 813 pp.
Price 50 cents.

Mineral Resources of the United States, 1883 and 1884, by Albert Williams, jr. 1885. 8°. xiv,
1016 pp. Price 60 cents.

Mineral Resources of the United States, 1885. Division of Mining Statistics and Technology.
1886. 8°. vyii,576 pp. Price 40 cents.

Mineral Resources of the United States, 1886, by David T. Day. 1887. 8°. viii,813 pp. Price
60 cents.

Mineral Resources of the United States, 1887, by David T. Day. 1888. 8°. vii,832pp. Price
50 cents.

Mineral Resources of the United States, 1888, by David T. Day. 1890. 8°. vii, 652 pp. Price
50 cents.

Mineral Resources of the United States, 1889 and 1890, by David T. Day. 1892. 8°. viii, 671 pp.
Price 50 cents. :

Mineral Resources of the United States, 1891, by David T. Day. 1893. 8°. vii, 630 pp. Price
50 cents.

Mineral Resources of the United States, 1892, by David T. Day. 1893. 8°. vii,850 pp. Price
50 cents.

Mineral Resources of the United States, 1893, by Dayid T. Day. 1894. 8°. vyiii,810 pp. Price
50 cents.

On March 2, 1895, the following provision was included in an act of Congress:

“Provided, That hereafter the report of the mineral resources of the United States shall be
issued as a part of the report of the Director of the Geological Survey.”

In compliance with this legislation the following reports have been published:

Mineral Resources of the United States, 1894, David T. Day, Chief of Division. 1895. 8°. xv,
646 pp., 23 pl.; xix, 735 pp., 6 pl. Being Parts III and IV of the Sixteenth Annual Report.

Mineral Resources of the United States, 1895, David T. Day, Chief of Division. 1896. 8°.
xxiii, 542 pp., 8 pl. and maps; iii, 543-1058 pp., 9-13 pl. Being Part III (in 2 vols.) of the Seventeenth
Annual Report.

Mineral Resources of the United States, 1896, David T. Day, Chief of Division. 1897. 8°.
xii, 642 pp., 1 pl.; 643-1400 pp. Being Part V (in 2 vols.) of the Highteenth Annual Report.

x ADVERTISEMENT.

Mineral Resources of the United States, 1897, David 'T. Day, Chief of Division. 1898. 8°.
Being Part VI (in 2 vols.) of the Nineteenth Annual Report.

The money received from the sale of the Survey publications is deposited in the Treasury, and
the Secretary of that Department declines to receive bank checks, drafts, or postage stamps; all remit-
tances, therefore, must be by MONEY ORDER, made payable to the Director of the United States

Geological Survey, or in CURRENCY—the exact amount. Correspondence relating to the publications

of the Survey should be addressed to
Tue DIRECTOR, |

UNITED STATES GEOLOGICAL SURVEY,
WASHINGTON, D. C., December, 1898. WASHINGTON, D. C.

se

Series.

Author.

Subject.

(Take this leaf out and paste the separated titles upon three of your cata-
logue cards. The tirst and second titles need no addition; over the third write
that subject under which you would place the book in your library.

LIBRARY CATALOGUE SLIPS.

United States. Department of the interior. (U.S. geological survey.)

Department of the interior | — | Monographs | of the | United
States geological survey | Volume XXXI | {Seal of the depart-
ment] | Washington,| government printing office | 1898

Second title: United States geological survey | Charles D.

Walcott, director | — | Geology | of the | Aspen mining district,
Colorado | with atlas | by | Josiah Edward Spurr | — | Samuel

Franklin Emmons, geologist in charge | [Vignette] |
Washington | government printing office | 1898
4°, xxxy,260pp. 43 pls. and atlas of 30 sheets folio.

Spurr (Josiah Edward).

United States geological survey | Charles D. Walcott, di-
rector | — | Geology | of the | Aspen mining district, Colorado |
with atlas | by | Josiah Edward Spurr | — | Samuel Franklin
Emmons, geologist in charge | [Vignette] |

Washington | government printing office | 1898

49. xxxv,260pp. 43 pls. and atlas of 30 sheets folio.

[Unirep STATES. Department of the interior. (U. S. geological survey.)
Monograph XXXTI.]

United States geological survey | Charles D. Walcott, di-
rector | — | Geology | of the | Aspen mining district, Colorado |
with atlas | by | Josiah Edward Spurr | — | Samuel Franklin
Emmons, geologist in charge | [ Vignette] |

Washington | government printing office | 1898

49, xxxv,260pp. 43 pls. and atlas of 30 sheets folio.

[Unirep SrarEes. Department of the interior. (U. 8S. geological survey.
Monograph XXXTI.]

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