piety on St5 sSrintce 4 nb? 2 et we ei “picaeaeeetc heelatanars pees ne + t ott 4 SPs Ss Pub shand oes pbs Rif S vm He LS ROW I Meta! Tena ass: ‘ : mires] ty hepr Tite siborie LIBRARY ‘ ROYAL ONTARIO. MUSEUM 100 Queen's Park TORONTC, Ontario M5S 2C6 Returned to: ) j 1 f Y| ds on ; ih [Azer Date: ie, gilt ones oy, PROCEEDINGS => 7 og OF THE ACADEMY OF NATURAL SCIENCES OF PHIADEH IEP EPA. LS it, ©. PUBLICATION COMMITTEE. Jospri Leipy. M.D.. Gro. W. Tryon, JR., Wm. S. Vaux, W.S. W. RuscHENBERGER, M.D., Gro. H. Horn, M.D. Eptrorn: EDWARD J. NOLAN, M.D. P AoA Da Re eA: ACADEMY OF NATURAL SCIENCES, S. W. Corner Nineteenth and Race Streets. 1876. HALL OF THE ACADEMY OF NATURAL SCIENCES, PHILADELPHIA, February, 1877. I hereby certify that printed copies of the Proceedings for 1876 have been presented at the meetings of the Academy, as follows :— Pages’; 9to 24 . E : . April 18, 1876. ys 25 to 40 . : ‘ 4 or 25, 1876. Sg (ILO, 6655 : : . May 23, 1876. ut PbO, sien 5 ; . June 13, 1876. Ae 73 to104 . : , . watly: 11, 1876. On stom 20). 3 5 . August 8, 1876. ei tomloziee ; : . September 5, 1876. SO Sep Use} tiopalicyf ; : . November 14, 1876. Ate (LSD t0;200e : : : s 28, 1876. 901 to B8Gul > eS ee Ye anuatye | Alene ‘6 233 to 264 . : : : ne 9, 1877. ‘6 265 to 328. : ' : as 23, 1877. ‘| “329. toa 10)”. : . : a 30, 1877. EDWARD J. NOLAN, M.D., Recording Secretary. PHILADELPHIA: COLLINS, PRINTER. LIST OF CONTRIBUTORS, With reference to the several articles contributed by each. For Verbal Communications see General Index. Allen, Harrison. Zoological and Biological Methods of Research..... Allen, J. A. Description of a New Generic Type (Bassaricyon) of Pate vom {TOM COSTA EGR 4 62h is ares sig sini als woes so Ris om ajassie Barcena, Mariano. On certain Mexican Meteorites................-- Pieshocksilsnownmad Mexicam OnyXs< 2. s.)c ssi sb svg nee sowie altos Binney, W. G. On the Lingual Dentition, Jaw, and Genitalia of Carelia, Onchidella, and other Pulmonata..................... Chapman. i. (C. Description of a Monstrosity... . 52.506 k s.iginne eons Clark, S. F. Report on the Hydroids collected on the Coast of Alaska and the Aleutian Islands, by W. H, Dall, U. S. Coast Survey Gu batiy, irom 18a) to 1874, Wiclusive:. ines < ceeese soTU S2r Sas fe seo Ss O08 SS 5,8 Se Se S oo SS Seo. ses | 24 Sats) ys tous oF. S BGS See to ntea : Ex CUNLLOMatetet ore cteley ote svarers * Beegie atiOn, Modified ve atition : * which proceeds by 9 jy P s phoad an ae s SHARON Sac coscodesopsucea) 2 * retardation, XA CHAO Ply tere = ; : . | 1.55 | 3.00 | 3.53 | 2.40 | 1.72 Width of muzzle at the canines . ; Sale GucieOOhateo0) elo: |» 6g Width of palate at second molar . é Se TOO)| eon liee Golllareo en |i cay, Length of upper molar series. : . | .92 11.50 | 1.60 | 1.60 | 1.07 Length of the three true molars . - ere Saleen Onl 9 gel 663 Length of lower molar series. é wn ee Gort Gi ihe 87,| 4.70 bles Length of the three true molars . : = | do OSE 26 [1.17 ) 72 Length of lower jaw . : : - . | 2.20 | 3.82 | 3.75 | 3.40 | 1.37 Height of lower jaw . ‘ ; : . | 1.03 | 1.30 | 1.65 | 1.52 | 1.03 The loss of the skin renders it impossible to now properly cha- racterize the species, but as it is presumably only temporarily mislaid, we hope soon be able to make known its external charac- ters. The large size and position of the orbits, and the large bulle, seem to indicate an animal of nocturnal habits. It is also evidently rather rare, or very difficult to obtain, since Pro- fessor Gabb’s collection, which embraces very large series of all the more common species, contains but a single example of this. For the genus I propose the name Bassaricyon, in allusion to its strong resemblance in several features to Bassaris, and for the species that of Gabbii, in recognition of Professor Gabb’s in- valuable contributions to our knowledge of the zoology and gene- ral natural history of the Republic of Costa Rica. As the species differs more from either Nasua or Procyon than the latter do from each other, it seems to form a type quite as well entitled to rank as a sub-family of the Procyonide as do either of the others, and may hence be called Bassaricyonine. 24 PROCEEDINGS OF THE ACADEMY OF [1876. DESCRIPTION OF A MONSTROSITY. BY HENRY C. CHAPMAN, M.D. I am indebted to Dr. James Ogden, of Paschalville, Philadel- phia, for the opportunity of dissecting the monstrosity, of the general appearance of which, the illustration gives a good idea. I learn from the doctor that the father and mother are both co- lored people. The mother is only 18 years old, and has had one child. The children were born dead. The labor lasted 12 hours, the head of the right child presenting first. There was but one placenta. As regards their mode of attachment, the children were joined together anteriorly by a common sternum and posteriorly by the ribs, the left ribs of the right child being joined to the right ribs of the left. (In my description the children are supposed to be lying upon their backs.) There were two distinct vertebral col- umns ; the heads and necks were quite separate and freely movable. The right upper and lower extremities of right child and the left upper and lower extremities of left child were normal. The two inner arms seemed to be represented in a rudimentary condition 1876. ] NATURAL SCIENCES OF PHILADELPHIA. 25 by a lump growing out of a scapula more or less divided into two. The inner clavicles of the children were united. The bone was found fractured, this being caused no doubt in labor. The inner legs of the children were fused into one, which articulated with the acetabulum formed by the inner innominates. The foot exhi- bited eight toes. Five of these belonged to the left foot of right child and three to right foot of left child. The pelves were double. The left innominate of right child was fused with the right inno- minate of left child. Circulatory Apparatus.—There were two distinct hearts with a sinus between them, which received the innominate veins and opened into the right and left auricles of the heart of the right child and the right auricle of the heart of the left child. The heart of the left child was twice as large as that of the right, the common carotids in both children arose by a single trunk from their re- spective aortas. The outer subclavians were normal, the inner ones feebly developed. The two aortas were well developed, but there was but one hypogastric artery; this, however, was large, and came off from the aorta of left child. Two pairs of lungs were present. Alimentary Apparatus.—While there were two distinct stom- achs, the two small intestines, however, united twenty-seven inches above the cecum to form one large intestine, which terminated in a single rectum with one anus. ‘The two livers were continuous, the umbilical vein divided into two branches, one for each liver. The two pancreas’ were massed together, but only one spleen was seen. The Genito-urinary Apparatus.—Four kidneys were found, those of left child lying rather loosely in the abdominal cavity ; they exhibited enormous ureters which terminated in a bladder in front of the uterus of the left child. As there was no external opening, their size arose possibly from their chronic dilatation by urine. The kidneys of the right child were found in their normal condition, their ureters terminated in a bladder which was seen lying in front of the uterus of right child. The uterus of the right child terminated in a bifid vagina with two external open- ings ; the uterus of left child was longer and narrower than that of right; its vagina was imperforate. The rectum lay between the two uteri. Reflection on the Cause of Monstrosities.—It is well known that there are two views offered by physiologists as expl*nations 3 26 PROCEEDINGS OF THE ACADEMY OF [1876. of the formation of monstrosities: either they are to be regarded as due to the fusion of two individuals, or the secondary indi- vidual is to be considered as having budded from the first. As an argument in favor of this latter view there is instanced the fact of there having been found in one yolk two embryos more or less united. While the fact is true, the inference that such embryos have been developed from one germ cannot be drawn until it has been shown that such a yolk has not resulted from the fusion of two yolks while in the oviducts. As an objection to the former view, it is urged that as the presence of an additional finger or toeis merely regarded as an exhibition of extra nutrition, a sort of budding, to be consistent an almost perfect secondary individual should also be regarded as such, inasmuch as there exists a gradual series between the very simple malformations and the more complex ones, and further, if an additional finger for example has resulted from the fusion of two individuals, what has become of the rest of the secondary being? It may be answered that the presence of an extra finger cannot be fairly compared with that of a secondary system, alimentary, circulatory, etc., well developed. Again, itis quite conceivable in certain cases that only a part of a secondary individual should develop and the rest atrophy. While not denying that there can be budding from cer- tain parts, it appears to me that a fact like that just described of two intestines fusing into one, with the remaining organs double and fully developed, is more readily understood by sup- posing that two individuals have been joined together than that one has budded from the other. The different pups in a litter are developed from distinct ova. Most authorities consider human twins as having the same origin. It seems a natural inference, therefore, that a monstrosity such as I have just described is the result of the union of two individuals in the early stages of ges- tation. 1876. ] NATURAL SCIENCES OF PHILADELPHIA. 27 DESCRIPTION OF NEW SPECIES OF FOSSILS FROM PALEOZOIC ROCKS OF IOWA. BY CHARLES A. WHITE, M.D. RADIATA. ACTINOZOA. Genus CHATETES, Fischer. Chetetes Muscatinensis (n. s.). Polypary not usually large or massive, but generally encrusting some object, upon which it attains considerable thickness by con- centric layers; cells exceedingly slender, but under a good lens they show their numerous septa and the slight constriction of the cells between them quite distinctly. This species seems never to become ramose, or even elongated except byencrusting some elongated object ; by this habit and the unusual minuteness of the cells it may be distinguished from all other species. Position and locality.—Devonian strata, near Muscatine, Iowa. Genus MONTICULIPORA, D’Orbigny. Monticulipora monticula (n. s.). Polypary usually consisting of small expanded masses, flat or concave below, convex above, thin at the edges, but the middle portion being thickened and considerably elevated ; the upper sur- face having the papillary elevations peculiar to the genus and the under side sometimes having the appearance of being provided with an epitheca; cells of ordinary size, not radiating from a com- mon centre but extending upward more or less perpendicularly with the plane of the base of the polypary. The uniformity of habit of this species is its most distinguish- ing characteristic, and by which it may be readily recognized. Position and locality.—Devonian strata, lowa City, Iowa. Genus LOPHOPHYLLUM, Edward et Hairne. Lophophyllum expansum (n.s.). Corallum broadly conical, slightly curved, transverse section subcircular, calyx broad, not deep; rays numerous; septal fos- 28 PROCEEDINGS OF THE ACADEMY OF [1876. sette not very distinct, situated at the convex side of the corallum ; columella prominent, laterally flattened so as to form a more or less sharp edge along its crest. This species is proportionally much broader than usual, and when its interior structure is better known it may possibly be found to belong to the genus Axophyllum, but its external charac- ters seem to warrant its reference to Lophophyllum. Height of corallum and diameter of calyx each about two centi- metres. Position and locality.—Keokuk limestone (subcarboniferous), Henry County, Iowa. : ECHINODERMATA. Genus STROBILOCYSTITES (n. g.). Body ovoid or subspherical; pectinated apertures forming three inclosed rhombic areas, one on each of the four parts of the body except the posterior part ; those of the two lateral parts situated above the middle of the body, and that of the anterior part below the middle; ovarian aperture distinct, situated a little below the summit of the posterior side; the four principal arm-grooves dis- tinct, radiating from the summit as far as, or below, the middle ; small secondary arm-grooves extending obliquely downward from each side of the principal grooves, their length and distribution being made irregular by the presence and unsymmetrical position of the pectinated rhombs. The principal plates are probably similar to those of Callocys- tites, but our examples do not show their shapes distinctly ; the secondary plates bordering and near the arm-grooves numerous and small. Two specimens only of the species representing this genus have been discovered. One of these is very imperfect, and the other, although in a comparatively good state of preservation, does not show clearly the arrangement of all the plates. Enough, however, is shown of its structure to separate it from any described genus. It is also, so far as I am aware, the first cystidian ever found in Devonian rocks, the family having hitherto been regarded as cha- racteristic of Silurian strata. Strobilocystites Calvini (n. s.). Body subovoid in form ; principal arm-grooves distinct, extend- ing nearly to the base of the body; the two antero-lateral and the 1876. ] NATURAL SCIENCES OF PHILADELPHIA. 29 two postero-lateral grooves respectively coalescing before they reach the summit, across which continuous connection is made with all of them by a short groove; the front, and the two lateral parts, of nearly equal width ; the posterior part narrower than either of the others, and bearing the ovarian orifice a little below its summit ; the pectinated rhombs divided longitudinally by a distinct suture ; the rhomb of the left side situated about one-third the height of the body below its summit, the direction of the long diameter being nearly at right angles with the axis of the body, and its length a little more than two-thirds the full width of the side: the rhomb ‘of the right side situated at about the same distance below the summit as that of the left, but its long diameter is nearly vertical and twice as great as its transverse diameter; the rhomb of the front side situated near the base, its long diameter being obliquely transverse with the axis of the body, and its shape and size being similar to that of the left side; secondary plates small, tumid, placed in alternating series along each side of the arm-grooves, and outside of these first rows there are other similar pieces, some of which alternate with the first, but others are more irregularly distributed, all giving the surface a papillose appearance. Column and appendages unknown. Height of body eighteen millimetres; transverse diameter thir- teen millimetres. Specific name given in honor of its discoverer, Professor Samuel Calvin of the Iowa State University. Position and locality.—Devonian strata, lowa City, Iowa. Genus MEGISTOCRINUS, Owen. Megistocrinus Farnsworthi (n. s.). Body below the arms moderately deep, its sides slightly ex- panded, but broadly convex below, and its immediate base a little concave; dome broadly convex, composed of numerous small tumid pieces, and apparently having a short, sub-central probos- cis; arms sixteen, four to each of the postero-lateral, and to the anterior rays, and two to each of the antero-lateral rays ; the basal series of pieces moderately large, slightly concave, more than half its diameter covered by the last joint of the column; the anal series of pieces occupying a comparatively broad space; the plates generally, having the proportions, shapes, and arrangement common to the genus; the central portion of all the plates is prominent, or 30 PROCEEDINGS OF THE ACADEMY OF [1876. they have their borders so depressed as to produce the appear- ance of central prominence to the plates, and of broad sutures between them. Height of calyx fourteen millimetres; diameter of body at the base of the arms, twenty-seven millimetres. This species differs from MM. latus Hall, from rocks of the same age in Iowa, by its smaller size, its tumid plates and depressed sutures, and in having only sixteen arms instead of twenty, as in that species. Specific name given in honor of Professor P. J. Farnsworth, of the Iowa State University, who first discovered it. Position and locality.—Devonian strata, Lowa City, Iowa. MOLLUSCA. BRACHIOPODA. Genus STRICKLANDINIA, Billings. Stricklandinia casteliana (n. s.). Shell moderately large, sublenticular, broadly subovate or sub- circular in marginal outline; valves almost equally convex. Dorsal valve usually showing a slightly elevated, indistinctly defined mesial fold, which is quite narrow upon the posterior por- tion of the valve, but widens toward the front, of adult shells; umbo broadly convex; beak not prominent. Ventral valve usually having a slight flattening of the antero- median portion, corresponding with the indistinct fold of the other valve; umbo broadly convex; beak not prominent, projecting backward little if any beyond the beak of the other valve; area distinct, narrow, its length less than half the greatest width of the shell. Surface of both valves marked by numerous, rather coarse, radi- ating, more or less recurving, angular or sharply rounded plica- tions, of unequal size and separated by spaces of unequal width. Length and breadth of the largest example discovered, each forty-two millimetres; thickness, both valves together, twenty-one millimetres. Position and locality.x—Niagara limestone, Upper silurian, near Castle Grove, Jones County, Iowa. 1876. ] NATURAL SCIENCES OF PHILADELPHIA. 31 CONCHIFERA. Genus PARACYCLAS, Hall. Paracyclas Sabini (n. s.). Shell sublenticular ; subcircular or subovate in marginal out- line; beaks small, approximate, pointing forward, elevated little if any above that portion of the dorsal margin which lies behind them, but considerably above that portion in front of them; dorsal, posterior and basal margins forming nearly one uniform curve, but the prominent front, which is the narrowest and thinnest part of the shell, has its margin more abruptly rounded; ligament small, slightly prominent, but it is made apparently more promi- nent by two distinct, moderately deep narrow grooves, one on each side of it, which extend from between the beaks backward, and become obsolete upon the postero-dorsal region; valves broadly and nearly uniformly convex, the surface being marked by ordinary lines and slight undulations of growth. Length of the most perfect example discovered, seventeen milli- metres; height fifteen millimetres; thickness eight millimetres. The proportionate thickness of fully adult shells is usually much greater than that here given. The specific name is given in honor of Mr. A. H. Sabin, of Mason City, Iowa. Position and locality—Devonian strata at Rockford, Floyd County, Iowa. Genus ALLORISMA, King. Allorisma Marionensis (n. s.). Shell small, elongate, ventricose anteriorly, and laterally flat- tened behind, where it is usually a little broader from base to dorsal margin than the anterior portion is; umbones prominent, elevated; beaks incurved, placed far forward; dorsal margin straight or slightly concave; postero-dorsal margin sloping back- ward to the posterior extremity, the greatest prominence of which is at, or a little below, midheight of the adult shell; base broadly rounded or straightened about midway where the slight umbonal flattening of each valve meets it. Surface marked by the ordinary concentric lines and undulations of growth. Length twenty-eight millimetres ; height thirteen millimetres. 32 PROCEEDINGS OF THE ACADEMY OF [1876. A few examples have been obtained that are about one-third larger than that of which the dimensions are here given, but it is an unusually small species. Position and locality St. Louis limestone (subcarboniferous) of Marion and Mahaska Counties, Iowa, where it is sometimes found quite plentiful, in both the calcareous and magnesian layers of that formation. GASTEROPODA. Genus BELLEROPHON, Montfort. Bellerophon Bowmani (n. s.). Shell small, somewhat flattened vertically ; umbilici small, and sometimes nearly or quite closed by the overlapping of the callus- like, slightly reflexed expansion of the postero-lateral portions of the margin of the aperture; volutions broadly convex both later- ally and longitudinally; aperture comparatively large, but the external margin is not reflexed or flattened by its expansion ; mesial band distinct, slightly raised; mesial notch not deep. Surface marked by numerous concentric folds which are crossed by revolving raised lines of nearly the same size, giving the sur- face a neatly cancellated appearance. Length eight millimetres ; breadth of aperture the same; height, lying with its aperture downward upon the table, five milli- metres. Specific name in honor of Mr. S. C. Bowman, of Andalusia, IIL, who first discovered it at that place. Position and locality.—Devonian strata, New Buffalo, lowa, and Andalusia, Illinois. Genus EVOMPHALUS, Sowerby. Euomphalus Springvalensis (n. s.). Shell rather large; spine much extended for a species of this genus; volutions six or seven, gradually increasing in size from the apex to the aperture; flattened upon the distal or upper side, regularly and continuously rounded upon the outer and proximal sides, and into the deep umbilicus; aperture nearly circular, its outline being modified only by the slight flattening of the distal side and the short contact of the preceding volution. Length about five and a half centimetres; breadth of last volu- ~ 1876.] NATURAL SCTENCES OF PHILADELPHIA. 33 tion seven centimetres; diameter of aperture twenty-three milli- metres. Position and locality—Kinderhook formation (Subcarbon- iferous), Springvale, Humboldt County, Iowa. PTEROPODA. Genus CONULARIA, Miller. Conularia Molaris (n. s.). Shell having the ordinary four-sided conical shape, each side having an indistinct very faintly impressed longitudinal line, not placed in the middle of the side but nearer to one angle than the other, each angle having the adjacent lines at equal distances, these distances being of course greater from two of the angles than from the other two. Surface marked by fine, sharply raised, minutely crenulated, transverse lines, which present the convexity of a broad curve toward the front as they cross the sides, but bend very slightly forward at the angles, the grooves of which most of them cross continuously to the adjacent side. These raised lines are at slightly irregular distances apart, the distance being usually a little greater than their own width. F,,+3Aq. at This formula appears improbable from its complexity, and from the fact that the affinities of fluorine are not satisfied by the metals. — Dr. Hagemann states the crystals to have been covered with a white earthy material (SiO, ?), and accounts for SiO, — 2.00 in the analysis. Whenever a mineral substance is so obviously heterogenous as this one, its analysis should not be considered reliable enough to deduce a formula, or form an opinion of molecular composition. Dr. Hagemann’s formula 2(2Ca+4Na)F+ ALF,+2H,0 1876. NATURAL SCIENCES OF PHILADELPHIA. 45 is not consistent with the analysis; it is a mere conjecture, as may be seen by comparing with the above atomic ratio. Having lately obtained a number of specimens from the Green- land cryolite locality, through the Reverend Dr. Beadle, of this city, to whom I herewith express my thanks, I thought it worth the trouble to corroborate the few analyses of these very interest- ing minerals. A specimen, agreeing completely in its physical properties with the description of Knop’s variety A of pachnolite, was first in- vestigated. The structure of the specimen is very like that of crusts of salt, as they are often obtained by slow evaporation— tabular aggregations of cubes, arranged parallel to each other, and at right angles, leaving interstices between themselves into which the cubic crystals project. The tabular masses have ap- parently one common cleavage face for all individuals, which is of a decided pearly lustre, as described for Thomsenolite. The faces projecting into the interstices are striated and tapering. The crystals are perfectly colorless for the most part. The basal plane O is well developed in all individuals, but the pyramidal faces 1, 1, are usually suppressed. Some of the projecting prisms carry very small octahedrons, either Chiolite or Ralstonite. In selecting the material for analysis, the greatest care was taken to select only perfectly clear cleavage crystals, on which any admixture might be most easily discovered. An attempt to measure the angles of cleavage direction proved unsatisfactory; the measurements differed several degrees, but (in most cases) were found to be near 90°. Spec. grav. — 2.937 (made with 5.6921 grammes); 0.5000 grm. gave— oA OM teem | Bllyy Ral) = 20.1176 Na,SO, = 0.1560 (Na = 0.0505) H,O 0.0450 1.0000 grm. gave NaCl — 0.2535 (Na = 0.0997) and MgO — 0.0023. AY S21814 227.5 = 0.496 HO —' 9.00: 18" ''='0.50 F =50.37: 19 = 2.63 (by difference) 46 PROCEEDINGS OF THE ACADEMY OF [1876. Taking Ca — 0.42 as unit, the ratio is— F Al Ca Na H,O 6.30 Ly 1.00 1.05 1.30 agreeing to the formula— Al Ca t F, + Aq Na as deducted from Knop’s analysis of Pachnolite. I selected now another specimen, which contains very brilliant crystals ina druse. I broke the crystals off with a forceps, so as to leave a stump on the matrix to be sure of a thoroughly homo- geneous material. These crystals were very slender, of quadratic section, and gently tapering to a point. The basal plane O seemed entirely suppressed in nearly all the crystals, and the pyramidal faces in many, but the very brilliant faces of the prism were distinctly striated horizon- tally. Basal cleavage very perfect, with pearly lustre. A series of measurements with specimens about } inch long and 5 inch wide gave for the prismatic angles the following figures :— 1 2 3 4 90° 30’ 90°,107 907 15! 902-5" 89° 36/ 89° 52! B9° 25! 50% 15? 90° 14! 90°13! 90°15" BOP 25" 89° 40’ 89° 45/ | Dieaames if 90815" The angles are not very constant, but the deviation from a right angle is very small. The angle of the basal plane with the prism could not be determined to my satisfaction. Considering the tapering forms, it seems impossible to say whether the form is rhombic or monoclinic, or quadratic. The points of all the crys- tals were colored yellow or brown by ferric hydrate, and some crystals had a light straw-color all through. Specific gravity — 3.008 (determined with 0.7153 grm. in a pyknometer holding about 2 cub. cent. of water). 0.5000 grm. gave— Al,O,; == 0.1170 CaO = 0.1270 Na,SO, = 0.1575 (Na = 0.0511) H,O = 0.0252 (from 0.3075 grm.) 1876.] Yielding percentage— F 6.080 Al =12.50: 27.9 = 0.454 Cars = 18;140:540) == 0.458 Nai == 10.23.2923" -== 0.444 HOS 8.19 2s == 0-495 es toe 2s h02 100.60 Taking Na — 0.444 as unit, the ratio obtains— Al Ca Na 1.042 1.020 1.000 Al Ca > F, + Aq. wa) NATURAL SCIENCES OF PHILADELPHIA. 47 H,0 1.030 (The fluorine is calculated for the percentages of the metals.) About the correctness of this formula, and the true molecular composition of the mineral, there can be no longer any doubt in view of the above analytic results. A mineral occurring in small stalactitic and warty masses which project from parallel walls or partitions made up of a compact mineral. lustre. It is colored strongly brown, and shows a velvety On closer observation the stalactites and warts appear to be aggregations of very minute prismatic needles of strong vitreous lustre. 0.5000 grm. gave— Al,0, CaO = 0.1235 == Vall go No selection was attempted. Na,SO, = 0.1135 (Na — 0.0367) H,O F,Ca = 0.047 = 1.0577 (F =0.5194) from 1.000 grm. Yielding percentage— aso: Aly = 13, 16); Ca =17.07: Na = (S30 ee H,O = 9.40: 98.92 19 = 2.134 215 == 0418 40 = 0.429 23 = 0.320 18 == 0.525 48 PROCEEDINGS OF THE ACADEMY OF [ L876. Taking Ca = .429 as unit, the ratio obtains— F Al Ca Na H,0 6.3 way 1.00 0.746 Lee The sodium is too low in this ratio to admit of anything more than an approximation to the general formula, and I consider this substance as a mixture like the one analyzed by Dr. Hagemann (Ua6:). The blowpipe and other general chemical properties I found to be as stated by Knop. In analyzing these substances it is neces- sary to evaporate the solution in the sulphuric hydrate to dryness, to redissolve by boiling with about 300 cubic centimetres of water slightly acidulated, when all the calcium sulphate will pass into solution. In separating calcium and aluminum I encountered no diffi- culty, although the aluminum hydrate is very gelatinous. Filter- ing under pressure, without washing the precipitate, I found, after redissolving it in HCl and reprecipitating by NH,HO, but a trace of Ca in the filtrate. It is necessary, however, to ignite the aluminum oxide on a blast in order to obtain a correct weight. In decomposing the mineral in HCl it dissolves, as in H,SO,, to a viscous mass, but a complete elimination of fluorine was not effected even after evaporating with strong acid (to dryness 6 times). The aluminum precipitate contained about one-half of the calcium as fluorid. As is well known, the determination of fluorine presents a num- ber of difficulties, which render an accurate result very uncertain. Fresenius’s method, although capable of yielding reliable results, is nevertheless almost impracticable, from the aceumulation of errors by changing weights in the numerous parts of desiccating and absorbing apparatus. I endeavored, therefore, to set the fluorine free as fluorid of hydrogen, and collect the latter in an alkaline solution. This method has been proposed (Rose—Ana- lytical Chem.), but Iam not aware whether it was ever practised with natural fluorids. Having a platinum still at my disposal, I thought of testing the applicability to the analysis of the above minerals. In a first experiment sulphuric hydrate was used to decompose the mineral at a temperature rising gradually to the boiling point of theacid. After 45 minutes, on opening the still and dropping in 1876. ] NATURAL SCIENCES OF PHILADELPHIA. 49 water, a strong disengagement of HF took place. In a second experiment one part of hydrate was mixed with one part of water. The distillation proceeded very well, and was only interrupted after the alkaline liquid in the receiver (containing 25 p. c. more of NaHO than was approximately required by the fluorine) turned acid. On opening the still and adding water,no HF was disen- gaged, and the entire residue from distillation passed into solution when heated with a large quantity of water; hence a complete decomposition of the mineral had taken place, and the acid vapors had carried all HF into the receiver. After neutralizing the liquid in the latter, a solution of CaCl, was added, containing slightly more than the fluorine would prospectively require, and the liquid heated to boiling. The calcium fluorid coagulated perfectly and filtered very easily. It was twice returned into the capsule and boiled with water to extract all calcium sulphate. The precipitate weighed after ignition 1.0577 grammes. To the filtrate a solution of sodium carbonate was added in excess and boiled, the precipitate ignited, and extracted with precaution by acetic acid. It weighed 0.0085 after being again ignited. The alkaline filtrate was acidulated and precipitated by BaCl,. Precipitate weighed 0.1580. In order to ascertain the exact quantity of sodium hydrate which had been combined with the acids, an equal volume (30.2 ¢.c.) was evaporated with HCl. The sodium chlorid weighed 1.7205 grms. = 0.9117 Na,O. But 0.2¢.c. had been used to restore the blue color, and has to be subtracted, giving 0.9117 — 0.0060 — 0.9057 Na,O combined with fluorine and sulphuric anhydrate. We found— BaSO, 0.1580 = SO, — 0.0542, requiring 0.0420 Na,O, hence 0.9057—0.0420 =0.8637 Na,O was combined with fluorine, but 31 Na,O : 19 F — 0.8687 : 0.5230. By precipitation was obtained 0.5194 F, a difference of 0.0036. This result was quite promising. It was obtained with the stalactitic aggregations of pachnolite. But on applying the method to the analysis of the parallelopipedic crystals of pachno- lite, I encountered difficulties quite unaccountable. I did not suc- ceed in decomposing the mineral completely, either with one part of sulphuric hydrate and one part of water, or with more dilute acid, or by fusing with KHSO, in repeated trials and proportions. 50 PROCEEDINGS OF THE ACADEMY OF [1876. I am, however, still confident that the method can be so modified as to be applicable to these fluorids. Regarding silicium dioxde, which Hagemann found in his analysis, I endeavored to find it, but failed. It was certainly owing to superficial impurity. Potassium I could separate in traces only. The determination of water I found to be most satisfactory when I used calcium oxide mixed with the minerals instead of lead oxide. The latter when heated to expel moisture is very apt to be partially converted into sesquioxide, which will ata red heat lose oxygen, and the quantity of water will be found too high. Conclusions. 1. The mineral analyzed by me is identical in composition with Knop’s pachnolite. 2. It is identical in form and physical properties with thom- senolite. 3. The measurements are so uncertain that the true form of the parallelopipedic crystals cannot be deduced, and the form may be explained as Knop did. 4. The mineral measured by Knop and Descloizeau has perhaps not been analyzed, since Knop does not describe his material taken for the analysis. 5. From the foregoing it does not seem justified to separate the parallelopipedic forms as a distinct species, and the name pachno- lite being very expressive and older, all the forms should be designated as pachnolite until further investigation. I may be permitted to state that I do not intend to discard the crystallographic results of Knop, Dana, and Descloizeaux (the original of the latter’s work I am unacquainted with). I should be very glad to obtain the crystals which gave the prismatic angles 98° and 81°, so that we should know whether there are two differ- ent molecules with two different forms, or whether there is only one dimorphic molecule. But from the measurements I was able to make, I should be very doubtful of dimorphism. Note.—While this paper is in press, I find a very recent publication by Professor Wohler (Ann. d. Chem. u. Pharm. vol, clxxx. p. 231), in which he gives an analysis and description of the variety A of pachnolite, and arrives at results closely corresponding to my own. 1876. ] NATURAL SCIENCES OF PHILADELPHIA. 51 APRIL 4. The President, Dr. RuscHENBERGER, in the chair. Forty-nine members present. On the Brains of Fishes.—Prof. Burt G. Witper, of Cornell University, stated that his investigations on the brains of fishes had three objects: 1. To determine, by careful structural compa- rison, the extent to which such brains may be homologized with those of the higher vertebrates. 2. To see whether brain charac- ters will enable us to define the limits of the group commonly known as Ganoids. 3. To ascertain how far brain characters, alone or in combination with heart characters, will serve for the characterization of al! the more comprehensive subdivisions (classes or sub-classes) of Vertebrates. During the last century fishes’ brains have had at least five different interpretations. Their unsatisfactory nature may be inferred from the fact that Prof. Huxley, who generally clears up difficult subjects, makes no attempt in his Manual of Anatomy of Vertebrates to reconcile the figures and descriptions of fishes’ brains either with each other, or with his admirable diagrammatic representation of the brain type, to which the brains of Batra- chians, Reptiles, Birds, and Mammals are easily referred. He gives a figure of the brain of a typical Ganoid (Lepidosteus or ‘“‘ var-pike”), but makes no allusion to it in the text. Prof. Wilder believed that brains can be fully understood only by careful comparison of preparations made from fish just taken From the water and hardened in strong alcohol; that there should be several of each typical form, and embryos or young as well as adults; and that, instead of trusting to the outward aspect, the mesial surfaces should be examined and sections made at several points. Finally, he believed it necessary to keep constantly in mind the typical brain as given by Huxley, and which ke then briefly de- scribed. By these methods he had been able, as he believed, for the first time, to find the clue to the homology of the two anterior pairs of lobes of the fish brain with parts of the brain of the higher Verte- brates. The front pair of lobes have usually, though not always, been called olfactory lobes. In Myzonts or Marsipobranchs (lamprey eels, etc.), in Ganoids and some Teleosts as in the higher Verte- brates they are sessile; but in many Teleosts and most, if not all Selachians (sharks and skates) they are connected by elongated crura with the second lobes. 52 PROCEEDINGS OF THE ACADEMY OF [1876. These latter are almost universally called hemispheres. Yet the essential features of hemispheres, namely, lateral ventricles and foramina of Monro, have never been found in the second pair of lobes of any fish-like form excepting those of the Dipnoans (Lepidosiren, Protopterus, and Ceratodus, the last just described by Huxley), which seem in most respects more like those of Batrachians than of fishes... The second pair of lobes are either lateral solid laminze joined below but with the upper borders more or less everted, as in Teleosts and Ganoids, or joined above also so as to inclose a cavity, as in Selachians. In either case the median space must be regarded as a forward continuation of the median or 3d ventricle and the lateral walls as anterior enlarge- ments of the thalami. These enlargements Prof. Wilder proposes to call prothalamz; in Selachians and some Ganoids they are con- nected by more or less elongated and depressed crura thalami with the optic lobes behind. From the anterior part of the space between the prothalami and, in Ganoids and Teleosts, apparently in the base of the olfactory lobes, Prof. Wilder had found two openings leading into the cavity of the olfactory lobes. These openings he regarded as foramina of Monro, leading into distinct, though small, lateral ventricles. He has found them in Myxine and Petromyzon (Myzonts) ; Mustelus, Carcharias, and other Selachians ; Aczipenser, Polyodon, Amia, and Lepidosteus (Ganoids), and Perca, Scomber, and An- guilla among 'Teleosts. The true hemisphere of Ganoids may be represented by a raised lip of the foramen of Monro. In an embryo Mustelus the anterior part of the brain is a single large vesicle with thin walls. From each side is a little bud which elongates to become the olfactory crus and lobe. By gradual thickening of the walls especially above, the single large cavity of the prothalamus becomes reduced to the two canais found in the adult brain near the ventral surface, which diverge forward from a median point to become continuous with the ventricles of the olfactory lobes. Prof. Wilder does not feel sure respecting the true hemispheres and the manner of their formation. In the Teleost brains so far examined the foramina of Monro are much smaller than in the Ganoids; and where long olfactory crura exist they may be wholly obliterated in the adult. But if, as is anticipated, they are present in most Teleosts, then, so far as the brain is concerned, they may be distinguished from Ganoids only by the optic chiasma of the latter, as first suggested by Miiller. To a careful comparison of the optic nerves in all fishes, therefore, attention should be directed. 1 Since this paper was presented I have seen the paper of Paul Langer- haus (Untersuchungen tiber Petromyzon Planeri [branchialis}, Freiburg, 1873), in which is given a figure showing the existence of ventricles in the hemispheres and olfactory lobes of the small lamprey, 1876. ] NATURAL SCIENCES OF PHILADELPHIA. 53 The points above mentioned were illustrated by diagrams and specimens, also by tables of a provisional arrangement of verte- brates according to the modifications of the brain and heart.’ There is much to be done before fishes’ brains can be fully under- stood. For instance, the brain of Myxine has not yet been satis- factorily homologized with that of Petromyson. In conclusion, Prof. Wilder exhibited a Chimera, recently obtained through the kindness of Mr. Alexander Agassiz, Curator of the Museum of Comparative Zoology, the brain of which, so far as he had been able to examine it, presented a remarkable combi- nation of characters, intermediate between those of Selachians, Ganoids, and Dipnoans. A full description with figures of the brain of Chimera, Prof. Wilder hoped to present to the Academy on a future occasion. On Spessartite—Dr. Grorce Auc. Kornre placed on record the analysis of spessartite from Yancey County, North Carolina. This interesting subspecies of garnet has heretofore been found at Haddam, Conn., as the only American locality. In the new locality it occurs in very large crystals, from six to eight inches long and three to four inches thick. The form is a distorted dodecahedron. The crystals have a dark, almost black color at the surface, owing to a superficial decomposition, by which black oxide of manganese is formed. But in fragments the color is deep blood- red, turning to reddish-brown in thin plates. The latter are trans- parent and reveal no admixing mineral. Fracture conchoidal. Hardness nearly =7; gravity — 4.14. B. B. unaltered in oxidizing flame, and fuses to a black vitreous globule in point of blue flame. With borax in oxidizing flame dark blood-red bead, which turns dirty-green in reducing flame. With soda, fuses to a green glass. Hot and concentrated acids attack the powder, which is of a brownish color, but very slowly, and complete decomposition cannot be effected. The very pure selected fragments yield by analysis— Oxygen. Atoms. SiO, = 35.80 19.092 19.092 0.599 17.06 ATO: == 19:06 8.881) 11.221 0.188 5.08 Fe,0; =. 6.25 DeSAO Ss oar 0.035 °1.00 MnO = 28.64 6.351 0.384 10.97 FeO = 9.49 2.107 >- 8.698 0.132 3.80 MgO = 0.60 0.240 0.015 99.84 O — 2.432 69.7 1 These with figures and descriptions of the brain of Lepidostews are pub- lished in the Proceedings Am. Assoc. for Ady. of Science. for 1875. 54 PROCEEDINGS OF THE ACADEMY OF [1876. The oxygen ratio is RO: R,O,: Si0,— | lai! ior uebe ed 5) and the atomistic formula is— IV 7} an Ale: ( 0, Mn aFe, | It will be noticed that iron is contained in this garnet, both in the ferrous and in the ferric state, while in the analyses on record the iron is given as being all in the ferrous state. When those analyses were made, the method of decomposing minerals in strong sealed tubes at a high pressure was not known, and the mineral cannot be decomposed at the ordinary atmospheric pressure, as stated above. In heating the powder for thirty-six hours with acid containing 25 per cent. of sulphuric hydrate at 160° C., I succeeded in decomposing all but 7 per cent. The ferrous oxide obtained from the solution was then calculated pro rata for the undecomposed part, and the above result obtained. To suppose that the presence of ferric iron is due to incipient alteration would not be justified, since no water was obtained by ignition, and the pellucidy of the mineral does not appear im- paired. ‘To explain the result of analysis the presence either of ferric oxide or manganic oxide must be admitted, which alternation would neither affect the oxygen ratios, nor the atomic composition. I am indebted to Mr. Clarence Bement of this city for the material used in this investigation, and I hereby express my thanks for his kindness. The thanks of the Academy were returned to Dr. James S. Gilliams for a portrait of the late Jacob Gilliams, one of the founders of the Academy, painted by Rothermell. APRIL 11. The Rey. E. R. BEADLE in the chair. Thirty-four members present. The following papers were presented for publication: ‘“ The Genus Pomoxys, Raf.” By D. 8S. Jordan and H. E. Copeland. “ Chemical Notes.” By Geo. Hay. Remarks on Arcella, etc.—Prof. Lerpy remarked that the Rhizo- pods are so exceedingly polymorphous, that, to say the least of them, their specific and generic limits appear less well defined than in higher animals. In speaking of the Difflugian Rhizopods, 1876.] NATURAL SCIENCES OF PHILADELPHIA. 55 Dr. Wallich expresses the opinion that the whole are referable to a single specific type, and as regards the Foraminifera, Prof. Carpenter observes “whether it will ever be practicable to ar- range the multitudinous forms of this group in natural assem- blages, whose boundaries shall be capable of strict limitation, is to us by no means certain.” It would seem that the existing Rhizopods, in respect to classi- fication, may be viewed as an epitome of all organic forms in all times, for if all these could be known it would be found that there were no absolute limits defining species or any other of the usual divisions in classification. The study of the Rhizopods is facili- tated by determining the more general and striking forms, and viewing the others as transitional or related forms, and we can better communicate the results of our study if the more charac- teristic forms are named as species or varieties. In his studies of the fresh-water Rhizopods, of various localities in this country, he had recognized most of the well-marked forms which have been described by European naturalists as pertaining to other parts of the world. Besides these he had detected a number of new forms, which perhaps in future will be found not to be peculiar to this country. As an example, in the published Proceedings of this Academy for 1874, page 226, will be found the description of a species, Huglypha brunnea, from New Jersey. Since then the same has been described in the Quarterly Journal, of the Microscopical Society of London for 1876, page 107, by Mr. Archer, under the name of Huglypha tincta. Mr. Archer’s description applies so closely to the specimens observed by Prof. Leidy in every detail, that he thought he was not mistaken. Among the usually recognized generic forms, Arcella had occupied his attention. In this genus the animal is provided with a membra- neous test, composed of exceedingly minute hexagonal elements, usually of some shade of brown, but colorless in the young condi- tion. The shape of the test is usually that of a greater or lesser portion of a sphere with a circular plane below more or less inverted towards a central circular mouth. The soft part of the animal rarely fills the test, but adheres to its inner surface by threads of the ectosarc. Pseudopods digitiform. The species or varieties observed are as follows :— ARCELLA VULGARIS, Ehrenberg. Difflugia arcella, Wallich; Arcella hemispherica, Perty. This is perhaps the most common form. Test approximating a hemisphere with the base rounded and often more or less pro- jecting. The dome is even or mammillated, or is impressed at the sides with concave shallow pits or angular facets. The in- ferior surface is more or less funnel-like, and the mouth elevated and circular. Color of the tests, from colorless in the young through all shades of raw sienna to burnt sienna brown. Sarcode colorless. Breadth of test from .06 mm. to .132 mm., height .036 to .08; mouth .02 to .048. 56 PROCEEDINGS OF THE ACADEMY OF [1876. ? ARCELLA DISCOIDES, Ehr. A discoid variety of the former, and nearly as abundant, has the test of the same form but three or four times the breadth of the height, and with the dome almost constantly convex and even. Mouth large. Measurement of a small colorless one: breadth 112 mm., height .028; breadth of mouth .04. Measurement of a large burnt sienna brown test: breadth .132, height .028; breadth of mouth .048. Certain discoid specimens from Florida approach those described by Ehrenberg under the name of A. peristicta, from South America. They are sub-circular, oval, or irregularly oval, often bent or curved in the shorter diameter; in section concavo-convex, with rounded ends. Mouth large, circular or oval, moderately elevated. Dome convex and even. ‘Test in the vicinity of the mouth with a circle of minute tubercles or pores? Color of test varying as in other Arcelle. Sarcode colorless. s2 jo oF | se a nes BOC re each Se et eee: eae non | Oa (Pema ese a | sepe ee : sex Com) ots |amlo| Few Be oe Constituents. Boe S532 SSa |Sosz acne = £2) aero |&ReS | hes |FSa2| ackE | ack& | No.1, | No.2 | No.3. | No. 4. | No. 5. | No. 6. SS aS A. Se | ] Specific gravity (in lump). | 2.882) 2.735) 2.731 2.750} 2.737) 2.770 j | Insoluble siliceous residue. | 4.400 12.270 12.000 3.570) 0.490) 41.710 Alumina and ferric oxide .| 1.170) 1.540, 0.450 0.210) 1.440) 6.850 Carbonate of lime . . . | !49.920 275.320 81.617 991.580 91.400) 43.728 Carbonate of magnesia. . | 142.980 10.750 6.400 44.110 7.290) 6.450 Sulphur. . . . . . «| 0.220) 0.120} 0.422/ 0.113) 0.003] 1.480 Sum... . . . «| 98.690 100.000.100.489 99.583)100.623) 99.718 Undetermined and loss. . 133i! sae were | atnats eeerere 0.282 ERCOESSi hc uss? co tie) ES fe she aes 0.489) 0.417, 0.623 Metallie iron. 6. -:.|) 00854] 0.698) >.2-5 | Aee2 18 On86)] aeaae Aluming. |. 4. 2. +. | 0.505//0.841)0%.5. | -... | 1.434) -aezaa Determinations of the carbonate of lime and magnesia in these rocks were made independently by Mr. D. McCreath, and are as follows :— | No.1. | No.2 | No.3. | No.4. | No.5. | No.6. 2 | 73.60 | 86.39 | 91.67 (91.25 | 44.50 98 | 10.98 | 6.42 | 4.11 17:58 | 8.56 yoni Lume Woes | 0.760 | 5 | 0.196 | Calcium carbonate . . . 49. Magnesium carbonate | 42 SHINE Se SaAstigs|| | | i | Some sesquioxide. The author is indebted to Dr. Cresson for his courtesy in offer- ing him the facilities of his laboratory for this investigation. As a supplement to this table the following, taken from p. 113 1 Determined by Mr. Dayid McCreath. 2 By loss. 73.6 as determined directly by Mr. D. McCreath. 3 Mean of two determinations. 4 Determined by Mr. D. McCreath. 5 Some sulphide is present, as sulphydric acid is produced when the rock is treated with hydrochloric acid. 1876.] NATURAL SCIENCES OF PHILADELPHIA. 63 of my Report of Progress in the District of York and Adams for 1874." Limestones. 7. New Red S. 8S. near Dillsburg, foot of MacWilliams slope. 8. Opposite Allison’s Mill, Xenia P. O., York Co. 9. From Shaft No. 5, 2 mile east from Mont Alto Furnace. 10. Half a mile south of Seitzland, in a cutting of the N.C. R. R. (A calcite very similar to that above described as occurring on the upper bench of the Pine Grove Quarry is found here.) VII. VIII. IX. x Calcium carbonate . F : Sq) Fests) 62.35 77.89 93.87 Magnesium carbonate : . : 4.37 6.32 2.83 0.96 Metallic iron 5 5 : 0.52 b.20 13333 0.30 Insoluble siliceous residue } 21650 20.06 15.89 4.30 Sum : : : ‘ : = | 99-07 94.00 97.94 99.43 Oxygen, organic matter, water, and loss : : ' ‘ - : 0.48 6.00 2.06 6.57 APRIL 18. The President, Dr. RUSCHENBERGER, in the chair. Forty-four members present. On the Geologic Age of the Vertebrate Fauna of the Eocene of New Mexico.—Prof. Cope presented a synopsis of the species de- scribed from the Eocene of New Mexico, arranged in the following manner :— MAMMALIA. : : é - siete ae 54 Perissodactyla . : ‘ 3 eat 10 Amblypoda : : : He Pod 9 Pantodonta : ‘ i sho one Incerte sedis . Z : : Str 3 Quadrumana . : c : at 10 Prosimie . : : - Set) de Rodentia . : ; 3 , e- Fes 3 Insectivora : : ; é aT 19 Teniodonta ; ca more: Bestia ‘ : r : ses de Creodonta . - ‘ 3 snk a AVES ; ‘ : : F , oe es aie 1 ' These analyses were made by Mr. A. S. McCreath, Chemist of the 2d Geological Survey of Pennsylvania. 64 PROCEEDINGS OF THE ACADEMY OF [1876. REPTILIA 4 : 5 ‘ ‘ Ny es oe 24 Crocodilia 5 i 4 i Sens 7 Testudinata 5 5 3 : ee togs 15 Lacertilia . : : z a 2 Piscmsy © : - ; 3 f ae srar Ae 8 Ginglymodi_ . : : : owe 2 Plagiostomi . . : : apie 6 This total number of eighty-seven species may be considered in two aspects, viz., in regard to their geological position, and their anatomical structure. As regards the former, it may be observed, that the record preserved in these beds is doubtless more imperfect than that found in many others, owing to various physical conditions. One of these is an evident disturbance of temperature and moisture which they have sustained, perhaps in connection with the vol- canic phenomena which played so important a part in New Mexico during the later tertiary times. The fossils are generally found in a fragmentary condition, and often distorted by pressure. The fractures of the surface are often of such a kind as to indicate that the bones have been in a plastic state (see the figures of Stypolophus hians) during which the fissures thus created in them have in many instances been filled with a siliceous limestone. This material now presents a rough external surface of great hard- ness, and sometimes incrusts the teeth in such a way as to render it a difficult matter to expose them. Nodules of the same material abound on the bluffs (see the geological report). Not unfrequently the bones are covered with an incrustation highly charged with the red oxide of iron, and this substance gives its characteristic color to a large percentage of the fossils, the others being gene- rally black or dark brown. The light colors of our miocene beds are almost unknown, and the bones are always much harder than these, or even than the fossils of the Bridger group of Wyoming. These facts, in connection with the reduced number of exposures of the beds, account for the comparatively small number of species obtained, and the feeble representation of certain groups, e.g., the birds, lizards, rodents, etc. Nevertheless a large number of in- dividuals were obtained, and a considerable extent of country explored, and I believe that the synopsis above given is an approxi- mation to an expression of the characteristics of the most abund- ant types, or, of the relative numerical representation in the fauna of the different genera, orders, etc. Comparison with the established scale of geological horizons of . Europe has established the fact that the beds in question belong to the Eocene category, as I have already shown’ to be true of the longer-known Bridger beds of Wyoming. It remains to collate them with the numerous subdivisions of that period. The differ- ences between the Wahsatch and Bridger faunz have been in part 1 Proceedings American Philosophical Society, 1872, February and July. 1876. ] NATURAL SCIENCES OF PHILADELPHIA. 65 pointed out in my Report on the Vertebrate Fossils of New Mexico, 1874,’ and may be more fully stated as follows:— 1. Divisions found in the Wahsatch beds not yet reported from the Bridger beds. Aves, genus Diatryma (allied to Gastornis) ; mammalia, Teniodonta; Phenacodus; Coryphodon;’ Meniscothe- rium; most species of Hyracotherium. 2. Divisions found in the Bridger beds not yet found in the Wahsatch: fishes, Amadx; reptiles, Ophidia; Anostira; mam- mals, Mesonychiide; Tillodonta; Achenodon; Dinocerata; Pa- leeosyops ; most species of Hyrachyus. The Wahsatch horizon of Wyoming has not yielded so many species of vertebrata as those of New Mexico, but the close re- semblance of the two faunze may be observed in the following list of forms which I obtained at several localities: Fishes, Siluroids ; mammals, Hyracotherium, two species; Phenacodus; Coryphodon, two to three species. Asis well known, the Wahsatch beds under- lie those of the Bridger group, and we therefore look for their European equivalent in the lower part of the series. It has been already pointed out‘ that the absence of Hyopotamus and Anoplo- therium, and allied genera, from the Bridger horizon precludes an identification with the upper Eocene of Europe. The comparison of the Wahsatch fauna with that of the lowest of the three divi- sions into which Professor Gervais has arranged the European Eocene, shows a remarkably close correspondence. This epoch, the Suessonien of D’Orbigny (Orthrocene, Gervais), includes the marls of Rilly and lignites of Soissons, the Thanet sands, London clays, etc. Fossils from these beds appear to have been no better preserved than those of the Wahsatch beds of the Rocky Moun- tains, yet some of the genera are identical, and others closely cor- respondent, as follows :— Wahsatch. Suessonien, Ambloctonus. Paleonyctis. Hyracotherium. THyracotherium. Coryphodon. Coryphodon. Diatryma. Gastornis. Lepidosteus. Lepidosteus. Asa point of difference between the beds, may be mentioned the absence of the Teeniodonta from the Suessonien, a suborder not yet known out of North America. The Wahsatch formation includes the Geeen River beds of Hay- den, a name which I formerly used for the entire series. It, however, applies properly to the fish shales of Green River, con- 1 Annual Report of Chief of Engineers, p. 592. 2 The species described by me as Bathmodon constitute a section of this genus, characterized by the absence of tubercle or ridge between the inner cusps of the last lower molar. Ido not maintain this section as a distinct genus. 3 See Report of the U. S. Geol. Surv. Terrs., 4to., ii. p. 38-39. 4 Ann. Rept. U.S. Geol. Sury. Terrs., 1873 (1874). 66 PROCEEDINGS OF THE ACADEMY OF [1876. taining Asineops, Clupea, Osteoglossum, etc., which are probably local in their character. The Bridger formation will then represent on the American continent more nearly than any other, the middle Eocene or Pa- risien of Cuvier, Brogniart, and Renevier. The teeth of shar ks described in the reports quoted are of un- certain origin. They are associated with oyster shells, and both have the appearance of having been transported; nevertheless some of the mammalian teeth ‘found associated with them have a similarly rolled appearance. It therefore remains uncertain whether the ocean had for a limited time access to the Eocene lake, or whether the shark’s teeth and Ostrez were derived from the cretaceous beds which formed its shores. Similar, and in one instance the same species of sharks were found in both formations, the division of the cretaceous being No. 3 and 4 of Hayden.* In conclusion, the classification of the North American Kocene may be represented as follows :— Formation. Equivalent. Locality. Characteristic Fossils. Paleosyops. Bridger Form. Middle Eocene. S.W. Wyoming. Tillodonta. Dinocerata. (XE New Mest | Teniodonta Wahsatch Form. Lower Eocene. CO, S. W. Wyo-4 Erlagae Be Diatryma. APRIL 25. The President, Dr. RUscHENBERGER, in the chair. Forty-nine members present. The death of Geo. Washington Smith was announced. ‘ In conformity with Art. III. Chap. V. of the By-Laws, John L. LeConte, Geo. H. Horn, E. T. Cresson, Chas. A. Blake, Wm. S. Pine, John Meichel, Geo. B. Dixon, Horace F. Jayne, Charles Wilt, James Ridings, James H. Ridings, and J. W. McAllister, were constituted the Entomological Section of the Academy of Natural Sciences of Philadelphia. The meeting having adjourned until May 2, the consideration of certain amendments and additions to the By-Laws was then 1 The same state of things exists in the siderolitic deposits of the canton of Vaud, Switzerland. Mingled with the mammalian remains are teeth of sharks, of which M. La Harpe remarks that their appearance does not war- rant the belief that they have been transported, or are not indigenous to the Eocene fauna. 1876. ] NATURAL SCIENCES OF PHILADELPHIA. 67 concluded. The propositions to amend, with the signatures and reasons for the same, together with the report of the council upon suid amendments, were read, and Chapters I.-XI., inclusive, and Chapter XVI. were then adopted. The following were elected members: Oliver Bradin, Geo. A. Piersol, John Wister, Wm. Nelson, Rev. Charles A. Dickey, J. H. C. Simes, M.D., Wm. B. Brewster, M.D., Wm. H. Castle, Robt. Hess, M.D., and Pliny E. Chase. The committees to which they had been referred recommended the following papers to be published :— 68 PROCEEDINGS OF THE ACADEMY OF [1876. THE GENUS POMOXYS, RAFINESQUE. BY D. S. JORDAN AND H. E. COPELAND. Among the fishes sent by Prof. 8. A. Forbes from the State Normal University of Illinois to us for examination, were many specimens of Pomoxys, known in the Western States as “ Crap- pie.” We have prepared the following review of the species that have been referred to this genus, and append the synonymy for future reference. The genus was described in 1820 by Rafinesque, page 33 of his Ichthyologia Ohiensis, in these words: ‘ Body elliptic, compressed, scaly. Vent anterior. Head scaleléss, jaws plaited extensively, roughened by very minute teeth. Gill-cover smooth, scaleless ; propercule forked beneath ; opercule membranaceous and acute posteriorly. Thoracic fins without appendage, but a spiny ray. One dorsal fin opposite the anal, both with many spiny rays.” This description has been accepted as sufficiently accurate by most authors, and the genus adopted. Rafinesque referred to the genus one species, obtained at the Falls of the Ohio, with the following description, drawn undoubtedly from the same speci- mens that suggested the genus: “ Silvery; back olivaceous, with some geminate brown transversal lines; a golden ring at the base of the tail; lateral line straight; dorsal and anal fins with six spiny rays; a marginal black spot behind both fins; tail lobed; lower jaw longer. Length 3 to 6 inches. Diameter equal- ing three-tenths of the length.” He called his species annularis. In the * Report of the Zodlogy of Ohio,” Dr. Kirtland described the same fish under the name of Cichla Storeria, but dropped this name on information from Dr. Storer’ that Cuvier and Valen- ciennes had already described it under the name of Centrarchus hexacanthus. We have not seen Kirtland’s original deseription, but in November, 1840, in a report on the “‘ Fishes of the Ohio and its Tributaries,” in the “ Boston Journal of Natural History,” vol. iil. p. 480, he gave a description of the fish, made evidently partly from the specimen in hand, from which a good drawing was made (pl. xix., fig. 2), and partly from the real hexacanthus of C. and V., a fish that is now commonly placed in the genus Hyperistius of Gill. The localities he mentions show that he supposed Hyperistius 1876. ] NATURAL SCIENCES OF PHILADELPHIA. 69 and Pomoxys to be one fish, if the description was not conclusive. In the “ Memoirs of the Am. Acad. of Arts and Sciences,” new se- ries, vol. ii., 1846, Dr. Storer, in his “Synopsis of the Fishes of . N. A.,” p. 290, relying on the truth of the information he had given Kirtland, copied the latter’s description, with a brief addi- tion, and used the name Centrarchus hexacanthus. He gave data of two specimens, one a Hyperistius, and the other a Pomoays. The localities and synonymy quoted referred to Hyperistius, Pomoxys, and what may have been Centrarchus irideus. In 1854 Professor Agassiz, in The Fishes of the Tenn. River,” p. 4 (of reprint), referred a specimen sent to him from that river, to Pomoxys annularis Rafinesque, saying it ** agreed fully” with his description, except in wanting the ring at the base of the tail. How Professor Agassiz overlooked the statement that the head and gill-covers are “scaleless,”’ is not easily accounted for by us. There can be no doubt, however, about his course in the event of his recognizing this as an error, for he had then taken the ground, since occupied by all our naturalists, that it is better to eliminate error from a recognizable description than to propose a new genus or species. In the Zoological report in the Pacific Railroad Reports, 1858, vol. x.p. 5, Girard reviewed the genus in his characteristic way. He arranged his material in the following manner, that we give in full to show the confusion into which the synonymy was falling :— 1. Pomoxis sparoides, Grd. = Labrus spar, Lac. Centrarchus spar. C. and Y. J: hexacan. Holb. Ich. S. C., pl. 6, fig. 1. 2. Pomoxis nigromaculatus, Grd. = Cantharus nigromac. Le Sueur, fide C. & VY. = Cichla Storeria, Kirt. 3. Pomoxis annularis, Raf. ** described, or rather recorded, by Rafinesque.”’ 4. P.nitidus, Grd. Pl. ii., figs. 5-8 (new species). We are not bold enough to tell what this all means, except that Pomoxis nitidus, Grd., surely is Pomoxis annularis, Raf. In the * Proc. Ac. Nat. Sc. of Phila.,’”’ 1865, p. 64, Professor Gill gave a “Synopsis of the genus Pomoxys, Raf.,’” “ to dissipate the confusion.”’ He cleared away, in a satisfactory manner, the mistakes of his predecessors, coming to the undoubtedly correct 2 70 PROCEEDINGS OF THE ACADEMY OF [1876. conclusion that but one species of Pomoxys was yet known, call- ing that storerius, for reasons following, and added three new nominal species of his own. Of storerius he says: “This species has been quite unfortunate in its nomenclature ;” and, “ This spe- cies was first intelligibly noticed by Dr. Kirtland, who, in the ‘Report on the Zodlogy of Ohio,’ introduces it under the name of Cichla Storeria;” and *“‘ the name Cichla Storeria must therefore be accepted as the specific appellation of the species described by Dr. Kirtland if Rafinesque’s is deemed unworthy of adoption.” As between the specific descriptions of Rafinesque and Kirtland, on comparison of a specimen from the Ohio with each, I have no hesitation in saying that Rafinesque’s is the better of the two. Without, therefore, resorting to the unanswerable argument that since there is but one species of Pomoxys in the region reported on by the two men, and that, therefore, Rafinesque’s specific name must stand on as good footing as his generic name, we retain annularis on the ground of its accompaniment by a prior and recognizable description. In regard to the three new “species,” we find by an examina- tion of the specimens from Normal, labelled as from the streams of Central and Southern Illinois, the following data:— The variation ranges in the dorsal spines from vy. to viii.; in the dorsal rays from 14 to 16; in the anal spines from v. to vi.; in the anal rays from 16 to 19; in the scales in the lateral line from 39 to 48. The first dorsal spine goes in the diameter of the eye from 4 to 14 times; the*length of the caudal peduncle is to its height as 19 to 13, or as 16 to 16. Specific characters, based on the number of dorsal spines, the size of the scales, the ratio be- tween the first dorsal spine and the diameter of the eye, or between the height and length of the caudal peduncle, are clearly untenable, falling within the range of individual variation, and therefore Pomoxys brevicauda, Gill, Pomoxys intermedius, Gill, and Pomoxys protacanthus, Gill, fall into the list of synonyms of Pomoxys annularis, Rafinesque, it being the only species of Pomoxys now known, unless Hyperistius prove to belong here. The following is the synonymy of the species, with the localities and common names :— 1876. ] NATURAL SCIENCES OF PHILADELPHIA. 1 PoMOXYS ANNULARIS, RAFINESQUE. Crappie (West), New Light (Ky.) Bachelor (Falls of the Ohio). Pomowis annularis, Raf. Ich. Oh. 1820, 33. (Falls of the Ohio; Ky.).— Ag. Fish. Tenn. 1854, 4. (Tenn. River.) —Grd. Pac. R. R. Rep. X. 1858, 6. “ Cantharus nigromaculatus, Le Sueur, fide C. and V. Hist. Nat. Poiss. IIT. 1829, 88’? (fide Grd.). (Wabash River, where Hyperistius is not found.) Cichla Storeria, Kirt. Rep. Zo6l. Ohio, 191 (fide Kirt.). Centrarchus hevacanthus, Kirt. Bost. Journ. Nat. Hist. ITI., 1840, 480, Pl. XXIX. (plate; dese. in part). (Big Miami River.)—Storer, Mem. Am. Ac., new ser. II., 1846, 290. (in part), (not of Cuv. and Val. fide Gill). Pomowxis nitidus, Grd. Pac. R. R. Rep. X. 1858, 6 Pl. II., Fig. 5-8. (Hous- ton River, Ky.) Centrarchus nitidus, Giinther, I. 1859, 257. Pomoxys storerius, Gill, Pr. Phil. Acad. 1865, 64.—Cope, Pr. Am. Philos. Soc. 1870, 251. (Missouri Riv.)—Jordan, Geol. Sury. Ind. 1874, 215. (White River. ) Pomoxys brevicauda, Gill, Pr. Phila. Ac. 1865, 64. (North Grand Riy., Mo.) Pomozys intermedius, Gill, Pr. Phila. Ac. 1865, 64. Pomoxys procanthus, Gill, Pr. Phila. Ac. 1865, 64. (Tarboro, N. C.) Pomoxys annularis, Jordan, Fishes Ich. Oh. : (Bull. Buff. Soc. Nat. Hist., April, 1876, p. 89) ; Manual Vertebrates E. U. 8. (in press)—Jordan and Copeland, Check-List N. Am. Fresh Water Fishes (in press). Habitat.—Basin of the Ohio, Illinois, Missouri ; probably in all the tribu- taries of the Mississippi. Not in the great Lakes? In North Carolina (fide Gill). 72 PROCEEDINGS OF THE ACADEMY OF [1876. CHEMICAL NOTES. BY GEORGE HAY. I. On the Decomposition of Stannous Chloride in a Geissler Tube. While observing, in company with my friend, Dr. Wm. M. Her- ron, the spectrum of chloride of tin through a powerful spectro- scope of four prisms (Browing’s make)—the Geissler’s spectrum- tube used for the purpose being illuminated by the spark from a large Ruhmkorff’s coil connected to six cells and a Leyden jar and a tin foil condenser, the spark being capable of passing six inches in air—the following facts were noted :— The constricted portion of the tube became hot—the spectrum became gradually feebler and feebler and ultimately ceased—a va- cuum had formed within the tube so perfect that the spark would not pass. On examining the tube I found a metallic deposit or mirror of extreme thinness, but having the well-known metallic lustre de- posited upon the glass at the negative end. The wire inside of the tube at the positive end was tarnished, and had lost its metallic lustre, and was covered with a white though thin incrustation. I too hastily concluded that this was anhydrous proto-chloride of platinum, and thank Dr. Koenig for his communication correcting me, as shall appear anon. I had no time just then to investigate further—hence the mistake. I have used up the tube in making the following observations :— Before opening the tube I heated the end containing the mirror and found that it did not sublime. Cut off the tube half an inch above the film, and noticed that the wire within the tube at this end was fused to a globule of the size of a pin-head adhering-to the glass projecting within the tube, through which the wire passed. Introduced one drop of concentrated hydrochloric acid, and, upon spreading this drop over the film and slightly warming, the film dissolved completely. Rinsed out the solution with water into a small evaporating basin, and evaporated to a few drops, to concentrate as much as possible and remove the large excess of acid. 1876.] NATURAL SCIENCES OF PHILADELPHIA. 73 Treated one dropin a watch glass with hydrosulphurie acid, and got a few brownish-yellow flakes soluble in potash. Treated an- other drop in a watch glass with hydrosulphuric acid, and intro- duced fluid and flakes into a narrow tube closed at one end, and evaporated in an air bath—heated this, but only a little free sulphur sublimed, leaving a few grayish flakes in the bottom of the tube. Chased back the sulphur to the bottom of the tube, and covered it and the minute flakes with powdered dry ferrocyanide of potassium and heated again, but, as might have been expected from former experiment upon original mirror, got no mirror anew. Treated another drop with nitric acid, and got upon evaporation the slight- est observable white film -insoluble in nitric acid. Chloride of mercury yielded a white opalescence. The quantity of metal was so exceedingly small that, had I not experimented upon single drops, I should have got nothing in the way ofa reaction. I got no reaction with gold, owing to the extreme minuteness of the quantity of metal. I do not believe that I could have weighed the quantity of metal composing this delicate mirror, but I did not attempt it. It must be remembered that all the chloride of tin within the tube originally was only a vacuum of its vapor; but it yielded the spectrum of chloride of tin, and it is well known that the spectroscope will yield certain results where ordinary chemical tests fail altogether. The tarnished wire at the other end of the tube was not fused. Scraped off a little of the tarnish with a penknife blade into a small watch glass and added one drop of water, but the flakes did not dissolve. To make sure whether the drop of water mentioned had dis- solved any chloride, added asmall drop of nitrate of silver solution, but obtained no opalescence. Scraped off the whole of the white tarnish and digested with a few drops of strong hydrochloric acid, and got thus a clear solu- tion. One drop of this solution treated with hydrosulphuric acid gave no precipitate. Another drop treated with ammonia yielded a few gelatinous-looking flakes soluble in caustic potassa. This white substance, therefore, appeared to be alumina, but, as in the case of the metal, there was extremely little of it—it had probably been chloride of aluminium, and, with the residual air or perhaps some moisture in the tube, had been converted into the oxide at the high temperature produced by the spark, a tem pera- 6 74 PROCEEDINGS OF THE ACADEMY OF [ 1876. ture sufficiently high to fuse the wire at the other end under the protecting influence of the mirror already mentioned. Within the tube at this end I found the wire consisted of aluminium, and outside of the tube at the same end it consisted of platinum, which had, I suppose, been joined to the aluminium by fusion. The tin salt was undoubtedly decomposed by electrolysis even when exist- ing as an attenuated vapor. II. On the Solubility of Tin, Arsenic, and Antimony in concen- trated Nitric Hydrate at 36° F. The following facts have never, so far as I am aware, been pub- lished, either by myself or by any one else. I have already commu- nicated to the Academy that the metal tin is soluble in a mixture of pure concentrated nitric acid and water in equal volumes. What I have now to communicate is, that tin forms with the undiluted acid a soluble salt, viz. the proto-nitrate of tin. The circumstances under which the salt was formed were as follows: Into a dry test-tube I poured a small quantity of pure concentrated nitric acid, and then set the tube containing the acid afloat in a vessel of water at a temperature of 36° F. Into the acid I dropped a fragment of pure tin; it became coated with a white substance, and in the course of fifteen minutes was entirely transformed into this white substance. Several fragments of tin were added at the above intervals, and all were transformed into this white subtance. The action of the acid had now become less decided, although the fluid was still strongly acid, and the contents of the tube presented a gelatinous appearance resembling the re- cently precipitated hydrate of alumina. It seemed doubtful whether I had not merely obtained the ordinary hydrate of me- tastannic acid. Upon the addition of about two volumes of water the whole of the white substance dissolved to a clear and colorless fluid, therefore holding the tin in the solution and proving that the white substance was not the hydrate of metastannic acid. The solution was tested as follows :-— Ist. A portion was boiled and the whole of the dissolved metal was precipitated as hydrate of metastannic acid. 9d. After neutralizing a portion of the free acid, hydrosul phuric acid caused the precipitation of proto-sulphide of tin mixed with sulphur. 1876.] NATURAL SCIENCES OF PHILADELPHIA. 75 3d. To a portion of the original solution was added solution of chloride of mercury, and in the course of a few hours a white pre- cipitate formed consisting of sub-chloride of mercury. 4th. Chloride of gold gave no precipitate. 5th. Potash soiution gave a white precipitate soluble in excess of potash. 6th. A mixture of ferricyanide of potassium and sesquichloride of iron was made, and to this mixture was added a portion of the original solution—the result was the production in a few hours of prussian blue. These tests were, in my opinion, retarded by the presence of a large excess of nitric acid, and the production of purple of Cassius was altogether prevented by the presence of an excess of this acid. All the other tests were perfectly satisfactory. To obviate the difficulty occasioned by the presence of a large excess of free nitric acid, a fresh solution was prepared by adding the metal to the acid until the contents of the tube had become thick and pasty, and there appeared to be little or no action going on, the tube being kept, as before, surrounded by water at 36° F, Water was now added to the pasty mass, but in this instance a not very considerable portion of white substance was left undis- solved. The solution was filtered, and to the clear filtrate was added— Ist. Hydrosulphuric acid. This yielded a brown precipitate soluble in solution of potash, and reprecipitated brown on addition of dilute hydrochloric acid. 2d. Potash yielded a white precipitate soluble in excess of pot- ash. 3d. Chloride of gold yielded a beautiful and strong coloration of purple of Cassius after addition of a drop of dilute hydrochloric acid in five minutes, and when the tin solution was not too dilute the purple of Cassius was precipitated at once. 4th. Chloride of mercury yielded a white precipitate of sub-chlo- ride of mercury immediately. 5th. To a mixture of ferricyanide of potassium and sesquichlo- ride of iron, a portion of the clear filtrate was added, and almost immediately prussian blue was formed. 6th. Boiling the original filtrate caused the precipitation of the tin as hydrate of metastannic acid. The above experiments prove that not only is tin converted into 76 PROCEEDINGS OF THE ACADEMY OF [ 1876. a soluble salt by concentrated nitric acid, but that proto-nitrate of tin is fofmed. Pursuing my investigations still further with regard to the action of nitric acid upon the group of metals usually said to be oxidized, but not dissolved or converted into salts by it, I next experimented upon antimony. Into a dry test-tube I poured about 2 c.c. of concentrated nitric acid, and then dropped into the acid about 20 grains of powdered antimony. The tube was immediately set afloat in a vessel of water at 36° F. and allowed to remain for about 12 hours, being shaken occasionally to diffuse the powder through the acid. At first there appeared to be no change produced, but by and by the fluid became distinctly green, and by the end of 12 hours a strongly green solution was obtained. On decanting this green fiuid from the powdered metal and diluting it with water, a bulky and abun- dant white precipitate was produced, showing that a large pro- portion of the antimony had been dissolved in the nitric acid, and in this respect it appeared to behave like nitrate of bismuth when diluted with water. In order to ascertain in what state of com- bination the antimony was held, the following experiments were made. Tartaric acid was added to the fluid containing the precipitate, and it at once dissolved to a colorless fluid. The fluid was now filtered in order to remove any particles of undissolved metal which might have been decanted. Ist. After neutralizing a portion of the free acid in a portion of the filtrate, a strong solution of hydrosulphuric acid was added —the result was a bulky, orange-red, unmistakable precipitate of tersulphide of antimony, readily soluble in potash, and reprecipi- tated from its alkaline solution by dilute hydrochloric acid. 2d. To another portion of the filtrate, potash was added, and a white precipitate of teroxide of antimony was obtained soluble in excess. 3d. To the alkaline solution last obtained, nitrate of silver was added, and there was obtained a jet-black precipitate of suboxide of silver insoluble in excess of ammonia—this being distinctive of teroxide of antimony. 4th. Neutralized another portion of original filtrate by ammonia to remove free nitric acid, and then acidulated with hydrochloric acid. Puta drop or two of the solution thus obtained upon a 1876. ] NATURAL SCIENCES OF PHILADELPHIA. TT clean surface of platinum, and introduced a fragment of zinc—the result was a dark-brown or black stain of metallic antimony not removable by cold hydrochloric acid, but removable by hot nitric acid. These four tests show that the original solution contained ter- oxide of antimony, and, as the solution was obtained by means of nitric acid, the probability is that it was a ternitrate of antimony, for a large quantity of the metal was dissolved. The HS precipi- tate was so bulky as at first almost to fill the test-tube. The solution of antimony in nitric acid kept cold will not bear dilution with water except in presence of tartaric or hydrochloric acid. Boiling the original green solution gave an abundant white pre- cipitate of antimonic acid accompanied by copious evolution of orange-red fumes. Boiled till the red fumes had disappeared— diluted and filtered—the filtrate did not pass through clear, but on passing twice more through the same filter was obtained a per- fectly clear filtrate. This filtrate gave every one of the four tests above-mentioned with the utmost readiness, 7. e., it yielded in succession tersulphide of antimony, teroxide of antimony, sub- oxide of silver, and metallic antimony, and therefore held in solu- tion even after formation and precipitation of antimonic acid by boiling a large quantity of teroxide of antimony dissolved in nitric acid, or existing as ternitrate of antimony. In this case no other acid but the nitric had been used. I now experimented upon arsenic in the same manner, 7. e., by keeping the pure metal (not pulverized) for 12 hours in contact with pure concentrated nitric acid at 36° F. The result was a beautiful transparent green solution of the entire quantity of metal. This solution yielded every one of the tests for arsenic acid. Ist. After reduction by sulphurous acid and partial neutraliza- tion, it yielded upon addition of hydrosulphuric acid the tersul- phide of arsenic. 2d. After complete neutralization, and addition of sulphide of ammonium, followed by addition of hydrochloric acid, it yielded the pentasulphide of arsenic. ; 3d. After addition of nitrate of silver and a small quantity of ammonia, it yielded the reddish-brown precipitate of arsenate of silver. 78 PROCEEDINGS OF THE ACADEMY OF [1876. 4th. In similar circumstances, 7. e., after neutralization by am- monia and addition of sulphate of copper, it yielded the greenish- blue precipitate of arsenate of copper. 5th. Neutralized and then mixed with a large excess of concen- trated hydrochloric acid and boiled with a slip of clean copper, a dark-gray film was deposited on the metal. 6th. Neutralized and added a clear mixture of sulphate of magnesia, chloride of ammonium and ammonia, it yielded at once a crystalline precipitate of arsenate of ammonia and magnesia. The original green solution was therefore either simple arsenic acid or a pentanitrate of arsenic. The curious fact is here observed that these three metals, arsenic, antimony, and tin, when treated with cold concentrated nitric acid kept cold, oxidized in the relation of their several vola- tilities—arsenic yielding either a pentanitrate? or merely arsenic acid, antimony yielding a ¢ernitrate, and tin a protonitrate; while the other curious fact is also to be observed that on boiling the original solutions all the arsenic remains in solution, a consider- able portion of the antimony remains in solution, and none or only the merest trace of the tin remains in solution. I ought to have mentioned in my last communication that the tin employed was not granulated but only cut by a sharp knife from a bar in order to prevent too rapid action of the acid upon the metal. I found it necessary on the other hand, to pulverize the antimony, as without this the action was hardly visible—the arsenic was used in large crystals. Note upon Mr. Hay’s Paper. By Guo. A. Koente, Ph.D. The reaction of nitric hydrate upon arsenic at 36° F. results, according to the author, in the exclusive formation of arsenic acid or arsenic pentoxide. This is not substantiated by his experi- ments. He certainly proved the presence of the pentoxide, but does not speak of any test for the teroxide, the presence of which does not interfere much with the other reactions. It isa fact well known by chemists, that a continued digestion of the teroxide is needed with concentrated nitric acid to change it into pentoxide, and some authors state distinctly that arsenic is changed by nitric acid both into the teroxide and pentoxide. Since it is known that by the action of nitric acid upon metals _ ee 1876. ] NATURAL SCIENCES OF PHILADELPHIA, 19 heat is generated, and also that antimony and tin are precipitated by heat from their nitric or other acid solutions, it was not aston- ishing to find those metals go into and remain in solution, by abstracting the heat with a cooling liquid in such measure as heat was generated. In the case of tin, dilute nitric acid is known to dissolve it as protoxide, and here the water in the acid prevents the heating; in using concentrated acid and applying a cooling liquid at the out- side of the vessel, the conditions remain unchanged, and only the application is different. 80 PROCEEDINGS OF THE ACADEMY OF [ 1876. May 9. The President, Dr. RuscHENBERGER, in the chair. Twenty-six members present. The following papers were presented for publication :— “Fourth Contribution to the History of Existing Cetacea,” by Edw. D. Cope. “ Zoological and Biological Methods of Research,” by Harrison Allen, M.D. Remarks on Fossils from the Ashley Phosphate Beds.—Prof. LeiIpy observed that the so-called phosphate beds of Ashley River, South Carolina, were remarkable for the singular admix- ture of multitudes of fossils of different ages, from the early ter- tiary period inclusive down to the present epoch. The phosphatic nodules, for which the beds are explored, appear to have had their origin from the eocene rocks beneath. These have also contributed numerous remains of marine vertebrates especially of squalodonts, reptiles, and fishes. Mingled in the sand and clay with the phos- phatic nodules and bones of eocene animals, are innumerable remains of cetaceans, sharks, and other marine animals of perhaps the middle and later tertiary ages. Added to these are multitudes of remains of both marine and terrestrial animals of the quaternary period. Pell-mell are found together bones of eocene squalo- donts, animals related with the whales and seals; hosts of teeth of the great shark Carcharodon angustidens ; myriads of the teeth of the giant of sharks of the tertiary period, the Carcharodon megalodon; bones and teeth of whales and porpoises; and abund- ance of remains of elephant, mastodon, megatherium, horse, etc. ; and occasionally the rude implements of our more immediate | ancestors. From among a collection of fossils, from the Ashley phosphate beds, recently submitted to his inspection by Mr. J. M. Gliddon, of the Pacific Guano Company, the specimens were selected which lie upon the table. One of these is a well-preserved tooth of a Megatherium; another, a characteristic portion of the skull of a Manatee; athird,a complete tusk of the Walrus; indicating a still further point south for the extension of this animal than had been previously known; fourth, a huge tooth of a cetacean allied to the sperm whale, probably the same as those from the crag of Antwerp ascribed to Dinoziphius. Besides these there are the beaks of three cetaceans of the little known family of the Ziphioids. These are porpoise-like animals without teeth in the upper jaw, and usually with but a single pair of teeth in the lower jaw. The beaks com- posed of the co-ossified bones of the face are remarkable for their 1876. ] NATURAL SCIENCES OF PHILADELPHIA. 81 ivory-like density which probably rendered them VGH as weapons of defence. A fourth beak from the same locality, presented by Nes Cost Bement, belongs to a different species of the same family. The beaks and some associated fossils will form the subjects of a paper shortly to be presented to the Academy. The beaks have been referred to species with the following names and brief distinctive characters :— CHONEZIPHIUS TRACHOPS.—Supra-vomerian canal open. Inter- maxillaries co-ossified. and forming a crest along the middle of the beak extending to the interval of the prenareal fosse. Maxillaries with a rugged tract at the upper part of the base of the beak. CHONEZIPHIUS Liops.— Beak proportionately of less length than in the preceding. Supra-vomerian canal and intermaxillaries the same, except that the crest of the latter in front is acute. Maxil- laries without the rugged tract at base. EBOROZIPHIUS COELOPS.—A new genus as well as species. Beak above forming a broad gutter as in Hyperoodon, and not divided by an intermaxillary crest as in the preceding. Maxillaries with prominent lateral crests at base, convex inwardly. Right prena- real fossa occupied by a thick osseous disk. Intermaxillaries co- ossified. Supra-vomerian canal open. BELEMNOZIPHIUS PROROPS.—Beak solid, with all traces of the original separation of the constituent bones and the ossified mes- ethmoid cartilage obliterated. Fish Remains of the Mesozoic Red Shales.—Prof. Lrtpy re- marked that the remains of life of any kind were exceedingly rare in the mesozoic red shales which cross our State about fifteen miles north of us. Hence any fossils whatever from these rocks were of interest. The three cycloid fish scales, and a few detached caudal rays, in the fragments of red shale, presented by him this evening, he found on the Perkiomen Railroad, near Yerkes’ Station, Montgomery County. One of the scales resembles those described by the late Prof. E. Emmons, under the name of Rabdiolepis elegans, from the mesozoic coal shales of Chatham Co., N.C. Botanical Correspondence of Zaccheus Collins.—Mr. REDFIELD called the attention of the members to the volume of letters of Zaccheus Collins which had been recently arranged and bound. Mr. Collins was well known in his day as an active philanthropist and as a zealous cultivator of natural science. He was early a member of the American Philosophical Society, was elected a member of the Philadelphia Linnean Society, in 1809, before this Academy was founded, became a member of our Academy in March, 1815, and was one of its Vice-Presidents at the time of his death in 1831. He devoted himself especially to the sciences of Botany and Mineralogy, and the letters of the most eminent botanists of that time show how highly they valued his know- 82 PROCEEDINGS OF THE ACADEMY OF [ 1876. ledge, and how eagerly they sought his advice upon all doubtful questions in their science. Mr. Nuttall complimented him—by naming for him the genus Collinsta—containing some plants of exquisite beauty, and now represented by eleven “North American species, mostly Californian, but of which the earliest known was discovered in the valley of the Ohio. The volume now before us contains an unbroken series of sixty letters from Rey. Henry Muhlenberg, of Lancaster, to whom American botany has been so much indebted, also a correspondence with his son Fred. Aug. Muhlenberg, in which we find the history of the transfer of the Muhlenberg Herbarium to the American Philosophical Society. There are also numerous letters from Stephen Elliott, author of a sketch of the Botany of South Caro- lina; from Dr. Jacob Bigelow, author of Florula Bostoniensis, and still surviving; from Dr. Wm. P. C. Barton, author of the Compen- dium Florze Philadelphicee ; from Dr. Wm. Baldwin, the talented and lamented young botanist, who died upon Long’s Exploring Expedition; from Nuttall, Torrey, Leconte, Sr., and many others well known to the scientific world. It cannot be expected that these letters of sixty years ago can add any new botanical facts to our stock; but they have great interest as illustrating the early history of botanical science in our land, and as revealing tous the obstacles which the students of that day encountered in the scarcity of books, and in the difficulty of communication. Mineralogical Notes; Hydrotitanite, a New Mineral.—Dr. Grorce, A. Ka@niG communicated the results of an investigation on a changed garnet and a changed perowskite, from Magnet Cove, Arkansas. A short time ago he had called the attention of the Academy to the occurrence of opaque nuclei observable in microscopic slides of garnets, in which by analysis 6 per cent. of titanic acid was found. He had obtained recently, through the kindness of Dr. Foote, a fragment of a garnet crystal weighing about three ounces, on which the faces of the dodecahedron are visible, and concentrically a nucleus, contrasting by its bright pitchy lustre with the dirty circumferential part of the crystal. The line of contact is apparently very well defined, but on pro- ducing on it a fresh fracture, no difference in color and lustre and no line of division can be seen. The streak of the centre is reddish-gray, that of the circumference light greenish-gray. Start- ing with the hypothesis of a gradual change from inside towards the outside, or, vice versa, a cut was made through the crystal, about parallel with one of the principal planes of symmetry, and thus a slice was obtained half an inch thick; this was divided radially into three sections, and one of these was cut into five parts at equal distances from the centre. On reducing the pieces to powder, each by itself, a very gradual change in color was noticeable from the reddish-gray of the central part to the greenish- 1876. ] NATURAL SCIENCES OF PHILADELPHIA. 83 gray of the circumference. 0.5 gr. of each sample was fused with 5 grs. of sodium hydro-sulphate, the solution reduced with hy- drogen sulphide, after filtration, diluted to 700 c. c. of volume and boiled. Numbering the samples 1, 2,3, 4,5 from centre to circum- ference, the author obtained precipitates by boiling, of respectively 25.00, 16.2, 9.2, 6.0, and 5.0. These precipitates were titanic acid with normal reactions in numbers 3, 4, and 5; very abnormal in number 1, and less in number 2. The description of the purely chemical investigation into the nature of those abnormal reactions will be reserved for a future memoir. In order to obtain more light upon the cause of this gradual decrease of titanic acid from centre to circumference, one of the sectors was ground to a microscopic section, which showed a banded structure at the circumference with a few opaque crystal- line fragments imbedded, but besides this the material appeared homogeneous, the color only changing from light-brown, very gradually into black opaqueness. Had the banded structure con- tinued to the core, the explanation might be looked for in the growing of the crystal at intervals in solutions of different com- position, but the change being so gradual, the author is inclined to believe in a metamorphic action from the centre. The chemical fact that titanic acid does not replace one or two of the consti- tuents, as revealed by further investigation, but that silicon, iron, and calcium diminish in the same proportion as titanic acid in- creases, speaks in favor of the metamorphosis by intrusion of titanic acid. The crystals of perowskite, pure octahedrons, or octahedrons modified by the cube, are often found to have yellowish-gray spots much softer than the rest of the mineral, and, in some instances, the whole crystal is composed of the same yellowish-gray sub- stance. The specific gravity of one of these crystals was found to be 3.681 ; nearly 0.2 less than the fresh mineral. An analysis of the same made with 6.5 gramme, gave the following:— Gs —— Via. 82 Be OR ss i 16 MeO) ==" 1p 22 a0: =, | 0.80 BG). =" 5.50 Vd Undetermined, but distinct reaction. 99.60 By metamorphic action nearly all the calcium and some iron have been removed, and water added. The result is a new mineral for which the name /Hydrotitanite is herewith proposed if the analysis of more specimens should prove the constancy of the composition. 84 PROCEEDINGS OF THE ACADEMY OF [1876. On the Microscopic Observation of Minute Objects. — Prof. FRAZER remarked, that he desired simply to put on record a thought relating to Helmholtz’s now famous establishment of the limit of vision through the microscope. As this limit was determined by half the length of a wave of light and since the wave-lengths of the most refrangible rays of the light spectrum (7. e. the violet) are somewhere near the 1-57000th part of an inch, the conclusion was reached that nothing more minute than the 1-114000th part of an inch could be seen. But actinic waves or others of smaller length (of greater refrangibility too) in pass- ing through a substance on which are lines or other markings less than 1-114000th inch apart, may be altered to light waves, and become visible, provided, that the substance through which they pass is capable of fluorescing, 7. e., increasing their wave length, and provided the distance apart of the marks to be seen is not less than one-half the wave length of such actinic waves. The meeting having adjourned until May 16; the following were then elected members of the Council :— For three years—Edw. 8. Whelen, R. S. Kenderdine, M.D., J. H. Redfield, J. G. Hunt, M.D. For two years—Geo. H. Horn, M.D., Jos. Wharton, Jos. Jeanes, Geo. A. Keenig. For one year—Geo. Vaux, J. 8. Haines, W. H. Dougherty, Harrison Allen, M.D. May 16. The President, Dr. RuscHENBERGER, in the chair. Thirty-four members present. The “ Sleep of Plants” as an Agent in Self-Fertilization.—Mr. Tuomas MrenAN said that what is popularly known as the “ sleep of plants,” the closing of some kinds of flowers at nightfall, though a matter within common observation, had not, so far as he was aware, been made a subject of physiological investigation, with the view of ascertaining the value, if any, of this kind of motion in the economy of plant life. He had recently discovered that by means of this peculiar motion the common “Clay tonia Virginica and some bntter-cups were fertilized by their own pollen. The fertilization of these plants had been somewhat of a mystery to him, as, in view of some prevailing theories of cross-fertilization by insect agency, these plants ought not to be self-fertilizers ; but from repeated observation he was satisfied that no insects had visited plants that had yet seeded abundantly. Watching the process of fertilization in Claytonia, he found the stamens on 1876. ] NATURAL SCIENCES OF PHILADELPHIA. 85 expanding fell back on the petals expanded during daylight. At night, when the flower closed, the petals drew the anthers up in close contact with the pistils. Cross fertilization could be accom- plished by insects if they visited the flower, but they did not; and actual fertilization only occurred in this way. In many cases, especially in the advance of the season, the stamens recurve so much as to be in a measure doubled up by the nocturnal motion of the petals. The anthers were not drawn into contact with the stigmas in these cases, and the flowers were barren as the result. In the Ranunculus bulbosus, our common butter-cup, in the evening following the first day’s expansion of the young flower, the immature anthers and _ the young stigmas would be found covered with pollen grains. The inference would generally be that this had been carried there by insects. But as he had been especially on the lookout for insects as visitors to the butter-cup, and feeling sure that none of any consequenee had been to them, he examined these flowers carefully, and found that on the first expansion of the flower a single outer series of stamens burst their anther-cells simultaneously with the expansion of the flower, and, by contracting the cell-walls, ejected the polien to the smooth petals, from which it easily fell to the immature anthers and stigmas, when the flower closed for the night. Knowing that another species of butter- -cup, the Ranunculus abortivus, had fixed spreading petals which did not close at night, and which, though with comparatively large nectariferous glands full of a liquid secretion, was wholly neglected by insects, and yet had every flower seeding profusely, he was anxious to find, in view of his other discoveries, how these were fertilized. Visiting a wood after twilight, to ascertain if any nocturnal insects visited them, he found that though the petals ‘did not close at sundown, the slender pedicles drooped, inverting the flower, and in this way the pollen found its way from the petals to the stigmas with- out any difficulty whatever. Plants, of course, had peculiar functions to perform, and there were pre-ordained plans and special arrangements through which these functions are exercised. But the workings of plant life are so complicated, that, though we see certain results follow certain movements, we are not always sure that we perceive the great and deeper object aimed at in the order of nature. Hence arose the differences of opinion prevailing in regard to the object of cross fertilization. Some plants had arrangements which seemed to preclude the possibility of self-fertilization, and the assumption followed that nature abhorred close breeding in plants, and spe- cially designed such structures to secure the plant against it. He believed that nature hada deeper purpose, as yet unknown : and chiefly because of just such instances as he had given this evening, where nature could not abhor close breeding, when the result of the “sleep of plants” was most perfect in securing self- fertilization. 86 PROCEEDINGS OF THE ACADEMY OF [1876. May 23. The President, Dr. RuscHENBERGER, in the chair. Thirty-seven members present. A paper entitled Further Notes on Inclusion in Gems, ete.,” by Isaac Lea, was presented for publication. Remarks on Fossils of the Ashley Phosphate Beds.—Prof. Leimpy observed, in continuation of his remarks of the previous meeting, on the extinct animals of the Ashley phosphate beds of South Carolina, that they are remarkable for the multitude of remains they contain of fishes, especially of sharks and rays. Among the former were the giants of their kind, the Carcharadon megalodon and C. angustidens. A tooth exhibited of the megalo- don shark is 54 inches long and 43 inches broad at the base. The living white shark, pertaining to the same genus, reaches upwards of 35 feet in length and has teeth 2 inches in length. Supposing the megalodon shark to have reached the same proportions in relation with the size of the fossil teeth, it must have exceeded 70 feet in length, and must have proved the most formidable monster of the ancient ocean. Another specimen, presented for the inspection of the members, is a knob of bone, such as is found at the root of the tail of the devil-fish, the largest of the existing rays. In the latter, the bone is the only one of the body, and it supports a minute spine, a mere rudiment of the barbed weapon of the sting-ray. Our devil-fish, of which a specimen was once exhibited in Peale’s Museum of this city, reaches a breadth of 18 feet with the length about 15 feet. The fossil-bone, though the only thing left to tell the tale of its former possessor, is quite a char acteristic specimen. It is of more robust proportions than that of its living representative, and pro- bably indicates an extinct species for which the name of Cerato- plera unios was proposed. Specimens exhibited of the dental armature of the roof and floor of the mouth of eagle-rays were referred to extinct species under the names of Myliobates magister and M. mordax, the former having been one of the largest of its kind. Similar speci- mens from the eocene marl beds of Monmouth and Burlington Counties, New Jersey, were refered to species with the names of Myliobates fastigiatus and M. jugosus. Prof. Leidy further directed attention to a specimen of the snout of an extinct cetacean, which he had recently observed among some fossils from the Ashley beds in the Smithsonian collection of the Government Departinent of the Centennial Exposition, and which had been obligingly loaned to him for description by Mr. ——————— ee eee 1876. ] NATURAL SCIENCES OF PHILADELPHIA. 87 W. P. Blake. The specimen, 24 feet in length, had the density of ivory, and indicated one of the largest of the little known family of the ziphioid whales. It was referred toa new genus and species with the name of Proroziphius macrops. The other fossils are of the giant sloth, the Megatherium, pre- sented by Mr. George T. Lewis, of this city. These were also found in the Ashley deposits, and are probably the remains of animals which became mired in marshes after the elevation of the Ashley deposits above the ocean level. Two New Minerals.—Prof. J. LAWRENCE SMITH exhibited speci- mens of two new minerals. The first is a mammillary coating on the columbic acid minerals from North Carolina. It is white and soft, being a hydrate columbate of yttria with about 15 per cent. ofwater. Suflicient of the mineral has not been obtained, in a state of purity for a thorough analysis, but there is every prospect that there will be. It is readily found on many of the specimens of Samarskite and Euxenite (which last mineral Prof. Smith has dis- covered to be a constant associate of Samarskite). No name has yet been given to the mineral, as Prof. Smith prefers to complete the analysis before giving it a name. He also gave some little historical account of the columbic acid minerals. Another species for which the name Daubrélite is proposed is an interesting mineral recently discovered by Prof. Smith on the nodule of Troilite existing on the Cohahuida meteoric irons that he has been examining. It is a sulphuret of chromium, is a black shining mineral, with a perfect cleavage in one direction, giving a black powder soluble in nitric acid which solution is of an intense chrome green—and is found to contain sulphuric acid, oxide of chromium, and a little oxide of iron, which last Prof. Smith sup- poses to come from some T'roilite not perfectly separated from the Daubrélite—as this mineral is found on almost all the nodules of Troilite in that iron. May 30. The President, Dr. RuscHeNnBERGER, in the Chair. Thirty-eight members present. Chapters XII., XIII., XIV., and XV. of the Amended By- Laws were adopted. Article 1, Chap. VIII., was amended by adding after the words “thirteen professors:” ‘“ Who shall be appointed and superseded or dismissed only by the affirmative vote of two-thirds of the whole Council.” 88 PROCEEDINGS OF THE ACADEMY OF [ 1876. The meeting having adjourned to June 6th, the following were then elected members :— Wm. Wharton, Jr., C. H. Cramp, Chas. H. Rogers, A. R. Justice, Edw. P. Borden, Edw. Taylor, J. T. Audenreid, J. S. Helfenstein, Mrs. Gertrude A. Quimby, Henry M. Laing, Mace ell Sommerville, and Chas. A. Slocum, M.D. Prof. Wentzel Gruber, of St. Petersburg, was elected a corre- spondent. On some supposed Lemurine forms of the Eocene Period.— Prof. Cope communicated verbally the following observations :— I have seen no reason to modify the view originally expressed as to the Quadrumanous affinities of Anaptomorphus, but new light has been thrown on the structure of Tomitherium and its allies. The fragments of skeletons of two species of this genus ( 7’. jarrovit and J. tutum) include numerous bones of the tarsus, and these are identical with corresponding parts in the Creodonta and different from those of the Lemuridz. The astragalus extends anterior to the shortened caleaneum, and the navicular is short and the cuboid not elongate. The astragalus presents two oblique flat sur- faces, one for the internal malleolus, the other for the transverse facet of the tibia. The portions of femur, including the third tro- chanter, the proximal part of the ulna, and the distal portion of the humerus, are all closely similar to those of the Creodonta. The type of Tomitherium includes some parts of the skeleton not pre- sent in the New Mexican species. Thus the ilium of 7’ rostratum, while furnished with the prominent anterior inferior spine of the Creodonta, is flattened towards the crest, and is not angulate on the external face. The femur is furnished with a very elevated third trochanter as in Chiromys and Talpa, and not low down as in Creodonta. The head of the radius is rounder than in Creo- donta. The skeleton of Tomithertum in fact bears strong resem- blance to that of Chiromys, leaving the skull out of view. The skeleton of the New Mexican form includes an entocunei- form like that of Stypolophus hians, which indicates a non-oppos- able hallux. It is apparent that the supposed lemurine Mammalia of the type of Tomitherium, which have the formula of the molar teeth 4-3, cannot be separated by ordinal distinction from the Creodonta. They differ from them, it is true, in their wholly tubercular molar teeth; but relate to them in this as the bears and Procyomide do to other Carnivora. I propose therefore to constitute these a distinct group or suborder, intermediate in position between the Creodonta and the Prosimiz, under the name of the Jesodonta. I cannot find characters by which to distinguish this division from the Jnsectivora as an order. 1876. ] NATURAL SCIENCES OF PHILADELPHIA. 89 I have applied to this order the name Jnsectivora so as to avoid the creation of a new one. I[now think that the latter would have been the better course. The name Jnsectivora has acquired cur- rency as applied to the well-known modern group of that name, and its application to types of such apparent diversity as those now associated under a single head is not a convenience. I there- fore propose the name Bunotheria for the order, and include under it the suborders, Creodonta, Mesodonta, Insectivora, Tillodonta, and Taeniodonta. Further investigation will be necessary in order to determine the relations of the Prostmiz to this order. The committees to which they had been referred recommended the following papers to be published :— 90 PROCEEDINGS OF THE ACADEMY OF [1876. ZOOLOGICAL AND BIOLOGICAL METHODS OF RESEARCH. BY HARRISON ALLEN, M.D. The influence of methods of zoology upon biological science has, in some instances, led to confusion of terms. The great or primary principles of life are certainly of deeper significance than the limited and often arbitrary deductions of zoology would lead us to infer. An anatomical process as considered within the range of its own forms, and having no direct reference to the needs of the systematists, often ends without the intervention of any of the hypotheses of evolution; not that they fail to sup- port such hypotheses, but that the anatomist finds the nomen- clature adopted by the naturalist to be remote from his purpose. We propose contrasting a few examples of zoological and biological methods as suggested chiefly by the study of deform- ations. These may be freely epitomized as follows: I. The principles of reversion as contrasted with gemmation. II. The terms gene- ral and special. III. Teleology as contrasted with morphology. IV. Methods of growth as distinct from typical forms. I. All monsters are now known to be the results of operation of law. Indeed, we have never advanced from the position taken by Montaigne that “‘ from omniscience nothing but the good, the usual, and the regular proceeds; but we do not discern the dis- position and relation.” The variance from the type to which the monster belongs cannot for a moment be compared to the variation from the characters of a known specific or generic formula. Indeed, it is singularly rare to have any portion of a monstrosity recalling the normal relation of parts of any animal congeneric with it. If any one compares, for example, the head of a dolphin with its anterior nares in a position somewhat similar to that of the central cavity in the face of a Cyclops sheep, he will find that the rudimentary nasal bones and the exposed position of the vomer, as well as the extraordinary projection of the maxillary processes in the front of the central opening, all suggest that the Cyclops, ee ee ee eee 1876. ] NATURAL SCIENCES OF PHILADELPHIA. 91 so far as its osseous parts are concerned, is dolphin-like; it will be seen, nevertheless, that the validity of such a comparison is at once dissipated when the intermaxille of the dolphin are detected occupying their normal relation to the superior dental arch; while these bones have never descended from the vertex in the Cyclops. In the same way, the mammal having cleft palate, in which the vomer is seen occupying a position on the plane of the roof of the mouth, is not to be placed in the same group with the Chelo- nian skull, in which the vomer normally exhibits an exposure in the hard palate, for the reason that this cleft palate is due in the mammal to some error of union between the fronto-nasal process and the related maxillary arches; this—the real cause of the de- formation—is not in any way affected in the Chelonian. It would appear that a lapsus in the course of the development of a highly specialized animal will cause the defect to be fixed at a point so low that no intelligent study can be made between it and the normal “relation and disposition” of parts in another animal equally if not more highly specialized than the one in which the deformation is seen. It is evident that no defect in a ruminant can be said to be a reversion to a cetacean—when the latter is the more specialized of the two animals. In the same way, great care should be exercised in compar- ing mammals, exhibiting defects in the numbers of toes, with re- lated zoological types. Starting with the tentative point that the most generalized form of the mammalian limb is a five-toed segmented axis, we have the type to which all other forms can be compared. This comparison is most successfully carried out in the carpus and tarsus. Confining our remarks to the posterior limb, we find the first, second, and third toes uniting through the intervention of the cuneiform bones with the scaphoid, while the fourth and fifth toes unite directly with the cuboid bone. Any descent from this number of five is seen to occur upon the sides, so that the first and fifth toes are lost before the second and fourth ; and if the animal possesses but one functionally active toe, it is invariably the third. Reversion, by which any special- ized form of foot shows a tendency to return to a more generalized expression, is thought to be exhibited in the horse. A horse having functionally active splint bones would thus suggest a 92 PROCEEDINGS OF THE ACADEMY OF [1876. reversion to Hipparion. Mr. Wood-Mason (Proc. Asiatic Soc. Bengal, Jan. 1871, p. 18) has figured (Fig. 1) and described a horse’s foot in which one of the splint bones was hoof-bearing. While accepting the premises by which can be demonstrated the line of descent of the horse from Hipparion, we think that the proof of the argument rests not upon the number of digits, but upon their “ disposition and relation.” The tarsus is the key to all parts of the foot arranged distally to it. Observers have too often neglected the ne- cessity of tracing supernumerary toes back to their corresponding tarsal elements, thus impairing the force of their conclusions, and confounding a zoo- logical inference (7. e., a reversion of a special to an embryonic form) with another larger principle (7. e., gemmation). In some of its expressions, at least, reversion and gemmation are terms of equal value; thus, if we look upon the limb as a bud, the toes partake of the same value as the main shaft of the limb, and may be called distal buds—diverging as rays from the tibia and fibula; the mere substitution of the term bud for toe is here of the first importance, for we can thereby account for any num- ber of toes as well as any interference in the order of the bones of the normal foot. Whereas, if we use the term toe instead of bud, we are limited strictly to the foot as determined by its own tarsus, and anything in excess of that number is atypical, and has no zoological equivalent. It is evident that the mere duplication of a “toe” is no proof of its reversion to anything, whether it occur in the horse or in man. Let us suppose, for example, that a child is born with six toes, it does not follow that the sixth toe is an example of reversion, but is a mere expression of an exces- sive tendency to budding. In like manner, the so-called second hoof of the horse may have no connection with either the fourth or the second toes, but may be a mere bud or graft from the third. (Fig. 2.) Prof. Leidy (Proc. Acad. of Nat. Science, 1871, 112) has called attention to the foot of a horse in which the splint bone, becoming functionally active, would appear to be an instance of reversion toward Hipparion. A careful examination of this specimen has 1876.] NATURAL SCIENCES OF PHILADELPHIA. 93 convinced the writer that four toes are here present instead of three, and that the first and second are united in a common shaft, bearing a hoof, occupying a position of the functionally active Fig. 2. Fig. 3. Im Lte—w splint bone, as in the case recorded by Mason. This specimen cannot be considered, therefore, as a reversion to a three-toed, nor even to a congeneric four-toed ancestor, since the first toe is present. (Fig. 3.) Fig. 4. Fig. 5. ry oe Otto (Monstr. Anat. Des.) has figured numbers of examples of six-toed and six-fingered monsters. In some of these the addi- tional digit is a distinct bud from the shaft of a marginal meta- 94 PROCEEDINGS OF THE ACADEMY OF [ 1876. carpal or metatarsal bone (Ibid., Tab. xxv., Fig. 9). (Fig. 4.) In others the new appendage extends upward to the tarsus (Ibid., Tab. xxv., Fig. 11). (Fig. 5.) We would place the first-mentioned of these in the group of rayed processes of Goodsir; and in the second group we would place those alone whose divergent rays enter directly into the construction of carpus and tarsus respec- tively. In this restricted sense, reversion is of subordinate value as compared to the principle of budding. M.S. Arloing (Ann. des Sciences Naturelles, viii., 1867, 55, pl. II.) figures and describes the anterior extremity of a horse, in which the bovine-like hoof is dependent upon an atypical budding from the end of the third toe (see Fig. 2). In like manner the union of parts usually distinct, as, for example, the produced digits of a hog—forming a solid terminal bone incased in a single hoof—should not even remotely suggest any variation in the type. Such unions are not known to yield corresponding change in the carpus. For figures, see Otto, loc. cit., and Struthers, Edin. Phil. Journal, N. S., 1863, 272. IJ. Pursuant to the method as above suggested, the terms general and special, as applied to the limitation of types, can be made to assume a deeper significance. It is accepted that, in the mammalian limb of a five-toed form having the digits of about equal lengths, we have what is accepted to be a generalized “ dis- position” of parts; but, at the same time, the muscles in a series of limbs so characterized will have varying degrees of special- ization. Thus the separation of the deep from the superficial flexor, in the hand of man, creates a high degree of specialization compared with the paw of the opossum, in which the division of the common flexor is barely manifested. So with the inferior extremity of man we find all the essential elements of the osseous structure of a remarkably low degree of generalization, so far as the parts below the neck of the femur are concerned. But the bone at that point and the hip-bones present an extraordinary degree of special development. Here, then, is a limb found in a highly specialized zoological form, which is spe- cialized only towards its proximal end. In the arrangement of its muscles, particularly in the posterior femoral group, we get a marked degree of specialization. The muscles which in most animals belong to the extrinsic group, such as the biceps flexor, semi-membranosus, and semi-tendinosus, are 1876.] NATURAL SCIENCES OF PHILADELPHIA. 95 removed entirely from the trunk, and pass between segments of the limb. This arrangement, joined to the excessive development of the gluteus maximus, enables man to assume the erect posi- tion. The consequences of this assumption are so varied and im- portant as to give the clue to some of his best physical character- istics. It is thus seen that the arrangement of these muscles is of great value, although it need not be taken into consideration if we view the limb, as is commonly done, from the standpoint of the osseous parts only. Ill. Now this posterior femoral group of muscles yields an upward prolongation of fascia, which is intimately identified with the biceps flexor. This prolongation extends as far as the sacrum, and has received the name of the great sacro-sciatic ligament. Very rarely the biceps flexor continues muscular along this tract, thus affording an illustration of reversion. But singularly enough, this reversion is not to the higher quadrumana, where the sacro- sciatic ligament is even less pronounced than in man. Probably we will find the type to which this upward prolongation of the biceps can be located somewhere in the link uniting the lemurs with the rodents. Teleology has been contemptuously regarded. Kitchen Parker has called it “a pretty gilded ball,” that lies by the side of the path of severe study, and if it attract attention at all, does it at the expense of true progress. But it will not do to ignore teleology. Here is a group of highly specialized muscles based upon a trifling difference in the arrangement of muscular fibres, which is nevertheless indirectly the cause of retardation or deviation of parts in themselves of great morphic significance. IV. The several types which have received the names verte- brata, articulata, mollusca, and radiata are no longer considered as expressions of distinct ideas, so much as different expressions of the same idea. The forces of nutrition in all the types are cbedient to the same laws. It is evident that it is more interest- ing to study these laws than the resultant forms. ‘There are no dissonant laws existing in the several types, but a few harmonious laws existing in all. The law of bilaterality, for example, is seen in all the types. The law of the spiral, the law of gemmation, the laws of conju- gation and fissuration are all actively expressed in the tissues. To these accepted data we may be allowed to add another, viz., the law of radiate nutrition. This is one of the most prongunced 96 PROCEEDINGS OF THE ACADEMY OF [1876. phases of growth force. Numerous examples of radiate skeletons are seen in the Protozoa, where nothing else in the way of formed tissue need be seen. It is, therefore, together with the force of the spiral, among the jirst expressions of growth force. It gives the entire group of the Radiata its most conspicuous superficial cha- racter. In the lower Annulosa it operates in more restricted fields, but often so powerfully as to be alone subordinate to the law of bi- laterality. In the Mollusks it appears to occupy a position below both bilaterality and the force of the spiral, although in the com- pound Ascidians we see examples of it, as well as in the minute anatomy of the tests of many bivalves. We called attention to the existence of a radiated type of nu- trition in vertebrates in 1872 (Proc. Acad. Nat. Sci., 1872, 42), and particularly invited attention to the arrangement of the bones of the pelvic and shoulder girdles. Prof. Theodore Gill' has also suggested the identification of homologous parts, from a central or determinate part outwards. Within certain limitations (viz., the acceptance of the limb as a peripheral quantity, potentialized from distal to proximal ends) this view is in harmony with our own. The law of radiate nutrition which so powerfully impresses the tissues at both the shoulder and pelvis, maintains its authority in the event of deformation. Thus, in a double monster, the right scapula of one individual, the left scapula of the opposite indi- vidual (Fig. 6), and a humerus, Fig. 6. bearing ulna, radius, and carpus, will be arranged as rays from a central point. It is evidently im- possible to identify this humerus and its associated segments with either of the individuals. In another example the parts of the limb were arranged bilaterally. One division represented the distal portion of the right limb of an in- dividual, the other portion of its opposite—the limb gradually end- ing in the femur as a single struc- ture. Tracing this single femur toward the trunk, we found, as ' Smithsonian Miss. Coll., 247, p. xiv. 1876. ] NATURAL SCIENCES OF PHILADELPHIA. 97 in the preceding instance, it bore the relation of a ray to the ossicles representing the pelvic bones. In addition to radiate nutrition, as shown in small and subor- dinated areas in an animal in which another type of nutrition is dominant, we may have, as in vertebrates, the principle of bi- laterality announcing itself in small territories of tissue apparently uninfluenced by the larger expression of force operating in the same direction elsewhere. Indeed, we may say that bilaterality is not merely a principle of right and left adaptation; but may be found operating anywhere, and, perhaps, in more than one place atatime. Thus, the development of the sternum is inde- pendent of the development of the vertebral column. It arises between the ends of opposed cost, and when this occurs in a single symmetrical individual, it would appear to be influenced by some deep-lying typal condition. But in double monsters the sterna, when present, do not belong to either individual, but arise between the right ribs of one individual and the left ribs of its opposite. Such a sternum thus takes its place on either side of the dual organism. It is very evident that these sterna cannot be identified with either individual, but are rods, symmetrically seg- mented, orignating de novo in an intra-costal space, and entirely irrespective of the bodies from which these costz spring. 98 PROCEEDINGS OF THE ACADEMY OF [1876. FURTHER NOTES ON ‘‘ INCLUSIONS” IN GEMS, ETC. BY ISAAC LEA, LL.D. In a communication on microscopic crystals contained in gens, which the Academy did me the favor to publish in its Proceedings’ a few years since, I gave some figures of these crystals which I have frequently since verified. I then observed that, beside these inter-crystalline forms, there were in most gens, cavities frequently so numerous that they amounted to tens of thousands. Since the period of the publication of my paper, I have made very large additions to my cabinet of gems, and particularly those of the Corundum group, Sapphires, Rubies, and the so-called Oriental Topaz, Oriental Amethyst, Asteria, etc. In the numerous fine blue Sapphires of my collection, I have rarely explored one without finding numerous cavities, and ordinarily also finding the beautiful microscopic acicular crystals, which, when the specimen is cut cabochon, cause the three bands, and these by crossing form the star in Asteria. The cuneate microscopic crystals are also quite common. Cavities, with or without the fluids, are so frequent in erysials, from the soft Calcite to the hard Corundum, that little may be said as to their occurrence, as they are so common. Cavities in quartz crystals inclosing fluids have been observed by the older mineralogists, but the kind of fluid, and gas or air, was not ascertained by them. Sir Humphry Davy, in 1822,’ investigated the contents of these cavities, and found them gene- rally pure water. The gas bubbles were sometimes found to be “azote.” Sir David Brewster, in 1823,’ published a memoir of great research and value. He first had his attention called to the examination of fluid in cavities by the explosion of a crystal of Topaz when heating it. He found cavities and air bubbles in nearly twenty different substances, and these inclusions were care- fully examined by him. In some of these cavities he observed two fluids and crystals, and these are figured in his plates. Subse- 1 Feb. and May, 1869. 2 Phil. Trans., 1822. 3 Trans. Roy. Soc. Ed., 1823. 4 These two fluids, Prof. Dana without any analysis has called Brewster- linite and Cryptolintte. et a NP: 7 MICROSCOPIC CRYSTALS & CAVITIES IN GEMS. 1876.] NATURAL SCIENCES OF PHILADELPHIA. 99 quently, Mr. Sorby published a long and admirable paper’ on Fluid cavities and crystals in minerals, with numerous and interesting figures. He considered that the cubic crystals were probably Chloride of Sodium. In his investigation he proved, by forming artificial crystals, that, in a natural state, the fluid cavities, with their “inclusions,” must have been formed by aqueo-igneous forces. He gives a figure of fluid in mica, but I have never seen any in that mineral, although many hundreds have passed under my microscope in looking after crystals of Magnetite, etc. Mr. Sorby also published a paper on cavities in quartz in the Phil. Mag., vol. xv. p. 153; also with Mr. Butler in Proc. Roy. Soc. London, vol, xvii. p. 299. Kirkel on Microscopic Minerals, Neues Jahrbuch, 1870, p. 80, mentions bubbles and cubic crystals in quartz. He found iron glance and fluid in Hleolite = Nephelite. In Emery, from Naxos, he found fluid in cavities. In 1872, Proc. Roy. Soc. Edin., p. 126, Mr. Sang published an account of water in cavities of Calcite. Very recently, Prof. Hartley, King’s College, London, has pub- lished a very able paper on the subject of the fluid in quartz, ete.’ He says that Simmler in 1858, offering an interpretation of Brew- ster’s observations, concluded that the expansible liquid was carbon dioxide. Professor Hartley states that in many cases the liquid in quartz is water, but that in some cases he found the two fluids, and his very satisfactory and careful experiments show conclusively that the most volatile of the two fluids is carbonic dioxide. He found in every experiment, that the fluid disappeared when exposed to 31° C., and reappeared on cooling. Prof. Hartley accords with Mr. Sorby in his reasoning that ‘tat the time of its assuming the solid state, the solution endured a high temperature.” Calcite has been found to contain nearly a quart of this fluid,’ but it is not as common to be found in small cavities as it is in quartz. Fluorite.—Cavities in this mineral are rarely found, but they are sometimes seen with fluid and air bubbles. Apatite.—I have never observed cavities in this mineral, but I have not given it much attention in microscopic examinations. 1 Journ. Geol. Soc., vol. xiv., 1858, Micro-structure of crystals. 2 Journ. of the Chem. Soec., London, Feb. 1876. 3 Specimen in the collection of the late Dr. Chilton of New York. 100 PROCEEDINGS OF THE ACADEMY OF [1876. Feldspar Group.—In a former paper,’ I gave the result of the examination of many specimens of various species. Since then I have examined numerous specimens of Labradorite, and found no cavities, but the black crystals were very numerous. In the JMoon- stone of this country, I have not observed cavities or crystals, but in two specimens, out of about one hundred from Ceylon, I have seen a series of very regular quadrate cavities or crystals which do not appear to have any fluid. Fig. 10, Pl. 2. Tourmaline.—This interesting mineral is found beautifully crystallized and of almost all colors, white, brown, green, red, black, etc. The finest are found at Mount Mica, near Paris, Maine.2 Some of these specimens have small internal elongate crystals, which are terminated. A red specimen (Rubellite) in my collection has many irregular cavities. One green one from Ceylon has cavities with fluid, and another has very minute black acicular crystals in one direction. In brown crystals from Lower Dianburg, Carinthia, there are rough objects in the interior, evi- dently another mineral inclosed, which do not require the micro- scope to detect them. Cyanite-—Of the white and the blue varieties I have not observed any well-defined cavities or crystals, but in the gray- bladed Cyanite, found at Cope’s Mills, near West Chester, Penn- sylvania, there are always, I believe, small black masses which do not take a regular form, but are usually elongate. These may easily be detected by splitting a crystal along its eminent cleavage, and examining the cleavage face with a lens of small power, but a higher power is preferable. Quartz takes upon itself many colors. In it are found cavities in very great numbers, particularly in the clear fine crystals. Those which exist in such an abundance in Herkimer County, New York, and which are so limpid, and finely and doubly ter- minated, are sometimes furnished with thousands of cavities, even in small specimens, and these are of many various forms, frequently containing fluid. In some cases the fluid may be seen to move by the unaided eye. In these Herkimer crystals, carbon in the form of Anthracite is of very common occurrence, 1 Proc. Acad, Nat. Sci., May 11, 1869. 2 Dr. Hamlin has published a beautiful little work on the Tourmaline, with illustrations. 1876.] NATURAL SCIENCES OF PHILADELPHIA. 101 and in one of my specimens a small portion moves in the fluid of a cavity. These cavities often exist in an entire sheet, almost across the prism of a crystal.' In smoky quartz, these cavities are much rarer, as also in Amethyst and wine-color and green quartz. The Amethyst is frequently penetrated with crystals of Rutile, and these are often very large, sometimes 1 to 4 inches long. The Chester County specimens usually have numerous curved filamentous crystals, easily detected with a common lens. In Way’s Feldspar Quarry, near Dixon’s, Delaware, there is a very peculiar form of quartz which is nearly transparent, but somewhat clouded. The fragments of all sizes, from that of a pin’s head to that of a small walnut, are inclosed in a mass of Dewey- lite. These fractured pieces are of indefinite forms. They are evidently cryptocrystalline, and look as if they may have been heated and suddenly cooled, and thus fractured. When these pieces are subjected to a high power, there may be detected in them very minute oval cavities in great numbers, and the major axes usually placed in one direction. I have never seen cavities in milky quartz or blue quartz. Sir David Brewster found many cavities in rock crystal from Quebec with ‘‘ water and mineral oil.’” Topaz.—In the various beautiful crystals which this mineral presents, there are frequently found cavities with fluid, and some- times in this fluid may be seen the cuboid crystals described by Sir David Brewster. He found a single fluid in some cavities, and in others two fluids with “air bubbles.”’ He says the fluid does not expand with heat. The Saxony transparent white crystals some- times have cavities, as well as those of pale wine-color. The Bra- zilian gold-yellow specimens have these cavities very frequently. The clear pinkish are more free from them. I have never observed any microscopic acicular crystals in Topaz. Emerald, Aquamarine,and Beryl—constitutionally the same— differ very much in regard to their possession of cavities and their commercial value. So far as I have been able to examine fine specimens of Emerald, it is rare to see one without cavities. One which I have, of very fine color, has many cavities of various forms, 1 Sorby, Journ. Geol. Soc., 1858, found many cavities, and thinks that the cubic crystals inclosed are probably chloride of sodium, as mentioned above. 2 The smoky quartz of Pike’s Peak has hexagonal spangles, which may be mica. 3 Trans. Roy. Soc. Ed., vol. x. 102 PROCEEDINGS OF THE ACADEMY OF [1876. in which are included a fluid enveloping generally two perfect cubic crystals of an unknown mineral. In all cases in this speci- men, the second crystal is much the smaller. Fig. 11, Pl. 2. In Aquamarine, cavities are not frequent, and in Beryl I have detected them only in a specimen from Unionville, Penn. Fig. 12, 12a, Pl. 2. In this there is a biangular cavity with a small cubic crystal at an inner angle. Throughout the mass there are small suboval cavities. Garnet.— As a precious stone this is by no means rare, but it is lustrous and of a fine color. Cavities and microscopic crystals are very common in this gem.’ The cavities are usually irregular and rough, and never to my knowledge have fluid. On a polished surface of a piece of garnet from North Carolina, nearly an inch long, the reflection of these crystals covered the whole surface with prismatic colors. Cinnamon Stone.—This beautiful variety of garnet, from Ceylon, as far as I have been able to observe it, and I have some twenty cut specimens, and numerous rolled pieces, has irregular cavities and some crystals, as I have stated in a former paper. Zircon.—With its high refractory power, this is used frequently as a gem, and sometimes sold as a diamond when white and per- fectly transparent. One of the numerous specimens which I have examined has cavities? and microscopic crystals, and a specimen: from Ceylon has remarkable dark brown, elongate, fusiform spots, with numerous dotted ones intervening. Fig. 9, Pl. 2. Chrysoberyl.—The few specimens I have of this beautiful gem have neither cavities nor microscopic crystals, but Brewster observed “strata of cavities and both the fluids.” Chrysolite = Olivine.—In some of my specimens I have observed small cavities with fluid. Brewster met with them containing ‘fluid and bubbles of air.” Spinel.—This gem occurs of several colors. The Spinel-ruby, so called, sometimes is very close in color to the true Ruby, but it has not by any means the depth nor brilliancy of the true Ruby. In a pale-green specimen of great beauty which I have received recently from Ceylon, I have not been able to detect cavities or 1 Proc. Acad. Nat. Sci., Feb. and May, 1869. 2 In a specimen in Dr. Leidy’s fine cabinet, there are anastomosing cavi- ties. 1876. ] NATURAL SCIENCES OF PHILADELPHIA. 103 crystals. In my former papers I have expressed uncertainty in this matter.’ Tolite.—This gem is inferior in hardness, color, and specific gravity to Sapphire, but is valued for its peculiar change of color, being dichroic. One of my specimens is without any inclusions. The other is filled with blue four-sided prismatic crystals, which are long, and inclosed in a nearly white subtransparent mass. These crystals are sometimes broken and their parts prolonged in the mass, and they are all lying in nearly the same direction. Turquoise, with its peculiar and agreeable blue, is never trans- parent, and neither cavities nor microscopic crystals are found in it. Opal.—This exquisite gem, which displays such brilliant colors, is very highly valued. It is but little harder than glass, and is indeed considered as voleanic glass. Its remarkable flashes of color are attributed to fissures, in accordance with the theory of Newton’s colored rings. I have never been able to detect either cavities or minute crystals in this beautiful gem—except in two cases. One of my specimens has a brown, terminated crystal, a six-sided prism of an unknown substance, about one-fifth of an inch long, and terminated by a single oblique plane; the other has several smaller ones. Lapis-lazuli. This was used by the ancients as a favorite gem, but it is not now valued as such. I have not been able to detect cavities or minute crystals in any specimen in my possession. Corundum.—This very interesting mineral, when in perfect transparent crystals, is highly valued as a gem, under the name of Sapphire, Ruby, ete., according to color. When yellow, it is called Oriental Topaz; when purple, Oriental Amethyst. When purely white it is sometimes sold as a Diamond. In this country we have two localities only of Corundum where any large quantity has been found, that of Chester County, Pennsylvania, and Franklin County, North Carolina. From the mines in Chester County, several hundred tons have been taken, but no transparent crystals. Some opaque ones are bluish and some pinkish. The North Carolina locality has produced some very large crystals, and numerous small ones. Of the latter there have been found many quite pure and transparent, and these are sometimes blue and sometimes red. But none of them yet found are of value as 1 Proc. Acad. Nat. Sci., Feb. and May, 1869. 104 PROCEEDINGS OF THE ACADEMY OF [1876. gems. The fine Sapphires and Rubies are chiefly from Ceylon, and they form some of the most beautiful objects in nature. I have many of these in the form of worn pebbles, and some in fine hexagonal form, as well as hundreds of cut specimens. I have examined carefully more than one thousand specimens, with a view to discover whatever “ inclusions” they might possess. In a communication to the Academy, I described and figured some microscopic crystals in these and other gems. Since then I have added a very large number to my collection, and among these several hundred large and small transparent crystals. In a care- ful microscopic examination of these, I found a large number which contain cavities and minute crystals, the former sometimes scattered irregularly through the mass, and sometimes forming a sheet or film. These cavities are of all forms, but usually sub- elliptical; sometimes tubular, and these tubes frequently anasto- mose in a very beautiful manner. These cavities are so numerous that they frequently give a cloudiness to the specimen, which is less valuable as a gem, but most interesting in a scientific point of view. In some specimens these cavities exist by tens of thou- sands, and Sir David Brewster stated that in a specimen under his observation there were about 37,000 of these cavities. I am sure that in one of my large cut specimens there must be more than double that number. It is a very common thing to see hundreds at a time of these cavities in the Ceylon specimens, partly filled with the fluids previously alluded to in these notes. But it is quite rare that they are found in the specimens from North Carolina. Still I have seen them in the transparent small frag- ments of deep blue crystals, and sometimes in the transparent light-colored ones. In one specimen of the latter, I discovered some most interesting cavities, which contained, beside the fluid, each a single cubic crystal, Figs. 1, 2, and 3, Pl. 2. I had never observed an included crystal in any cavity in the numerous Ceylon specimens which I have examined. These cubic crystals have the exact form and appearance of those in the Hmerald described herein. In regard to the microscopic crystals in Sapphire, having described and figured them in the papers before alluded to, I have little toadd now. Further observation has confirmed what I then ! Proc. Acad. Nat. Sci., 1869. 1876.] NATURAL SCIENCES OF PHILADELPHIA. 105 stated regarding the radii of Asteria. Very recently I have received a number of these Asteria of various colors, blue, purple, white, red, and dove-color; several three-quarters of an inch in diameter. The red and purple specimens are of peculiar beauty, and when examined in the syn, or any strong light, they both exhibit the microscopic acicular crystals with peculiar beauty, displayed as they are in hexagonal form, and reflecting the spectral colors. The Ruby Asteria is certainly among the most beautiful objects in nature, and the purple are very little less so. In some crystals of Corundum, there is a strong bronze reflec- tion, and this is the case with some of the large hexagonal crystals which were imported by Mr. 8. 8S. White from India for commer- cial purposes, and which he distributed with so much liberality to our mineralogists. These bronze crystals have also been found at the Black Horse and Village Green localities in Delaware County, Pennsylvania. When examined with a good power, these bronze reflections are at once seen to be caused by minute acicular crys- tals, and these may sometimes be seen in bunches. A pale Ruby, “ Rubicelle,” which I lately received from my friend Hugh Nevill, Esq., Ceylon, about three carats, is a most interesting and beautiful gem. It has the depth and brilliancy almost of the diamond. It is nearly of a rose-color, and is per- fectly transparent. It is cut with a top table and not entirely symmetrical. Its refractive power is unusually great. Yet when this brilliant transparent gem is examined with a high power and strong light, the whole mass may be seen to be filled with long acicular crystals in three directions, parallel to the prismatic planes, and interspersed are numbers of very minute and delicate cuneiform crystals. It has also a small cloud of exceedingly small cavities. Another remarkable specimen may be mentioned here, which has small cavities and minute microscopic crystals. It is of a pale yellow or straw-color, and of a depth and brilliancy scarcely exceeded by the diamond. During the examination, about two years since, of some hundreds of small crystals of Sapphire, perfectly transparent to dark blue, I discovered one which had very singular plumose impressions on the planes of the prism. This induced me to examine carefully all those which I sabsequently procured, and I have now over a ' Proc. Acad. Nat. Sci., May 11, 1869. 106 PROCEEDINGS OF THE ACADEMY OF [1876. dozen specimens which exhibit this very singular character.t I ain entirely at a loss to discover the cause of this form of minute impressions on so hard a substance. It evidently has been formed by some collateral mineral substance, against which the molecules in crystallization have been arranged. Diamond.—The hardest of all substances stands first among gems. It has not, however, much interest to the microscopist, as no cavities with fluid have been, so far as known, observed, nor’ has it included crystals of foreign substances. They are often very imperfect, containing rifts and discolorations. Some of my speci- mens have beautiful triangular impressions on the surface of the planes. My friend, Dr. Hamlin, of Bangor, Maine, is engaged on an extended work on the diamond. Such a work is much needed, and I know no one as capable as he to accomplish it. This gem sometimes occurs of various colors. In my cabinet I have six different colors. REFERENCES TO PLATE 2. Fig. 1, 2, 3, Plate 2. Represent cavities and crystals in a specimen of transparent Corundum from Franklin, North Carolina. In no other speci- men of the numerous ones I have examined have I found cavities with a fluid and included crystals both, while it is very common in the Ceylon Sapphires to have cavities without an included crystal. Fig. 4. A Sapphire from Ceylon, given to me by Dr. Ruschenberger, has cavities without fluid; the cavities being in the form of crystals in the larger ones, but in the numerous small ones subrotund. These cavities are interspersed throughout the mass with numerous acicular crystals running generally in two directions. Fig. 5. A specimen of blue Sapphire (Ceylon), with er nearly perfect subhexagonal crystals, somewhat flattened. These are surrounded by an immense number of minute cavities, some of which anastomose. The crystals seem to be filled with a black fluid. There are also very minute acicular crystals. Fig. 6. In the same specimen with the above, there is a group of very different crystals which are here represented. These can only be seen with a proper angle of light. Then they reflect all the colors of the spectrum. This group consists of very perfect cuneate and acicular crystals, and is somewhat like that figured in my pl. 9, fig. 2, Proc. Acad. Nat. Sci., May, 1869, but the crystals are much more defined and eee than in that plate. 1 Wigs: 7 and 8, Pl. 2. 1876. ] NATURAL SCIENCES OF PHILADELPHIA. 107 Fig. 7. Represents a small blue Sapphire one-fourth of aninch long. The very remarkable plumose impressions cover all the six prismatic planes. Fig. 8. A blue Sapphire similar to Fig. 7, about three-sixteenths of an inch. The prismatic planes here are covered with impressions more in a dotted form. These two (Fig. 7 and 8) were examined with a power of one hundred diameters. Fig. 9. A specimen of Zircon from Ceylon has very singular, dark brown, elongated fusiform maculations, in one direction. These are surrounded with numerous dotted ones. Fig. 10. Among all the numerous specimens of Moonstone which I have examined I have found two only with ‘‘inclusions.’’ These have numerous parallelograms which look like cavities, but may be true crystals of some foreign substance. There is no appearance of fluid in them. Fig. 11, a, 6, c, Emerald. A very fine specimen in my collection is filled with exceedingly interesting cavities with included cubic crystals, enveloped by fluid. The forms of the cavities are exceedingly varied, and the cubic crystals—generally too, a small and larger one—are remarkably perfect. These characters make this specimen one of very great interest. Fig. 12 and 12a, Beryl from Unionville, Pennsylvania. Fig. 12 repre- sents a remarkable biangular cavity with a cuboid crystal at one of the interior angles—has no fluid. Fig. 12a represents in the same specimen two cavities with fluid and air bubble. Both figures represent the numerous irregular cavities and imperfections which exist throughout the mass. INote.—I have made these drawings with great regard to correctness, and the artist has well represented them. 108 PROCEEDINGS OF THE ACADEMY OF [1876. JUNE 6. The President, Dr. RUSCHENBERGER, in the chair. Forty-five members present. Fertilization of Flowers by Insect Agency.—Mr. THoMAs MEE- HAN remarked that the subject of cross fertilization and fertilizing by insect agency, was still one of absorbing interest. There was no question about the facts; differences of opinion arose as to the meaning of the facts, and the extent to which they prevailed. , Contrary to the belief of many distinguished botanists, he could not see that those plants which were arranged for cross fer- tilization had any advantage in the “ struggle for life’ which prevailed in races, over those which were closely fertilized by their own pollen; and again, he found that many plants which were adduced by his friends to prove arrangements for cross ferti- lization, in fact fertilized themselves. He said he would to-night refer only to three remarkable cases, the Scrophularia, dandelion and ox-eye daisy, and the red clover, and he selected these, because the distinguished author of ‘* How Plants Behave,” Professor Asa Gray, had made much use of the two first named in his book in describing arrangements for cross fertilization; and, as Professor Gray was present this evening, he felt sure that with his usual friendliness and good feeling towards all who were earnestly seeking the truth, he would do the meet- ing the favor to correct him if he found the speaker’s observations not confirmed by his own. Red clover he would refer to, because it was oftener quoted. Red clover was, in fact, the Vade mecum of the insect fertilizationist. Mr. Meehan then exhibited specimens of Scrophularia canina, and explained its floral development. The pistil protruded while yet the anthers were rolled back in the throat of the corolla. One by one these stamens were straightened out, the anther coming into close proximity with the stigma, when it burst, and by the contraction of the sacs, the pollen was ejected, falling on the stigma. The pollen was of a brilliant orange color, and ‘the stig- ma of a pearly white, so that the smallest particle could be seen even by a good naked eye; and could be easily noted if carried to the stigma of other flowers by insects. Small sand wasps and other winged insects visited the flowers in extraordinary abun- dance ; but it could be seen by observers that no pollen appeared on any stigma until the bursting of its own pollen sacs. Profes- sor Gray, he said, in ** How Plants Behave,” had described “ Scro- phularia” as acting in a very different w ay to this, making no ex- ceptions to any species, though it was fair to note that the illustrs 1876.] NATURAL SCIENCES OF PHILADELPHIA. 109 tion accompanying the text was of Scrophularia nodosa, a species not yet in flower with him. Composite plants, he said, had been referred to as illustrating the peculiar arrangements for insect fertilization. The colored ray petals had been characterized by his friend as so many flags alluring winged insects to where the sweet secretions were, in order that they might bring foreign pollen at the same time. In his vicinity, surrounded as he was by an abundance of sweet flowers, he had never seen a winged insect on dandelion or ox- eye daisy (Chrysanthemum leucanthemum), though, on the waste grounds near him, they were in bloom by,the thousand; but every little flower perfected a seed. There were millions on millions of ° seeds, and even admitting that there might be some winged insects at them that he did not see, they were certainly so scarce that it was out of the question to suppose that each of these had been fertilized by winged insects. He had found thrips in some flowers and on one occasion an ant, but these were too few for the immense work to be done. But this presumptive argument was unneces- sary, as a careful observation of how the plants behaved, showed they were self-fertilizers. In the dandelion, he said the united column of stamens perfected, and spread its pollen in advance of the pistil. As the pistil grew it carried the pollen with it. The apex of the pistil then forked, and as the interior surface of the cleft alone had the stigmatic surface, it had been argued that none of the pollen could be used for itself. Buta watcher would see that as the cleft opened the pollen on the line of the cleft fellin. It was but a little, but that was enough. Then the position of the upper part of the pistil in the dandelion favored this intrusion of the pollen. Just before the expansion of the stigmatic lobes, the pistil curved at the apex, and the slit opened first on the upper side of this then horizontal position. The pollen easily fell. into the chasm. The lobes finally separated, until they became direct- ly opposite to each other as generally seen in the dandelion. While this is going on, the lobes, having pollen abundantly on the under side, as they are sweeping the horizon, drop pollen, or even rub their surfaces on the expanded stigmas of the flowers below, and in this way, if they had no pollen of their own, the lower flower would be fertilized by that above. This would be cross-fertilization, but not by insectagency. But whatif it were? Physiologically speaking, what benefit can it be to a composite flower to be fertilized by another from its own head, even granting the utmost asked by those who consider composites arranged for cross-fertilization ? The composite flower is not a compound flower, it is true. It is but an imperfect umbel. But each umbel for all physiological purposes might as well be a single flower. Side by side the flowers are set, as any one familiar with the dotted thimble-like receptacle of dandelion very well knew. They all had just the same food, the same light, the same conditions of 110 PROCEEDINGS OF THE ACADEMY OF [ 1876. life in every material effect. If the familiar illustration by refer- ence to the human family has any weight in plants, surely these flowers must be brother and sister, in any sense claimed by insect fertilizationists; and the physiological benefits to the race would be no more than if the whole head was a single flower, as a Ranun- culus, instead of the compound flower we see. He then explained the manner of fertilization in the ox-eye daisy. The united column of stamens was forced from its holdings by the growing pistil, which finally attempted the cleavage of the apex, while still holding the cap-like covering of anthers over it. The pollen fell into the stigmatic cavity more easily than in the dandelion. In- sects might visit it subsequently ; it would make no difference, having already received its own pollen. In regard to clover, Mr. Meehan said that in his remarks at Detroit last year, he had stated that he had watched a field of clover, found remarkably few insects at work, and yet the crop of seed was abundant, and that a careful examination of the clover blossom in all its stages convinced him that from its structure and behavior it was a self-fertilizer. He had been met with the assertion that the first crop of clover never produces any seeds. This was so generally believed that it must be true to a great extent. He could not have been mistaken last year, but he visited a field of two acres again a few daysago, and now exhibited heads nearly mature, all the flowers with seeds, and these (June 6th) about the first flowers that could have formed. On this visit he watched the field for an hour, and in that time saw only eight humblebees at work, rather small grist, he thought, for so large a mill, if all those flowers had to be insect fertilized. He watched their motions closely, and found, to his astonishment, that in spite of the elaborate arrangements for the work of the humblebees in the mouth of the corolla, they did not enter that way at all! They made a slit in the base of the tube, extracting the honey in this surreptitious way. With this final fact, if found general, there must be an end of the clover case. There was no bottom for the “ arrangements” to stand on. He had intended, he said, to rest the case here, but he had mentioned to his friend, Professor Gray, that he had noted the common bladder-nut, Staphylea trifolia,as being a self-fertilizer. It was one of those observations so recently made by him that he should not have introduced it to this body without further investi- gation; but Dr. Gray had suggested to him to refer to it, as he thought he could show it could not be fertilized except by insects, so he detailed what he had seen simply in order to have the bene- fit of Dr. Gray’s experience. Dr. ASA Gray said that Mr. Meehan and himself, looking at the same subjects with somewhat opposing prepossessions, were apt to see different facts; that is, either was likely to notice some particular which was not noticed by the other. For instance, Mr. 1876. ] NATURAL SCIENCES OF PHILADELPHIA. lll Meehan had some little time ago called his attention to the blad- der-nut (Staphylea) as a case of close fertilization; but Dr. Gray’s own observations, made in consequence of this suggestion, con- vinced him that this was a good case of arrangement for cross- fertilization. Like many other flowers, it was capable of self- fertilizing; for the anthers, charged with pollen, were contiguous to the edges of the dilated stigmas. But what his acute friend had omitted to notice was—that the flowers were hanging, and that, although the anthers surround the stigmas, the pollen is not ejected, but lies on the opened face of the anther in a thick coat- ing, and when it falls, it will drop to the ground instead of upon the receiving stigmatic surface; some, however, may come in con- tact with its margin. Moreover, Dr. Gray found that the stigma was earlier than the anthers by twenty-four or forty-eight hours. The stigmas, borne on styles then considerably longer than the stamens, occupied the very entrance of the corolla as soon as it began to open, and was, as he found, in condition to be pollenated a day or two before the anthers of that blossom opened. Now in each raceme there were flowers in all stages, and the blossoms, as Mr. Meehan declared, were the favorite resort of bees; these while feeding from a flower with anthers open must needs smear their faces with the pollen, and when visiting flowers a day or two younger deposit some of this pollen upon their stigma, at a time when it could not possibly get any from its own anthers. As to Scrophularia, his observations upon S. nodosa had pre- pared him to make a different reading of the facts now shown in S.canina. The arrangements for cross-fertilization in S. nodosa, as detailed and figured in the little treatise which Mr. Meehan referred to, seemed essentially similar in S. canina, except that both stamens and style were much exserted. Mr. Meehan had described the early protrusion of the style and the straightening and lengthening of the filaments a day or two later, so as then to bring the anthers into proximity with the stigma. But Dr. Gray doubted if any of that pollen ever acted upon the contiguous stigma, even if it reached it, thinking it more probable that the stigma was by this time withered and past fertilizing, as was the case in its relative, S. nodosa. 'The arrangement was a capital one for cross-fertilization, bees passing from flower to flower, brushing the same part of their body against the anthers of an older and the stigma of a younger flower; while self-fertilization was impracticable, at least, in S. nodosa, because no one flower shed its pollen until its stigma was past receiving it. As to clover, Dr. Gray could now say nothing, except that it was a member of a tribe of plants which, though seemingly ar- ranged for self-fertilization, were actually for the most part capital examples of the contrary. His attention had been called by Mr. Meehan to Dandelions, which, from general recollection, he thought were frequented by > flying insects. The first walk he took in his own neighborhood 112 PROCEEDINGS OF THE ACADEMY OF [1876. did not confirm this impression; but on the second he found small wasps and a dipterous insect busy with the dandelions, and flying from one to another, and also ants in abundance. It was clear that the narrowness of the style-branches in this and other liguliflorous composite gave them a chance for self-fertilization, but their characters were equally good for crossing through insect agency. As to ox-eye daisy, he could not confirm Mr. Meehan’s description as to the carrying up of the anthers upon the style, which must have been abnormal. Dr. Gray supposed that the arrangement would be found to be like that of the allied Feverfew, which was well figured by Lubbock, after Ogle, and this clearly betokened cross-fertilization. About Cambridge, ox-eye daisies were so infested with small insects that ladies objected to having them brought into the house among cut flowers; and flying insects, he thought, did not disdain them. As to the benefit of cross-fertilization, this was a large subject, which could not be disposed of in a few words; but Dr. Gray thought it probable that cross-breeding even of flowers in the same in- florescence was better than self-fertilization, and that wherever this occurred wider crossing was common. Mr. MARTINDALE called attention to the fact that, in the case of Staphylea, the stigma is ready for the pollen some time before it cam receive it, and suggested that, therefore, perhaps the first flowers do not produce seed. Dr. Gray rejoined that it could seldom happen that the first flower of every branch on a shrub or tree, or on different trees of the neighborhood, all opened on the same day; so that even the earliest flower had a fair chance to be fertilized. Mr. MEEHAN handed a specimen of Orobus atro-purpureus from the table, and remarked that it might aid in settling that ques- tion; as, so far as his recollection now served him, it was the first flower of the season and of the raceme, and only the first flowers that generally perfected seed. On Samarskite.—JosEPpH WILLCOX made some additional state- ments in reference to samarskite, which, until recently, has been avery rare mineral. The first discovery of it in Mitchel County, North Carolina, occurred in the spring of 1873, in a mica mine; and during that and the succeeding year about 700 pounds of the mineral were found, since which time the mine has not been operated. 1876. ] NATURAL SCIENCES OF PHILADELPHIA. 113 JUNE 13. The President, Dr. RuscHENBERGER, in the chair. Thirty-two members present. A paper entitled “On the Occurrence of Helix terrestris, Chemn., in North America,” by Wm. G. Mazyck, was presented for pub- lication. On a New Genus of Fossil Fishes.—Prof. Cope described a species of fish represented by a fragment of a jaw, which was said to have been derived from the phosphatic deposit near Charleston, S. C. The fragment indicated a species of large size, and supports alveoli or teeth to the number of ten in a space of M. .080. The crowns of the teeth are compressed, with a broadly rounded apex ; the section at the base being lenticular, with sides swollen and apices produced. The latter are the sections of a cutting edge, which constitute the apex as well as the borders of the tooth. The longitudinal transverse section is triangular. The root is not composed of dentine, but of an ossi- fied pulp, of osseous tissue, as in the Pythonomorph reptiles. This portion is nearly concealed in the alveolus, and there are no foramina along the inner side of the jaw communicating with the pulp cavities. : The succession of the teeth has been from below, as in the Saurodontide, the crown of the young tooth being developed be- low the centre of the root. Absorption followed; so that the centre of the root disappeared, leaving a cylinder with thin walls of osseous tissue running at right angles to the fibres of the inclosing jaw. The root has a lateral groove, which at this stage constitutes a fissure opening into the central cavity of the ad- joining root. The osseous tissue at the base of the crown is quite spongy. Length of bases of five teeth M. .040, or long diameter of crown at base M. .008. Transverse diameter of base of crown .00T ; elevation of crown .010. This fish belongs to a genus hitherto unnamed, presenting resemblance and perhaps affinity to Pachyrhizodus and Cono- saurus. It differs from both in the compressed trenchant crowns, and from the first named in the entire inclusion of the roots in alveoli. From Saurodontidx it differs in the absence of true dentinal roots. It was named Cyclotomodon, and the species, C. vagrans. 114 PROCEEDINGS OF THE ACADEMY OF [1876. JUNE 20. The President, Dr. RuscHENBERGER, in the chair. Twenty-two members present. The Botanical Section reported that a meeting for organization had been held, and that officers had been elected, as follows:— Director, W.S. W. Ruschenberger, M.D. Vice-Director, Thos. Meehan. Conservator, Chas. F. Parker. Recorder, Isaac Burk. Treasurer, Jose O. Schimmel. Secretary, Henry Leffmann, M.D. Remarks on Vertebrate Fossils from the Phosphate Beds of South Carolina.—Prof. Lripy observed that in a further search among the objects of the Agricultural Department of the Government Building of the International Exhibition, he had found another fossil specimen of a ziphioid cetacean. Like those previously described, it consisted of a detached beak, from the property of the Wando Mining Co., on the Ashley River, 8. C., and was oblig- ingly loaned by Mr. Amidon. The specimen, exhibited to the Academy, has nearly the form and other characters of the one last described under the name of Proroziphius macrops. The bones are thoroughly co-ossified, and the condition of the beak indicates a mature animal, smaller than the species just named. The beak is 19 inches long in advance of the nasal apertures, and is about 3? wide near the middle. The supra-vomerian canal is closed over to within less than four inches of the end of the beak by the complete coallescence of the inter- maxillaries. The prenareal fossz are funnel-like, and terminate forward in a canal penetrating the maxillaries instead of first being prolonged into an open groove as in P. macrops. ‘The anterior extremity is drilled in a remarkable degree by boring mollusks. With the other specimens previously indicated, the present one will be more fully described in a memoir on the verte- brate fossils of the Ashley phosphate beds. The species was named Proroziphius chonops. Prof. Leidy further remarked that while examining the materials from the different phosphate beds of South Carolina, and mainly those exposed to view at the International Exhibition, his atten- tion had been attracted by the large size of many of the teeth referred to Carcharodon megalodon. Among many teeth of this species, and others of C. angustidens, ete., contained in a show- 1876.] NATURAL SCIENCES OF PHILADELPHIA. 115 case of the Bradley Fertilizer Co., in the Agricultural Hall, there is a megalodon tooth, from the Stono River, which measures 6 inches 8 lines in median length from a level of the ends of the root to the point of the crown, and 4 inches 8 lines in breadth across the base. A second specimen in the same collection and from the same locality is 6 inches in median length, and 5 inches 1 line in breadth. A specimen from the Ashley River, formerly in the possession of Prof. Holmes, according to him, measures 6 inches 5 lines in length, and 5 inches 5 lines in breadth, and weighs 2 lbs. 8 drachms, apothecaries’ weight. These specimens are probably the largest shark teeth on record. If the animals to which they pertained held anything like the relation of length of body to the teeth as existing in the living white shark, they must have been upwards of a hundred feet in length. JUNE 27. The President, Dr. RUSCHENBERGER, in the chair. Fifty-one members present. Remarks on the Rhizopod Genus Nebela.—Prof. Letpy stated that in order to facilitate a ready reference to ordinary forms of rhizopods, he was disposed with some other observers to restrict the genus Difflugia to those rhizopods with lobose pseudopods, which ordinarily possess a covering or test composed of extrane- ous bodies, such as particles of quartzose sand, and diatome cases. In the genus Nebela, which he had viewed as distinct from Difflu- gia, the test is composed of discoid plates and minute rods, ap- parently siliceous and intrinsic to the structure of the animal. To the genus Nebela probably belong the species named by Ehrenberg, Difflugia collaris, D. cancellata, D. carpio, D. bino- dis, D.annulata,and D.laxra. Likewise the Difflugia peltigeracca of Carter, most of the forms described by Wallich under the name of Difflugia pyriformis, var. symmetrica, and also the Difflugia carinata of Archer. Formerly Prof. L. had indicated several spe- cies under the names of Nebela ansata, N. equi-calceus, N. sphagni, N.numata, N. barbata,and N. flabellulum. Pr. A. N.S. 1874, 156. Most of the above-named species of Ehrenberg had been re- ferred by the same author to a group with the names of Reticella and Allodictya, headed with a species named Difflugia astero- phora, which, so far as could be judged from the description and figure, did not coincide with the characters of Nebela. Of the forms referred to Difflugia symmetrica by Dr. Wallich, the first one described has recently, by Schulze, been viewed separately from the others as characteristic of a new genus with the name of 116 PROCEEDINGS OF THE ACADEMY OF [1876. Quadrula symmetrica. The test of this is composed of quadrate plates, arranged in rows, like bricks in a wall. In all the species referred to Nebela, which have been observed by Prof. L., in all instances the test is compressed pyriform. Wallich remarks in reference to the tests of Difflugia symmetrica, that they “are sometimes so compressed as to give the aperture the undulating appearance represented in Figs. 27, 29 and 30, but more frequently the tests are not compressed, and the aperture presents the ordinary circular or nearly circular outline.” The species Nebela numata, probably synonymous with D. col- laris, is an exceedingly abundant form, in much variety in our sphagnum swamps, and illustrates well the character of the genus, and also exemplifies the extraordinary variation in the structure of the test, which appears to be common also in the other species of Nebela. In some individuals of Nebela numata, the test is composed of or invested with comparatively large circular disks of uniform size, as represented in the diagram (Fig. 1). In other individuals the disks are of the same character, but oval as in Fig. 2. In other individuals again the test is invested with circular or oval disks | as in the former, but separated, uniformly scattered, and with the intervals filled with small circular disks as in Fig. 3. In other in- stances large circular or oval disks occupy the fundus of the test, and small ones extend from one-half of the body to the mouth, sometimes mingled with a few of the larger disks. In some in- stances the test is composed of minute circular disks alone, or with a few large oval or larger circular ones scattered here and there. Generally the disks of the tests are sharply defined, closely placed, and touching at their contiguous edges. Sometimes they are crowded, and assume in a certain focus a more or less poly- gonal outline. Sometimes they appear to overlap the edges. Usually very distinct; they are sometimes more or less indistinct. 1876. ] NATURAL SCIENCES OF PHILADELPHIA. 117 The large disks in a certain focus appear centrally shaded, and exhibit a striking resemblance to ordinary blood corpuscles. Not unfrequently the test is mainly or almost entirely composed of minute rods, placed in alternating oblique patches, with a few minute round disks, as in Fig. 4. In other tests the disks pre- Fig. 3. Fig. 4. dominate. In some tests large and small disks and rods are in- termingled. In other tests larger, and fusiform rods, probably diatomes, are mingled with disks, as in Fig. 5. Between the structural forms of the tests indicated, all sorts of intermediate forms are found. Occasionally, mingled with the more intrinsic elements of the tests, there are un- doubted diatome cases, and rarely distinct and com- paratively larger particles of siliceous sand. Prof. L. looked upon the disks and rods of the test of Nebela as intrinsic structural elements. They appear to be siliceous, as they undergo no change in heated sulphuric acid. No similar elements could be detected among the ordinary materials among which the animals lived. Dr. Wallich regards the disks and rods, of the forms he has called Difflugia pyriformis var. sym- metrica, as being derived through the metamorpho- sis of diatome cases, through the combination of these with the basal substance of the test. In the reference to his figures 27 to 33 An. and Mag. Nat. Hist. 1864, pl. he says that they “represent the series of forms exhibiting the transition from the ordinary mineral and chitinoid elements of the test to the evolution of the colloid disks.” Prof. L. remarked that notwithstanding he had examined multitudes of Nebela, he was not prepared to confirm this view, though he had too much respect for Dr. Wallich’s accuracy of observation to doubt its correctness. The figures 1-4 represent ordinary forms of N. numata ; and 118 PROCEEDINGS OF THE ACADEMY OF [1876. Figure 5 the relative compression of the test. Figure 6 is the form described as N. flabellulum, which may be regarded as an extremely broad variety of the former. Figure 7 represents the relative thickness of the same test. Between the forms referred to N.numata and N. flabellulwm, all sorts of transitional ones occur. Figures 8, 9 exhibit two views of a narrow form of N. numata, which resembles the Difflugia binodis of Ehrenberg. DV Fig. 6. Fig. 7. Fig. 8. Fig. 9. Figure 10 represents an outline view of Nebela carinata, or Dif- flugia carinata of Archer, from sphagnum of New Jersey. Fig- ure 11 represents a transverse section. Figure 12 Nebela equt- Fig. 11. Fi Se - 9 o = 2, 13; ANA ig Fig. 14. Fig. 15. calceus, a transitional form from N.carinata. Figure 13 a trans- Fig. 10. Fig. 12. verse section. Figure 14 Nebela ansata, which looks as if it were derived from the former by the loss of the horse-shoe-like ribs. Figure 15, another form observed, unnamed, in which, instead of the horse-shoe of Figure 12, there are two hook-like processes pro- | jecting in the interior of the test. Figures 16,17 outlines of Ne- 1876.] NATURAL SCIENCES OF PHILADELPHIA. DES bela sphagni. Figure 18 Nebela barbata. For characters of the species see Proc. Acad. Nat. Sct. 1874, 156. Fig. 16. Fig. 17. Fig. 18. On Certain Trap Rocks from Brazil.—Prof. PERSIFOR FRAZER, Jv., stated that during a recent engagement by the Commission of Brazil to the International Exhibition, now being held here, to examine and arrange the ores, minerals, and rocks of that country, a number of traps were obtained, of which thin sections had been submitted to a preliminary investigation. These have been studied without the aid of chemical analysis, and the results, so far, are hereby laid before the Academy. It is evident that this mode of determination cannot by itself be exhaustive, but it is believed that some new facts are hereby added to our knowledge of the igneous rocks of the globe, and a close analogy between certain species of North and South Ame- rica made out. It was not possible to ascertain the localities in all cases. The following is a partial list :— No. 580.—Between Casa Branca and Rio das Pedras. No. 587.—Between Ouro Preto and Casa Branca. No. 610.—From Resaquinha. No. 790.—Procedencia Morrotos. The following is a hasty glance at their mineral constituents :— No. 279.—Dolerite. Labradorite, Pyroxene, Chlorite, and Magnetite. No. 580.—Pyroxenite rock, with microliths. No. 587.—Pyroxene and Biotite. No. 591.—Decomposed mass, containing Pyroxene and Mag- netite. No. 610.—Chlorite, with concretions of Ferric Hydrate. No. 635.—Under 230 diameters, and without polarized light, the “ flowing” structure is well shown. Between crossed Nicol’s prisms the lines which resemble micro- liths exhibit an intricate network and polarize from white to light blue. Under 1080 diameters the above lines seem to be corrugations or clefts in the mass, while a new set of minute black and brown prismatic crystals come into view, indicating by the gradual curve in the line of their direction also a “ flow 120 PRUCEEDINGS OF THE ACADEMY OF [1876. structure.” Chrysolite (Olivine) and Mica appear to be present in this specimen. No. 665.—Labradorite rock, with bundles of microliths. Con- taining also pyroxene and magnetite. No. 684.—With an enlargement of 350 diameters and between Nicol’s prisms this specimen exhibits Labradorite and Pyroxene (one beautiful main section of the latter). The blades of labra- dorite are smaller and the pyroxene less distributed through the mass than in No. 706. Another mineral not certainly determined polarizes from green to black. No. 692.—Pyroxene in a vitreous paste, containing Chlorite. No. 706.—With a magnifying power of 230 diameters this section exhibits a mass of brown and reddish-brown fragments of irregular shape. The cross fractures are numerous and irregular. Various an- gles of fracture were found to give 84° 47’, 78° 51’, 73° 20’, 538° 59’, and 88° 28’, but the micro-goniometer employed could not be relied on for angles of less than 1°. The latter of these measurements is sufficiently near the pris- matic angle of Augite (7. e. 87° 5’), to suggest the presence of that mineral. Many slabs of Labradorite are associated with it, each of which is readily detected by its characteristic mode of twinning. Black masses of Magnetite are strewn through the field of view, and some rod-like Apatite. Under 350 diameters more crystals of Apatite appear. With ane prism, isolated spots of the mineral first described show feeble dichroism. Dolerite. ‘ No. 769.—Decomposed Pyroxene, with Magnetite and Labra- dorite. The specimen shows signs of the passage of Dolerite into a rock more nearly resembling Diabase from the presence of a chloritic material (perhaps the “ Diabantite” of Hawes), and its generally decomposed appearance. No. 786.—Under 1080: diameters Chlorite and Pyroxene are visible, together with a white, pasty glass. No. 790.—Feldspar, Olivine, Magnetite, and Apatite. No. 795.—Dolerite. Consists of Pyroxene, Magnetite, Labra- dorite, and large numbers of Apatite crystals. (The sections of the Magnetite and of the Apatite crystals are very fine.) Feeble dichroism is observed in spots on the Pyroxene. No Mica visible. No. 795.—Pyroxene, Magnetite, Labradorite, and a large num- ber of Apatite crystals. x. Magnetite, Chrysolite, Labradorite, and some Pyroxene. x’. Labradorite, Pyroxene, Magnetite, and Apatite. Dolerite. 1876.] NATURAL SCIENCES OF PHILADELPHIA. 121 Thin sections of these rocks and also those of similar character from Pennsylvania were projected on the screen in polarized light and compared. Harvey Fisher, Geo. A. Wright, A. C. Lambdin, M.D., John Russel, J. C. Martindale, and A. E. Brown were elected members. The following papers were ordered to be published :— 122 PROCEEDINGS OF THE ACADEMY OF [1876. ON CERTAIN MEXICAN METEORITES. BY MARIANO BARCENA. At the last meeting of the Academy, Prof. Smith having spoken of an aerolite from Chihuahua, I have thought proper to relate some facts about other Mexican meteorites. Certainly, my country is most abundantly provided with these meteoric masses; to the present time they have been found in the States of Chihuahua, Sonora, Sinaloa, Nuevo-Leon, Coahuila, Zacatecas, Durango, San Luis Potosi, Mexico, and Oaxaca. The most notable masses which have been discovered in Chi- huahua are found in the ** Concepcion hacienda,” and in a place called “* Chupaderos.” I have seen two pictures of one of the meteorites of the former place, and, according to the explicatory scale which the drawing had, I could judge that it was of great dimensions ; its form, like that of all the meteorites of Mexico, tends to that of a prism of curved faces, and presenting various irregularities. They have assured me that the mass which is found in Chupaderos is of greater dimensions than the one I have mentioned. Other meteoric irons of various dimensions are found in the vicinity of the ** Presidio del Principe,” in the same State of Chi- huahaa. The National Museum of Mexico possesses various facts about these masses, and probably will get some of the latter, as the inhabitants of that State have promised to send some of them. The Mexican Society of Natural History of the City of Mexico received last year a picture and some small fragments of an enormous meteoric mass lately discovered in the State of Sinaloa. Although I do not remember at present its exact dimensions, still I can assure the Academy that its length was more than twelve feet. I have commenced to analyze that meteorite, and I will conclude the work on my return to Mexico. Like those to which I have referred, it belongs to the class of the SrpErirss of Mr. Daubrée—as it is composed essentially of iron and nickel. It is of a silver-white and grayish color. The aerolites of Nuevo-Leon and Coahuila were found in 1876.] * Santa Rosa” and in the ‘ Potosi.” ing them are few and insignificant. NATURAL SCIENCES OF PHILADELPHIA. 123 The facts we have regard- From Zacatecas they have taken to Europe various samples of meteoric irons; one of them was analyzed by Clark, and had the following composition :— Tron . 86.09 Nickel 9.96 Chromium 0.67 Sulphur : 7 0.84 Magnesia : : : ; 0.19 97.75 Baron Humboldt and other persons have also carried to Europe some samples of meteorites from Durango. The analysis made by Mr. Damour of the aerolite of the Mezquital is known; the composition is the following :— Tron ‘ ; p B : 4 ; . 3 93.38 Nickel . 5.89 Cobalt cE : ; é : 3 0.39 Phosphorus . : : 5 5 ‘ : ; 0.23 99.89 In the National Museum of the City of Mexico exists another meteoric mass, which came from the “ Cascaria” hacienda in the State of Durango. It is composed in great part of iron, and, on attacking its surface with acid, the figures of Widmastaeten appear very clearly—the dominant form of these figures being quadri- lateral. R In the State of San Luis Potosi two aerolites of large dimen- sions were found. One of them, called “* Meteorito de la Descu- bridora,” was sent four years ago to the Mexican Society of Geography and Statistics of the City of Mexico, by Messrs. Cabrera and Yrizar of the City of San Luis Potosi. This mass, which weighed 576 kilogrammes, was divided in several pieces for the purpose of making some investigations as to its structure. The form of the meteorite was also prismatic; it resembled that of a pyramid with a triangular base; the drawing taken with a photographie apparatus presented in its outline several lines well determined, which formed triangular and quadrilateral figures very similar to those produced by hydrochloric acid upon the polished surface of the same mass. The color of the aerolite is 124 PROCEEDINGS OF THE ACADEMY OF [1876. grayish-white, and its texture is notably crystalline. Its specific weight is 7.38. It is composed of Tron i é : ; s ‘ A : : SO: Nickel . ‘ : ; 3 ; ‘ ‘ pele ss00 Cobalt cy .e'e ee ee eee Ie Sulphur 5. ‘ C a 5 ; 7 5 =) JOF45 Chromium . ‘ 3 3 4 5 < i «,. trace Loss ‘ ‘ ; 3 ; ; 2 5 ‘ - 0.05 100.00 The resistance of that iron to rupture by compression is 38 kilogrammes to the square millimetre; the resistance to the rupture by extension is 40 kilogrammes, being the section of the metallic thread of a square millimetre. The coefficient of lineal dilatation between 0° and 100° is 0.0000701. The analysis of the meteorite in question was made by the Mexican chemist, Don Patricio Murphy ; the other studies were made by a commission, of which I had the honor of being a member. My learned friend, Prof. James D. Dana, of New Haven, pos- sesses a fragment of this meteorite, which I sent to him, and in which the figures of Widmasstaeten are perfectly formed. The meteoric iron of the ‘ Descubridora” is also very notable for the many cavities which it has in its interior, and which are occupied by the troilite or proto-sulphide of iron. It presents itself under the form of a crystalline powder of a bronze-yellowish color. Another meteorite from the State of Zacatecas, which was found in the vicinity of ** Charcas” was taken to the Museum of Paris by the French army. Its form is like that of a triangular pyra- mid. Its analysis was made by Prof. Mennier, and is as follows:— Tron . “3 : : : : f . 98.01 Nickel . : : : : : : : : ae abey Insoluble matter in acids s 5 5 3 4 - ORO 98.038 In the State of Mexico have been found several meteorites called * Ocotitlan,” “Toluca,” * Yxtlahuaca,” and Xiquipilco.” The first three were taken to Europe: the “ Ocotitlan’’ was studied by Profs. Burkart and Bergeman, who, on analysis, found the fol- lowing composition :— 1876.] NATURAL SCIENCES OF PHILADELPHIA. 125 iron: >. : - > : : : : : . 85.49 Nickel . ‘ : : 5 - e : ‘ ig es Cobalt . : : ; : : ; ‘ 0.56 Insoluble matter in acids comprising Schreibersite, Gra- phite, etc. . : ; : : : : = +300 99.12 In Xiguipileo the meteoric irons are very abundant, and all proceed probably from a great mass which was broken into pieces. A sample from that locality analyzed by Mr. Pugh had the fol- lowing composition :— Tron : : . : : : ; ? A . 90.43 Nickel . : ; : : : = ; 2 - 7.62 Cobalt . : : . ; , ‘ : P oe Ube: Phosphorus . : : 2 : : : ‘ =~ O15 Sulphur. a - : ‘ : : : : -. 0.03 Copper andtin . : - : - 3 - eee: 0cs Schreibersite . + - ; : - - - - OLaG Graphite : : : ; : : : ‘ . 0.84 99.88 The specimens of a meteoric iron from Xiquipiico are very re- markable for their crystalline structure. Schreibersite is found under the form of white and flexible laminz determining octahe- dral cleavages. In the same collection which the Mexican Society of Natural History of the City of Mexico sent to the Interna- tional Exposition, is found a sample of iron from Xiquipilco, in which I discovered a part of a regular octahedron, raising the lamin of the Schreibersite, which are located in perfect regu- larity on the specimen. The National Museum of the City of Mexico sent also to the Exhibition a sample of meteoric iron from the same locality ; in it is observed an oxidized layer which presents several green spots produced by the compounds of nickel which it contains. That layer to which I refer is characteristic of the iron from Xiqui- pilco. In the State of Oaxaca have been found two very remarkable meteoric masses, which are distinguished by the names of ** Mixteca Iron” and *“ Yanhuitlan Iron.” The first was studied by Profs. Burkart and Bergeman; its composition is the following :— 126 PROCEEDINGS OF THE ACADEMY OF - (1876. itroni. ‘ : ; : . 86.857 Nickel ‘ ‘ : : 3 = SOIg ii Cobalt 5 : ‘ : : SOSA Bnew OrHE alle i : ; ‘ ee 0.524 carbon and iron. Sulphur. te : : : - + 02553 | 0.058 phosphors. Insoluble residue in the acids . 5 WS | 0.451 § 0.133 nickel. 99.117 L (0.265 iron. The meteorite Yanhuitlan” is found at present in the National Museum of the City of Mexico. It was found in the vicinity of Yanhuitlan, by some countrymen when they were tilling the soil, at the foot ofa hill called Deque-Yucumino. Its weight is 916 pounds. The figure of this mass is very interesting, as it approaches remarkably to that of a tetrahedron. Its color is grayish-white. Its specific weight is 7.824, and its composition, discovered by the celebrated Mexican chemist, Don Leopoldo Rio de la Loza, is the following :— rons) Vet ee eT ee hee, ee Seana Nickel : ; : : , : ‘ ; . 1.83200 Volatile substances . ; Z , ; rc . 0.86210 Silicious sands . ; : 3 : : ; . 0.00560 Carbon . : : 3 A : p : . 0.00018 Lime. - 3 5 : : F : : - 0.60815 Alumina . ‘ ; 2 ; : 4 : - 0.61015 100.000 There are other facts about several meteorites from Mexico, but the places where the latter are found are not well determined. That peculiar property, difficult of explanation, which the Mexi- can soil has in attracting the meteoric irons, is even noticed at present; numerous are the shooting stars which cross the atmos- phere of that republic, and more especially in the months of August and November. This phenomenon, which is also observed in other parts of the world, I have seen on various occasions in my country. Lately one of those shooting stars came against a summer-house in the State of Puebla, causing much damage to the occupants. The studies which may be made beforehand of the physical characters and the chemical composition of the meteorites of Mexico, will group the latter in series, and will refer many of them, perhaps, to the same origin, as it is the case with the “ Xiquipilco” meteorite, which, by its crystalline structure and other properties, may be thought to proceed from the same mass. ' 1876.] NATURAL SCIENCES OF PHILADELPHIA. 127 ON THE OCCURRENCE OF HELIX TERRESTRIS, CHEMNITZ, IN NORTH AMERICA, BY WM. G. MAZYCK. In July, 1875, I accidentally discovered a number of dead shells of Helix terrestris, Chemnitz, in St. Peter’s (Episcopal) church- yard, Logan Street, Charleston, S. C., but, notwithstanding a most diligent search, no living examples of the species could be found at that time, owing probably to the prevalence of an almost unprecedented drought. In September, I was, however, fortunate enough to secure two living specimens; which were sent to my friend Mr. W. G. Binney for examination, who kindly furnishes the following description of the jaw and figures of the lingual dentition :— “Jaw slightly arcuate, low, wide; ends blunt, slightly acumi- nate; anterior surface with over 14 broad, crowded, flat ribs, slightly denticulating either margin.” Von Martens (Albers’ Heliceen, p. 116) places the species in the sub-genus Turricula, Beck, giving as the habitat, “Italy and Southern France.” I have never heard of its occurrence elsewhere until its discovery in Charleston, where it exists, as far as I can ascertain, only in St. Peter’s churchyard, accompanied by Helix aspersa, Miller, H. Hopetonensis, Shuttlw., Zonites minusculus, Binney, Pupa marginata, Say, and Stenogyra decollata, Linneus, which latter is exceedingly abundant throughout the city. St. Peter’s Church was burnt in the great fire of December 12, 1861, at which time the greater portion of the shrubbery of the graveyard was also destroyed. The ruins of the building were removed about two years ago, and, the shrubbery not having been renewed, there is but little shade, a circumstance which has, doubt- 128 PROCEEDINGS OF THE ACADEMY OF [ 1876. less, greatly retarded the propagation of the species which has probably existed in small numbers for several years in this very restricted locality. I am indebted to Mr. Thomas Bland for the determination of the specific name. Specimens of the dead shells have been deposited in the Museum of Comparative Zoélogy, Cambridge, Mass., in the cabinets of Mr. W. G. Binney and Mr. Thos. Bland, and may be seen in my own collection. 1876. ] NATURAL SCIENCES OF PHILADELPHIA. 129 FOURTH CONTRIBUTION TO THE HISTORY OF THE EXISTING CETACEA. BY E. D. COPE. Grampus griseus, Cuvier. PI. III. A specimen apparently belonging to this species was taken by the United States Commission of Fisheries off the coast of Mas- sachusetts. Its appearance may be learned from the accompany- ing plate, which is copied from a drawing made on the spot by the artist of the Commission. Its length is five feet five inches; the length of the pectoral fin, measured along its median line, is nine inches. Globicephalus brachypterus, sp. nov. Globicephalus? sp. noy., Cope, Proceedings Academy Philadelphia, 1866, p. 8. A female of this genus was taken by fishermen, in February of the present year, on the east coast of Delaware Bay, at the mouth of Maurice River, and was sent to this city, where it fell under my observation. Its uninjured condition offered an opportunity of making a description of its external proportions and appear- ance. This had been a desideratum, since the examination of a cranium several years ago had led me to suspect that the black- fish of the middle and southern Atlantic coasts of the United States is a different species from the Globicephalus melas of the northern coasts of both continents. The measurements of this specimen are as follows :— Feet. In. Total length, measured along the side 2 : ; Bale 6.5 Length to base of dorsal fin 37 Length of base. of dorsal fin 24 Elevation of the dorsal fin 9 Length of the pectoral fin 25.5 Greatest width of pectoral fin 7 Width of thorax between pectoral fins 18 Depth at middle of dorsal fin : : 30 Length from vent to end of tail (on sgnyenitnys. 52 Depth of caudal peduncle half way between anus and ant of tail 22 Expanse of flukes 43 The color is a uniform black, without any markings whatever. 130 PROCEEDINGS OF THE ACADEMY OF [1876. The profile of the head has the protuberant convexity of the other Globicephali, with a very narrow projecting lip. The gene- ral form of the body is elongate, more so than in the G. melas; and the dorsal fin has a more anterior position. Instead of standing near the middle of the length, it rises at the end of the anterior fourth of the length. Its base is unusually long, and its elevation not great. Its superior border is convex, and the apex decurved behind so as to be slightly descending. The posterior or caudal part of the body is much compressed, and maintains its depth with a very gradual diminution until near the flukes, where it contracts more rapidly. The blow-hole is situated at a point less than half way between the points opposite the eye and front base of pectoral fin; it forms a fissure, which presents a shallow concavity forwards. The anterior base of the pectoral fin is situated at the anterior third of the distance between the blow- hole and the front border of the dorsal fin. It is characterized hy its relatively small size, and offers one of the distinguishing features of the species. It enters the total length six times, while in the G. melas, according to Van Beneden, it enters the total 4.5 times in a fully grown foetus, and the length increases with age, according to Flower, so that its proper length would be about one-fourth of the total. This measurement nearly agrees with that given by Dr. Jackson, as obtained by him from a specimen from the New England coast, which I suppose to belong to the G. melas. In a specimen taken by the U. 8. Fish Commission, the length of the pectoral fin is nearly as in the G. brachypterus. This probably represents the G. intermedius, Harl., and has a white abdominal band, and light gular areas. The teeth in the specimen from Maurice River are small, and number five in the upper jaw and six in the lower. There is a mammary fissure on one side of the vulva, and a fissure with an additional fold on the other side. The skeleton of this specimen presents several interesting char- acteristics. The cranium differs from that of G. melas in the ante- rior lateral expansion of the premaxillary bones, so that they entirely conceal the maxillaries when viewed from above. This character is not seen in numerous specimens of the G. melas from Cape Cod. The front teeth are less firmly implanted in alveoli than those of the G. melas; thus on one side of the maxillary bone, four alveoli are filled with osseous deposit; and on the 1876. ] NATURAL SCIENCES OF PHILADELPHIA. 131 other side, one. The cervical vertebre are all coodssified, and they present no parapophyses, and but one diapophysis on each side (the seventh). Three segments of the sternum are preserved, which are longer than broad, the anterior two codssified. The first / one is furnished with recurved antero-lateral processes, and is divided in front by an oval foramen. The scapula is as wide as high; it presents a rather long, truncate, coracoid process, and a 132 PROCEEDINGS OF THE ACADEMY OF [1876. prominence of the proximal part of the spine, which represents the acromion. The cranium which I formerly described (Proceedings Academy Philada., 1866, p. 8) is that of an adult of full size. I remarked Fig. 2. at that time that it differed from the crania of the G. melas from the European and New England coasts in the greater width of the premaxillary bones, which extend to the lateral borders of 1876. ] NATURAL SCIENCES OF PHILADELPHIA. 133 the basal two-fifths of the maxillaries; and also in the small number of maxillary teeth, there being only five alveoli in the upper jaw. The existence of the same number of teeth in the Fig. 3. specimen now described proves that this small number in tlie adult is not due to shedding, or connected with age, and it is probably a constant character of this species. In the G. melas 134 PROCEEDINGS OF THE ACADEMY OF [1876. there are ten teeth in the maxillary bone, as I have observed on numerous specimens from the New England coast. In review, the Globicephalus brachypterus is characterized by the short pectoral fins, the few teeth, the wide premaxillary bones, and the absence of white band along the median line of the lower surfaces. The anterior position of the dorsal fin is also probably characteristic. In the two characters first enumerated, it ap- proaches the genus Grampus more nearly than does any other well-known Globicephalus. The cuts represent the profile and superior and inferior surfaces of the skull of the larger individual above mentioned. Phocena lineata, sp. nov. This new porpoise is represented by a single specimen, which was taken in the harbor of New York not many months ago, and sent to the Smithsonian Institution, where the skeleton is now preserved. Under direction of Professor Baird, a plaster cast of the animal was made and colored directly from the specimen, with the excellent result of offering a means of study more reliable than the dried skin, where the form is likely to be distorted from various causes, and the color changed by the action of the oil. 208 .118 ‘* at post condylar angle . : : . 069 .085 146 PROCEEDINGS OF THE ACADEMY OF [1876. One ramus nearly entire, and the molars of the other (except- ing the last) were obtained near the Pawnee Buttes of N. E. Colorado. ‘ The evolution of the existing types of Camelide is a good illus- tration of the operation of the laws of acceleration and retarda- tion. In evidence of this we may follow the growth of the foot, and dentition of the most specialized, and therefore the terminal genus of the series, the American Auchenia. It is well known that the animals of this genus, in common with other ruminants, have the constituent metapodials of the cannon bone distinct during alonger or shorter portion of foetal life. As these ele- ments are permanently distinct in the oldest or Miocene genus Poebrotherium, it is evident that acceleration of the process of ossification has caused their union at successively early periods in the genera of later ages. This is indicated by the long dura- tion of their separation in the Loup Fork genus Procamelus. It is also well known since the time of Goodsir, that the embryos of ruminants exhibit a series of superior incisor teeth, which disap- pear early. It is probable, but not certain, that in the Miocene genus Poébrotherium, as in various contemporary selenodont Artiodactyla, that the superior incisors persisted. He had, how- ever, discovered that these teeth persisted in the Loup Fork genus Protolabis during adult life. He had also found that one, the second of these teeth in Procamelus occidentalis, persisted without being protruded from the alveolus until nearly adult age. In genera (e. g., the bunodont Artiodactyla) where the incisors are normally developed, they appear at about the same time with the other teeth, and continue to develop to functional completeness. This development is retarded in Protolabis, since they are not so matured as to remain fixed throughout life in their alveoli. In Procamelus the retardation is still greater, since the first incisor reaches very small dimensions, and is, with its alveolus, early removed, while the second incisor only grows large enough and for a sufficient time to occupy a shallow alveolus, without extend- ing beyond it. In the first incisor the process of retardation has reached its necessary termination, 7. e., atrophy' or extinction ; while in the existing Camelidx the second incisor also has dis- appeared in the same way. In ruminants other than Camelide, the third or external incisor has undergone the same process; while, in the Bovide, the canines also have been retarded in de- velopment, down to atrophy. In the genus Auchenia, as has been pointed out, the premolar teeth are two in number; in Poébrotherium of the lower Miocene, they number four, the first and second of the normal mammalian series being present. The first premolar is present in Poébrothe- rium, Protolabis, Procamelus, Pliauchenia, and Camelus; it is ' See Proceedings Academy, Philadelphia, 1876, p. 17, for an explana- tion of these terms. 1876. ] NATURAL SCIENCES OF PHILADELPHIA. 147 wanting in Auchenia and other Ruminantia. In the latter it is present in the feetus, but soon disappears; in Auchenia, accord- ing to Owen, it is retained for a somewhat longer time.’ Thus retardation of the growth of this tooth is first seen in the latter genus so far as known, and is more pronounced in the other Ruminantia. The second premolar is present in Poébrotherium, Protolabis, and Procamelus; it is absent in Pliauchenia, Came- lus, and Auchenia. In the last two genera it is a transitional character of immaturity, and we may infer that this is also the case with Pliauchenia. It is thus evident that retardation in the supply of nutritive material to this tooth has caused its reduced size, and terminated the duration of its existence. This has not occurred in the other lines of Ruminantia, where it remains as in Poebrotherium. From these and many analogous eases, the general law may be deduced, that identical modifications of struc- ture, constituting evolution of lypes, have supervened on distinct lines of descent. EK. O. Thompson and A. E. Foote, M.D., were elected members. Dom Pedro II., Emperor of Brazil; Capt. Luiz de Saldanha da Gama, of the Brazilian Navy, and Dr. José de Saldanha da Gama, of Rio Janeiro, Brazil, were elected correspondents. The following paper was ordered to be published :— 1 Odontography, p. 530. 148 PROCEEDINGS OF THE ACADEMY OF [ 1876. DESCRIPTION OF A NEW SPECIES OF ZGIALE AND NOTES ON SOME OTHER SPECIES OF NORTH AMERICAN LEPIDOPTERA. BY HERMAN STRECKER. Fgiale Cofaqui, nov. sp. 2. 24 inches in expanse. Head dark brown; palpi whitish; thorax brown, mixed with hoary, posterior half, above, clothed with yellowish hair; abdomen brown; antennez black above, white beneath, terminations black. Upper surface of wings blackish-brown. Primaries with an ex- ceedingly irregular, bright, deep yellow band, extending from vein 1 to the subcostal nervure; the outer edge of this band is rather regular from veins 1 to 4, though further removed from the exte- rior margin at the latter than at the former; from veins 1 to 2 it is narrow, from veins 2 to 4 it is nearly three times as broad ex- tending to where vein 8 joins the median vein, the balance of it is within the discoidal cell and is narrow, of about the same width as it is between veins | and 2; the portion of this nearest the costa is paler in color than the rest. Between veins 4 and 6, exterior to this band, is a mark composed of two small almost connected yellow spots. Interior to these, between veins 6 and 9, is a narrow yellowish-white mark. Midway between the inner edge of the large yellow band and the base of wing, and between veins 1 and 2, nearest to the latter, is a roundish yellow spot. Inner half of base covered with rich yellow hair. Fringe yellowish-white, alter- nated with dark brown at terminations of veins. Secondaries. Basal third, especially in inner part, heavily clothed with rich yellow hair and scales. A band of four yellow spots, separated only by the veins, cross the wing beyond the middle; from this band towards the costa, opposite the apex, is another quite small yellow spot, which is succeeded by a larger one near to the costa, nearly midway between the apex and base of wing. Outer margin between the veins yellow, forming patches more or less triangular, with the points inwards. Fringe yellow- ish-white. Under surface. Primaries brown, not as dark as above, and shaded at outer margin and apex with hoary; no yellow at base of wings. Markings as above, excepting that the yellow band is _s 1876. ] NATURAL SCIENCES OF PHILADELPHIA. 149 continued from its lower end to, and connected with, the yellow spot between it and the base, and between veins 1 and 2. Secondaries. Hoary or whitish-gray, dark-brown along costa, especially towards the base. Towards anal angle, a pure white spot, corresponding in position with the first of the series of four that compose the yellow band of upper side; each of the remain- ing yellow spots of upper surface, and the next one of the two, between them and the costa, is represented by a small dark-brown spot, or rather row of continuous spots; the last towards costa is replaced by one of pure white; half way between this latter spot and the base is another white spot, and also one in discoidal cell, from which a dark-brown line extends to near abdominal margin. Fringes white and brown. In markings of upper surface, this species resembles somewhat closely the lowermost of Boisduval’s figures on plate 70, in the Lep. Am. Sept., but the outline of the wings is entirely different. In the present species the primaries are much produced at veins 2 and 3, and from veins 38 to 7 they are hollowed, making the wing most decidedly fulcate, though the apex is very slightly rounded. The inferiors are narrow, even between the apex and abdominal angle, and the wing at the former is not rounded, but the costa and exterior margins meet at almost a right angle. As far as outline goes this species has no possible resemblance to Boisdu- val’s figures, or to the species he purports to represent, the history of which has been given in full detail by Prof. Riley,in Trans. St. Louis Acad. Sc. That species, 4. yucce, has much longer and comparatively narrower fore wings, and the shape of exterior mar- gin of these is just the reverse of the present described species, the hind wings are also as entirely different in shape as can be in two insects generically the same. The under surface of inferiors in yucce is brown, broadly bordered with whitish-gray, especially at the costa, and with a large triangular white spot below costal vein about one-third the distance (from base), between base and apex. The present species has under surface of secondaries grayish, with dark-brown costa, and four conspicuous white spots on various parts of the wing. Boisduval’s lower figure may have been intended to represent this insect, but his upper two figures show the upper and under surface of yucce, though none are correct as regards shape of wings, especially of the inferiors. All three figures on his plate were either drawn from three different examples, or the 150 PROCEEDINGS OF THE ACADEMY OF [1876. artist was most culpably careless, as none are of same size, or agree in outline, though the presumption would naturally be, that the middle figure with wings erect, was intended to represent the under surface of one of the others. What leads me further to sup- pose that two species are figured on Boisduval’s plate, is that the lowermost figure has the small spot on inner half of primaries, of which Prof. Riley says, that of the ten specimens of yuwece he had examined, “none of them have the spot on primaries, indicated in one of Boisduval’s figures, just within the middle of the wing and below vein 2.” I have placed this insect in Agiale, where, with yucce, I think it belongs; Seudder’s Megathymus I consider but a synonym of Felder’s genus. The example from which the foregoing description was made was captured in Georgia. Papilio Indra, Reakirt. 9.* Same size as %. Primaries somewhat faleate, broader and less produced apically. Secondaries more rounded exteriorly; the rudimentary tail even less conspicuous than in the other sex; macular bands on all wings nearly twice the breadth, on seconda- ries covering part of the discoidal cell. The discal bar of prima- ries better defined, and at two lines distance inwardly succeeded by another paraliel bar, which on the under surface is widened into an ovate spot. In other particulars same as %. - Two 92 examples taken by Mr. Duncan Putnam, July Ist, 1872, in Clear Creek Cafion, between Golden City and the Forks of the Creek, Colorado. The example above described, through the courtesy of Mr. Put- nam, has passed into my keeping, the other, which is still in that gentlemen’s collection, differs mainly in the mesial band of secon- daries being entirely exterior to the discoidal cell. These are the only females that I have yet heard of, and no males were seen by Mr. Putnam, nor have any been taken, to my knowledge, since the original types, captured by Mr. Ridings in 1864, on Pike’s Peak, Colorado. 1% described in Proc. Ent. Soc., Phil. VI. p. 123 (1866), and figured by myself in T. II. Lep. Rhop. et Het. 1876.] NATURAL SCIENCES OF PHILADELPHIA. 151 Cossus nanus, nov. sp. Expands 1} inches. Has the appearance of a miniature Cossus ligniperda, is gray, of lighter and darker shades, and reticulated with black lines which are most noticeable across the disk and on the terminal part of wing. Secondaries uniform grayish. Beneath grayish, faintly reticulated. Hab. Colorado. Arctia cervinoides, nov. sp. Expands 7 inch. Head black, white above the eyes. Collar white, with two black bars. Thorax white, with three black bands as in Nazis, and others. Abdomen black above; at sides and be- neath, each segment is broadly edged with white. Upper surface. Primaries white, marked with black almost exactly as in Phyllira, Drury. Secondaries with obscured grayish, ill-defined marks almost semi-diaphanous, resembling those of Quenselii, Payk. Under surface marked as above, but paler on primaries. Entirely distinct from all known North American species, nearer to Quenseliz, from Labr., and Cervini, Fall., from summit of Alps, than any others I wot of. It is from Colorado. Cymatophora magnifica, nov. sp. %. Expands 1} inches. Head and collar chestnut-brown; an- tenn pectinated and brownish; thorax ashen-white, with a few scattered brown atoms; abdomen brown; legs clothed heavily with whitish-gray hair. Upper surface. Primaries lustrous brownish-gray or ashen; the outer space, forming a large oval spot extending from apex to inner angle, is brownish-yellow of a somewhat golden tint; this space, as well as the whole upper wing, reminds one strongly of Phalera Bucephala, Lin.; on the outer edge of this terminal space, midway between the apex and inner angle, is a parallelogramic brown spot; the inner margin also of this terminal space is edged irregularly with brown marks; the part of the wing adjoining this is paler than the rest; at base of wing is also a pale patch same color as thorax; the whole surface of wing, except the yellow ter- minal space, is more or less reticulated or flecked with dark brown; none of these reticulations are very conspicuous, except a few which form an abbreviated slight transverse band, which extends neither to costa nor inner margin, and is distant from thorax about 152 PROCEEDINGS OF THE ACADEMY OF [1876. one-third of the length of the wing. Secondaries brown, with paler fringes; they are remarkably produced at the outer angle. Under surface brown, with indistinct reticulations; the square mark on outer margin, midway between apex and inner angle, is repeated. Hab. Florida, captured by Mr. J. Doll. It is doubtfulif this is by any means a true Cymatophora, though it undoubtedly belongs to the Cymatophoride, HS.; the pectinated antenne would seem to indicate a position near the insect described as Dicopis muralis, Grote, but there is plenty of room for any one who has the inclination to make a new genus for its reception. For my part, I would take infinitely more pleasure in doing away with many of the genera erected of late on trifling grounds, than in adding to the confusion by creating new ones. Cosmia perophoroides, nov. sp. Expands 13 inches. Head and thorax pale brownish, insensibly fading into yellowish-white as it nears the abdomen, which latter is also yellowish-white; tarsi dull crimson. Upper surface. Primaries, same yellowish or tawny-white as in the Bombycid Perophora Melsheimerii, which the whole insect superficially resembles in color and ornamentation; the costa, outer and inner margins, edged with a dull crimson line; the whole surface of wing powdered with minute crimson scales; a narrow crimson transverse anterior line, elbowed outwards almost at a right angle in its middle, crosses the wing from costa to inner margin, as also does a transverse posterior line of same color; this latter is rather straight, making but a slight curve a short distance from the costa. Secondaries white, powdered, not heavily, with red at outer margin; fringes white. Under surface. Primaries, basal third, white, rest reddish, paler towards outer margin, which is edged with a narrow red line, as is also costa and inner margin. Secondaries white, bordered with. a few minute red scales on costa and at apex. Taken in Florida by Mr. J. Doll. Phrygionis argentistriata, nov. sp. Expands 13 inches. Much the same silky gray or dove-color as in P. cultaria, Geyer, to which it is closely allied; but differs in the gray being a little more inclined to brownish, less bluish, in the inner edge of band that crosses all wings being very much 1876.] NATURAL SCIENCES OF PHILADELPHIA. 153 less silvered, and in veins of hind wings being yellow, narrowly edged with black, from inner edge of this band to past the middle of wing, the yellowish veins being continued or shot off from the yellow of cross band; the sub-basal band of primaries is irregular and strongly elbowed in middle; whilst in cwlfaria it is straight from inner margin to costa. Near the angle produced at middle of exterior margin of secondaries, is a rather large oblong dark red spot, tipped at its outer end with silver; near this, on side towards abdominal margin, is a smaller triangular spot of same color, also with a little silver at outer end; between this and anal angle are two more spots of red and silver, but quite small. The band common to both wings is not nearly so strongly elbowed outwardly in its middle as it is in cultaria, and the space between this band and outer edge of secondaries in that, is not nearly so broad as in the species at present described. Florida, from Mr. J. Doll. Euclea penulata, Clemens, Proc. Acad. Nat. Sci. Phila., p. 159 (1860), is the insect lately redescribed under the name of Parasa incisa by Dr. Leon Harvey in Can. Ent., p. 5, vol. viii, 1876. His type he received from Belfrage in Texas, who also sent me exam- ples of it, which, as above stated, turned out to be Clemens’ species. 11 154 PROCEEDINGS OF THE ACADEMY OF [1876. Avaeust 1. The President, Dr. RUSCHENBERGER, in the chair. Twenty-four members present. Diurnal Motion in Liatris pycnostachya.—Mr. MEEHAN called attention to a peculiar diurnal motion he had observed in Liatris pycnostachya. When throwing up its flower stems the top was always curved over towards the east in the early morning, nearly erect at midday, and towards the west at sundown. For commer- cial purposes he had thousands of plants growing, and the habit was uniform in all. The motion was evidently vertical, and not in a horizontal direction, and this still left it open to ascertain how the point turned towards the east for its early morning start. As soon as the flower spike approached its full growth the motion ceases. Fasciated Branches.—In reference to a broadly flattened branch of a sweet potato on the table, to which attention had been di- rected by a member, Mr. MEEHAN said these branches were found on numerous plants, and there was no reason why all plants may not be found to produce them. They were species of fasciations, which took different forms at times. In trees they often appeared as “crow’s nests.” The old theory referred them to over-lux- uriousness; but in a paper published in the Troy Proceedings of the American Association it was shown to be just the reverse. In union there is strength, in vegetable as in other bodies. Any tendency to a multiplicity of small branches on a tree instead of making a few large ones, all other things being equal, is an evi- dence of lower vitality. And this was proved by these fasciations. In severe winters fasciated branches were the first to die. Often they were the only branches that were destroyed. Again, it had been shown in his papers before the American As- sociation and before the Academy of Natural Sciences of Philadel- phia, that only when a flowering portion of a plant was in the best conditions to maintain its hold on life, in other words in the highest conditions of vitality, did it produce pistils, or female flowers. With a lowered or depreciated vitality the male organs of the flower or male conditions were favored, and it was a singular fact that whenever these fasciations flowered, the female organs were nearly always abortive, and stamens and petals increased at their expense. These were some of the facts which had proved the old notion that over-luxuriousness, in the sense of high vital power, had nothing to do with fasciations, but rather the reverse. The final cause of this defective vitality was imperfect nutri- 1876. ] NATURAL SCIENCES OF PHILADELPHIA. 155 tion in that immediate part. This was as near to the full expla- nation as science could get as yet. The facts were not as new as he liked to bring before the Academy, devoted as it is to original research; but the conclu- sions of the Troy paper are rather recent, and not yet well known, and this might excuse his remarks. Mineralogical Notes.—Dr. Grorcre A. Ka@niea spoke about the coloring matter of the amazon stone from Pike’s Peak. This beautiful mineral has lately been obtained in large specimens and in considerable quantity through the exertions of Dr. Foote, who furnished the author with the material for this investigation. The color of the amazon stone from Pike’s Peak varies between a light bluish-green and a dark emerald-green. On many specimens the faces of modification, as prisms and domes, are without color, or yellowish, or flesh-colored. The interior of very large crystals is likewise of a much lighter color generally than the outside. Assuming the coloring principle to be a compound of iron, the following experiments were made to test the value of this hypo- thesis :— | 1. Fragments were exposed to the action of boiling hydro- chlorie acid and aqua regia for several days, until the liquid was free from iron. Under this treatment the intensity of color was increased, the coloring substance withstands, therefore, the action of the above agents. 2. Fragments, prepared by the treatment described, were placed in a glass tube, and hydrogen passed through the latter at a red heat. After cooling, the mineral was found possessed of an evenly spread gray color. 3. The same pieces were now treated with oxygen at a red heat, and exhibited, after cooling, an even rose color, the intensity of which was proportional to the intensity of the green. 4. Green fragments were heated in an atmosphere of dry chlo- rine, at increasing temperatures. No change occurred until ata red heat, when the mineral became perfectly white, and a slight sublimation of ferric chloride was noticed. 5. The rose-colored pieces become white when boiled in strong hydrochloric acid. 6. Thin fragments do not show at any place a concentration of the green color, when examined under the microscope. 7. Heated in the outer flame of a Bunsen burner, the same effect is caused as in the current of oxygen, but with a less brilliant color. These experiments prove— First. That the basis of the coloring substance is 77on. Second. That the iron is present as a very stable compound, probably as an organic salt. Third. That the coloring substance is not in molecular combi- nation with the feldspar; because, if it were so, the iron could 156 PROCEEDINGS OF THE ACADEMY OF [1876. not be extracted completely by hydrochloric acid from a solid piece after oxidation; but that the color is of later date, and caused by infiltration into the numberless capillary cleavage fis- sures of the mineral. Investigation into the composition of the organic acid is re- served for a future communication. Dr. Ka@nte also mentioned his discovery of Zircon in the ama- zon stone from Pike’s Peak. Dr. Foote had observed brownish spots in the feldspar, with an apparent cleavage. The speaker was able to extract complete crystals, showing a tetragonal habitus: P +o Po. The largest crystal measures } inch in length by } inch square. The angle of the pyramidal faces was found 122°, which is near the zircon angle. The prismatic faces are uneven by the preponderance of a step-like structure; there is a prismatic cleavage. Lustre, greasy vitreous; color, dark grayish-brown; fracture, straight. H—6.5, spec. gr. — 4.065. Every crystal is associated with columbite in well-defined pris- matic needles, which pierce the zircon. The powder has a cinna- mon color. Owing to the deficiency of material, only an approxi- mate analysis can be given for the present. SiO, = 28.00 MgO = 8.93 (Fe,0,)Zr0, — 60.00 HO 345 100.40 Besides the large percentage of magnesia, there is a very anom- alous behavior in the zirconia. It is easily soluble in oxalic acid, and the oxalate dissolves in a very small quantity of water, and is not decomposed by boiling in a dilute solution. He had since established the same behavior in the earth from the Clay County, N.C., zircons, and was still engaged in the study of this matter. Dr. Kania mentioned further the occurrence of earthy barite on the calcite from the city quarries of St. Louis, Mo. This mineral is found in very friable clusters between the large crystals of calcite. Color perfectly white. Under the microscope the powder resolves into transparent prismatic crystals. They are small enough to pass through the meshes of a hair sieve. The analysis gave— BaSO, —98.8 HeO: ens Ignition — 0.14 99.44 This is one of the purest varieties of barite on record. GQ == 1876.] NATURAL SCIENCES OF PHILADELPHIA. 157 On Frost-Drift in North Carolina.— Prof. W. C. KeErr re- marked that there are some peculiar features in the surface geology of North Carolina which have not hitherto been accounted for. We have no true glacial drift, or at least none well charac- terized. But besides the ordinary quaternary gravels which over- lie a large section of the coastward half of the State, there are found, chiefly on the flanks and among the foothills of the Blue Ridge, and over a considerable portion of the Piedmont region, beds of earth and stones which are characterized by a peculiar arrangement of their materials, explicable neither on the theory. of their being morainal nor modified drift. Reference was made to the subject in the North Carolina Report of last year, and a theory suggested; but as illustrations were wanting, it was not practicable to do more, and he should require the blackboard now to make the matter intelligible. He represented, in a diagram, the succession of different arrangements of the detrital materials as they may be seen in descending the slopes on which these accu- mulations are found. All our gold gravels come under this de- scription of quaternary deposit. In one part of the diagram the arrangement which obtains in the higher portions of the deposits, nearest the source of the materials, was represented. The lower part, perhaps one-half or one-third of the vertical depth, is filled with angular and little worn fragments of quartz and other hard rocks; the upper part being simply unstratified earth. As we descend the slope, the angular blocks have become more rounded, and are accumulated in a successively lower and more crowded stratum, at last hugging closely the surface of the underlying rock. In the case of the auriferous gravels, the gold is found, of course, only on the upper slopes, and near the sources of the ma- terials, its greater specific gravity insuring its speedy descent to the bottom of the moving mass. It is perfectly obvious, both from the position of these beds on the slopes of hills and moun- tains, up to 1500 feet above the sea, and from their arrangement, that they have not been deposited under water. And it is equally evident that they are not true glacial drift ; and, indeed, they are readily traced, in many cases, to their sources, distant only a few rods, or even feet. But he had not hit upon the solution of the question of the origin and mode of accumulation of these beds until he had accidentally found in a railroad cut near Morganton, the structure indicated in the second diagram, where a small quartz vein was represented rising up, undisturbed, through the underlying strata of rock, in a nearly vertical direction, until it reaches the lower surface of the deposit in question, where it is seen to be suddenly interrupted, and its materials—angular frag- ments—strewn along the surface of the rock, down the slope a distance of several yards. A close study of this phenomenon at last suggested the theory which he had proposed of frost drift. It is obvious that in subglacial regions (and in glacial regions in subglacial times) the annual frosts of winter would penetrate to a 158 PROCEEDINGS OF THE ACADEMY OF ' (1876. great depth; and likewise the summer thaws, aided by the enor- mous precipitation which characterized those regions and times. And it is equally obvious that a mass of water-saturated earth, in freezing and thawing, must be subject to the same laws of move- ment as a true glacier, the rate of motion being proportioned to the quantity of water. The depth of some of these deposits at first presented a difficulty, this depth rising in some cases to twenty and even thirty feet, although they are for the most part less than half that depth. But after learning that in Vermont, in the winter of 1874-5, the frost penetrated to a depth of eight feet, and that in Siberia and other subarctic regions the ground is annually frozen and thawed to amuch greater depth, there seemed to remain no part of the phenomena presented by these beds which is not satisfactorily accounted for by the theory. The occasion of his bringing this subject to the attention of the Academy was this: In passing an excavation on Market Street, above Forty-Fourth Street, he had observed a new and striking confirmation of the view just presented. In an accumu- lation quite like those already described as occurring in North Carolina, this additional feature was observed: several banded seams of decomposed mica schist, standing nearly vertical in the undisturbed rock below, on reaching the lower edge of the drift were bent at a sharp angle, in the direction of the movement of the mass, down the slope, and were traceable many feet, diminishing with a gradual and regular taper in a horizontal direction, until lost in the homogeneous mass of earth which formed the body of the bed. How this happened is obvious enough on the theory given, but on no other known to him. AveustT 8. The President, Dr. RuscHENBERGER, in the chair. Twenty-seven members present. On the Diurnal Opening of Flowers.—Mr. Tuos. MEEHAN re- ferred to observations he had made this season on the nocturnal and diurnal expansion of flowers, and said that, contrary to the popular impression, it was not probable that light or its absence alone determined the opening of the blossoms. ‘There were some plants, as, for instance, @nothera biennis, the evening Primrose ; Anagallis arvensis, the “ Pimpernel,” and others, which remained open or otherwise longer when the weather was humid or cloudy, and were looked on in consequence as kinds of floral barometers ; but from other facts it was clear that it was not the weather merely, but some other incident accompanying the weather that governed the case. For instance, though @nothera biennis, and other Gnotheras, 1876.] NATURAL SCIENCES OF PHILADELPHIA. 159 opened at evening, and, if the atmosphere be moist, continue open the greater part of next day, many species opened only in the daytime ; and this they did regularly, quite regardless of meteoro- logical conditions. . serrata of Colorado was one of these. It was regular in opening about noon; the blossoms were all closed long before sundown. In other allied families we saw similar divergence. In the Cactus family, Opuntia and Mammillaria opened only about mid- day; while most of the Cereus opened at night. The night- blooming Cactus was a familiar example. But the chief interest was in the fact that many had their special hours of day or night for the expansion. The Portulaca oleracea, common Purslane, opened about eight A. M., and by nine had performed all its functions ; while a closely allied plant, the Zalinum teretifolium, from the serpentine rocks of Chester County, opened at one P. M., and was closed by three. The conditions of the weather did not seem to influence them. There was the same attention to daily periods in the growth of the parts of plants, as well as in the expansion of the petals. In composite plants the floral growth was generally in the morning, and was usually all over by nine or ten o’clock A.M. The elongation and expansion of the corolla was usually completed in an hour after sunrise, but the stamens grew for an hour more, and the pistil continued for still another. There was little if any growth in the floral parts after nine o’clock in a very large por- tion of this order of plants. In grasses, Cyperacex, and some rushes also, the floral parts were very exact in their time of opening. In the plantains (Plantago) the pistils appeared a day or more in advance of the stamens; and these last appeared at about a regular time in each day. In Luzula campestris, the wood rush, he had by a series of observations timed it exactly. Before nine the anthers’ were perfect, but by ten the pollen has been all committed to the winds, and only dried membranous matter remained. So far as he could ascertain, meteorological conditions did not influence the time in the least in this case. The popular impression of light and moisture as agents in this behavior, had seemed to receive a tacit scientific assent. It was clear, he thought, there was a more powerful agency underlying these; and it was, perhaps, a gain to science to be able to see this, though in so dim a light. Dr. Henry C. Chapman was elected curator in the place of Mr. Tryon, resigned. 160 PROCEEDINGS OF THE ACADEMY OF [1876. Aveust 15. The President, Dr. RuscHENBERGER, in the chair. Twenty-three members present. On Hexagonite, a New Mineral.—Mr. KE. GotpsmitH remarked that Mr. John C. Trautwine, of Philadelphia, had been kind enough to present to him a mineral from near Edwards, St. Law- rence County, N. Y. As it was not comparable with any of the known species that occur in said locality, it was presumed by Mr. T. to be new. The mineral is crystallized hexagonally, the forms noticed being the infinite pyramid (110), and the basal plane (111). The crys- tals are small, from about 3 mm. in length and 1 mm. in thickness, although some are 5 mm. thick. Two distinct cleavage planes were observed, which could be easily produced by striking the specimen with the hammer. It was found that these planes inter- sected at 120°; there is a third cleavage plane parallel to (111), but less smooth than the former. Fracture uneven. The small crystals and fragments are trans- parent, while the thicker ones are semi-transparent. Lustre subvitreous, somewhat glimmering on the cleavage (110); on the basal plane the lustre is dull. A basal cleavage fragment was introduced between two Nicol prisms transmitting no light, in such a way that its principal axis formed a continuous line with that of the prism, and, no change in the light being observed, the crystal was pronounced uniaxial. The coior is pale violet, but not equally distributed ; the mineral in spots is colorless, and it is thought that if the sub- stance was absolutely pure it would have no color. The coloring principle, which is a small quantity of manganese, is so finely dis- tributed through the mass that it is impossible to separate it mechanically. The streak is colorless, and so is a large bulk of the powder. The substance is brittle. Its hardness is between apatite and orthoclase; that is, 5.5. 5. — 2-01 If the substance, in the form of a thin splinter, is heated to redness in the Bunsen burner flame, no change is produced; the same is the case if the oxidizing flame with the blowpipe is di- rected upon it; but a rounding of the sharp edge of the splinter is effected by treating it in the reducing flame; the transparent substance then becomes opaque and white, enamel-like. On moistening this rounded spot with cobalt solution, and strongly reheating, a violet coloration is produced. In the glass tube there 1876.] NATURAL SCIENCES OF PHILADELPHIA. 161 is no change whatever. The flame reaction indicates the pres- ence of soda. From the above observation he pronounced the mineral to be infusible. Fused with microcosmic salt, it shows a skeleton of silica; and if heated with borax in the oxidizing flame, the reaction of man- ganese is observed ; the same if heated with carbonate of soda in the oxidizing flame. On coal heated with cobalt solution a violet mass is produced, which is due to the presence of a small quantity of alumina and a larger of magnesia. In regard to its solubility in acids, it was observed that it yielded only to hydrofluoric acid, the others having no effect. The fine powder was fused with carb. soda, in order to find all the elements contained in it by the processes in qualitative chemical analysis in the wet way; by this means were found silica, alu- mina, and manganese, lime and magnesia. The quantitative analysis gave these results :— Silica . . . 57.92 per ct. contains oxygen 27.91 Alumina and) 239, == manganese } men Sa. TO 89+ a : 3.42 Macnesia,. . 26.238 “ Ps : 10.49 >} = 14.45 Sopa oa... . 21) be Ue 0.54 ) 100.62 The alumina and manganese amounting to 2.39 per cent. are con- sidered as an impurity, and for this reason they are excluded from the consideration of the ratio. The oxygen ratio of the bases and the silica is as 14.45: 27.91 —1: 1.9, or adopting 2 for the latter will give the general expression (R)i,S, in which (R) stands for the monoxyds (Ca, Mg,Na). The new mineral species hexagonite is formulated thus: (Ga, Mg, Na) Si,. As this described bisilicate is anhydrous, and is crystallized in hexagonal form, it consequently belongs to the beryl group, of which it will be the third species. On Opuntia Rafinesquii and O. vulgaris.—Mr. MARTINDALE remarked that the large natural order of plants, the Cactacee, comprises about 800 species chiefly natives of tropical countries, and the western part of the United States, where many grow to an immense size. The only representative of this large order in the northern United States, east of the Mississippi, is the genus Opuntia. The only species of that genus described in the older works on the flora of that section, is the so-called O. vulgaris, “from Massachusetts, southward, mostly near the coast.” In the new edition of Gray’s Manual, the O. Missouriensis, a western species having dry prickly fruit, is admitted as occurring in Wis- 162 PROCEEDINGS OF THE ACADEMY OF [1876. consin, and O. Rafinesquii, with smooth pulpy fruit, somewhat like the O. vulgaris, also in the western section from Wisconsin to Kentucky. Dr. George Engelmann, of St. Louis, in a recent ex- amination of the genus, after comparing specimens from Massa- chusetts, New York, Pennsylvania, and New Jersey, heretofore classed as O. vulgaris, determines them to be identical with O. Rafenesquii from the west. In a recent note from him he says, “I have specimens growing here from Massachusetts, New York, Pennsylvania, and New Jersey, and they are all O. Rafinesquii; the vulgaris I have only from the falls of the Potomac and South Carolina.” In June last Mr. Martindale collected near Haddonfield, N. J., some specimens of Opuntia in flower, which on examination, and comparison with the species as figured in the fourth volume of the Pacific Railroad Reports, he had determined to be the O. vulgaris. In the latter part of July he again examined the plant, then in full fruit, and his former conclusion was sustained. He also sent a fully developed specimen to Dr. Engelmann, who pronounced it to be the true O. vulgaris, which he had not before seen north of the falls of the Potomac, and asked if it is a real native in New Jersey. On that point he thought there could be no doubt, as the owner of the land, John Gill, informed him it had been there to his know- ledge at least twenty-five years ; and while it does not incline to spread any, shows no signs of disappearing. On comparing this plant with specimens growing near the coast, and which appears to be the O. Rafinesquii, the following cha- racters appear. The O. vulgaris has a pale green appearance, the flat joints obovate, with small ovate subulate leaves, stout and tapering from a broadish base, mostly less than one-fourth of an inch in length, and appressed to the joint, with a fascicle of min- utely barbed bristles, and occasionally a spine in their axils. The flowers are sulphur-yellow; the fruit smoothish, about an inch in length, and half an inch in thickness, somewhat ventricose, or largest just above the middle, and tapering to the base, with a depression at the top where the flower had fallen off, from one- eighth to one-quarter of an inch in depth. The O. Rajinesquii has rather larger flowers, occasionally with a reddish centre; more numerous petals; the fruit fully one and a half inches in length, with an elongated tapering base; the depression in the top of the specimens examined is rather shallower than in the vulgaris ; the older joints have a darker green appearance, the leaves more slen- der, longer, from one- quarter to three-eighths of an inch in length, and spreading, and more frequently with the lar ge spine, particu- larly about the top of the joint. He had examined specimens from Woodbury, New Jersey, about twelve miles from the Haddonfield locality, which are O. Ra/jine- squii, and which have fusiform tubers on the extremities of the roots, similar in this respect to a western form of Ra/fi Sinesquit de- scribed in the Pacific Railroad Reports as O. fusiformis. He a EE —————— 1876.] NATURAL SCIENCES OF PHILADELPHIA. 163 had not been able to find tubers on the vulgaris, and the published description of that species made no mention of any. There is growing in the Meehan nurseries, near Germantown, Pa., a specimen of O. Rafinesquii from New Jersey, which is identical with one from Illinois, also a specimen of O. vulgaris, from Harper’s Ferry, Virginia, which is identical with the one collected near Haddonfield, N. J. These two species are some- what closely allied; yet the form and position of the leaves are manifestly different, and being early deciduous is possibly the cause of their being so long confounded. Certain it is, if the two species as described are distinct, we have both of them in New Jersey. Supernumerary Anterior Extremity in a Domestic Cow.—Dr. ALLEN exhibited a drawing of a malformation somewhat similar to that recorded in the Proceedings of July 25. In this instance, however, the digits were reduced to two. These were of unequal size and one only was ter- minal. The remaining digit was appended to the side of the metacarpus, but was not articulated with it. It was indeed a dwarfed digit held in position to the metacarpus by fibrous tissue and integument. When at rest it lay nearly parallel to the main digit. Each digit possessed a well-developed hoof-like covering, the larger mass being curved and compressed from side to ‘side, while the smaller one was styliform. Above the smaller digit was a small conical append- age, which may be considered a localized hypertrophy in the normal position of the ‘cleet.” Avaust 22. The President, Dr. RuscHENBERGER, in the chair. Twenty members present. AvautsT 29. The President, Dr. RuscHENBERGER, in the chair. Twelve members present. A paper entitled “‘ Note on the Discovery of Representatives of Two Orders of Fossils new to the Cretaceous Formation of North America,” by Wm. M. Gabb, was presented for publication. On the Coal and Iron Resources of Alabama.—Mr. WILLIAM GEsNER remarked that a number of applied and interesting 164 - PROCEEDINGS OF THE ACADEMY OF [1876. scientific facts had developed themselves in connection with the construction of geological sections in miniature of the Warrior and Cahaba Coal Measures in Alabama for exhibition at the Centennial. The frequent inquiry for information concerning them had induced him to believe that a description of these measures would prove interesting to the Academy of Natural Sciences. The three coal fields of Alabama, comprising an area exceeding seven thousand square miles, and separated by narrow silurian valleys, are just now being brought into prominent notice by the superior character of the coals and coke they afford, and the economy incidental to the manufacture of iron by their means. The valleys which separate these fields being stored with inex- haustible’ supplies of the best grades of hematite and brown ores, even to that variety best adapted to the manufacture of ferro- manganese, it seems surprising that both of these resources should have been allowed to lie dormant for such a length of time, while others of less extent, richness, and economy of working have been given their fullest development. It is now ascertained that the coal measures of the Warrior and Cahaba coal fields consist severally of 172 and 173 strata, embracing respectively forty-six and fifty-one coal-seams of all dimensions, from one inch up to six feet six inches in thickness, constituting a grand aggregate of one hundred and eighty-eight feet of bituminous coal. In the Warrior field there are many localities where the beds of coal lie horizontally, while in the Cahaba they are more fre- quently inclined; but all of those being worked in either are reached by slope or tunnel. Two beds of black band characterize the Warrior measures, one of them showing a richness of 43 per cent. metallic iron; clay iron-stone is abundant, and is found in all of the coal fields in Alabama. In one instance it constitutes the roof of a twenty- eight-inch bed of coal in the Warrior measures. The fossil fauna and fiora of these beds are found to be similar. Immediately beneath the mountain limestone of the carboniferous formation in the upper silurian, a bed of fossiliferous hematite occurs as one of its members. It extends in a northeastern direction, a distance exceeding 120 miles, and into the State of Tennessee, where it may be seen outcropping, interstratified with ferruginous limestone seven feet thick, under Mitchell’s Point, Walden’s Ridge. In Jefferson County, Alabama, its thickness is found to be twenty-eight feet, gradually becoming thinner toward its north- eastern prolongation. Wherever it outcrops on the top, from the sides, and in the valleys of Red Mountain, it is noted for affording the most fertile soils. It is conceded by all who see and examine this immense bed ¢ 1876.] NATURAL SCIENCES OF PHILADELPHIA. . 165 of ore, that it is to become the great base from whence in the future our principal supplies of iron will be produced. In the neighborhood of from two to three miles east and west of this ore bed lie the coal fields before mentioned. For its entire extent through the State, and immediately under it, lie the lime- stones of the silurian formation, among which are many of the purest and those best adapted for fluxing iron from its ores. Geologically, in descending order, next occur the immense beds of brown ore, comprising the varieties manganiferous and fibrous limonite, mamillary and crystallized hematite, belonging to Tal- ladega, Coosa, Cahaba, Roop’s and Murphy’s valleys, from which ‘heretofore nearly all of the Alabama iron has been produced— charcoal being used for fuel. At the present time, by a practical application of all of these advantages, great progress has been made by the Eureka Com- pany, under the able superintendence of Mr. James Thomas. After remodelling the plant of the former Red Mountain Iron and Coal Company at Oxmoor Station, on the South and North Alabama R. R., he has put in hot blast one furnace, on coke pro- duced on the spot by ovens, with attached combustion chambers of his own devising. The ore charges are made to consist of the mixture—three-quarters fossiliferous hematite and one-quarter brown ore, which is yielding from the furnace 56 per cent. good pig metal, costing under twelve dollars per ton in its manufacture. In view of these facts it becomes evident that Alabama will soon attain pre-eminence in the production of iron; and, as steel super- sedes its use for railroad and all other mechanical appliances (our next great stride in the march of civilization), she must become most populous and prosperous, for her climate is equable and her soils rank among the most fertile. Dr. 8. H. Linn, of St. Petersburg, Prof. Paul Groth, of Stras- burg, and Dr. James Hector, of New Zealand, were elected corre- spondents. The following papers were ordered to be published :— + 166 . PROCEEDINGS OF THE ACADEMY OF [1876. THE ROCKS KNOWN AS MEXICAN ONYX. BY MARIANO BARCENA. I have the honor to present before this Academy a report upon the calcareous rocks of Mexico, which so deservingly are occupy- ing the attention of the public in the present International Exhi- bition. These rocks are known in Mexico by the names of “ Tecalli,” ** Mexican Onyx,’ and “ Mexican Marble.” The first of these names refers to the place where they are found, as the principal beds are located in the neighborhood of the town of Tecalli, in the State of Puebla. The word Tecalli is a compound one, and, in my judg- ment, is derived from two Aztec words: Tefl (mountain) and Calli (house), the meaning in this case being “ House of the Mountain.” The origin of the word might be supposed as well to be Teocalle (God’s Mansion), name given by the Indians to their temples. The names Onyx and Mexican Marble are due: the first, to the fact that, like the true onyx, the Mexican rock shows stains and parallel stripes; and the second, to their chemical composi- tion, which, in point of fact, is the same as that of the common marble. I have read in some of the latest European journals that Mr. D’Amour informed the Academy of Sciences of Paris, that the Mexican onyx was nothing but a calcareous alabaster. This same opinion was expressed by myself, more than two years ago, in the ‘* Mexican Society of Natural History.” It was published in the first number of the third volume of “La Naturaleza,” and I have been most happy to learn that the classification of that celebrated chemist agrees with mine. The rocks of Tecalli offer a great many varieties in their dif ferent grades of transparency, in the diversity of their colors, and in their physical properties. In order to make a close examina- tion of these rocks, I selected a white specimen, as I considered this to be the purer variety. The characteristics were as follows:— Irregular form. H = 4.90 (Breithaupt’s scale), G@—=2.90. Lus- tre vitreous—resinous. Color white, slightly tinged with green. Transparent in thin slices, and translucent in pieces of some thick- ness. Fracture splitting in the oblique section and fibrous, with a somewhat silky appearance in the vertical section. Streak white. 1876.] NATURAL SCIENCES OF PHILADELPHIA. 167 B. B. infusible, becoming opaque and with a light reddish color. In two analyses made I found the following composition :— Lime ‘ : ; ° : c ; . 99.00 Magnesia § : : 5 . : : = le eo Water and oxide of iron and manganese : Pn O10 Carbonic acid . : : : : : : . 42.40 Sulphuric acid. : 5 : 5 : : 5 alsa) 100.00 This composition shows that the rocks are essentially formed by carbonate of lime, and that the other substances may be con- sidered as accidentally mixed, because of their existing in dif- ferent proportions in the red, green, and yellow colors, as ob- served in the block. The small proportion of sulphuric acid discovered was probably in combination with the lime, as the quantity of this base ex- ceeded that which is required for combination with 42.40 of car- bonie acid; for this proportion of the acid are required 93.96 of lime. The excess of this base is 1.04, which would take 1.48 of sulphuric acid to form the hydrous sulphate (Anhydrite), being this amount of acid very similar to that found in the analysis. The oxides of iron and manganese, as well as the selenite, were mixed only with the carbonate of lime, which alone formed the bulk of the analyzed specimen. Prof. W. J. Ward lately presented to the Royal School of Mines in London a qualitative analysis of the same rock, having found exactly the same substances that I did myself on my examina- tions; but, I understand he selected one of the most colored varieties, as he found the iron in large proportions, and partly combined with the carbonic acid. He found the sulphuric acid, and also the oxides of iron and manganese, which latter he con- siders to be the only coloring matters. The capricious variegation of colors produced by those oxides, as well as the different grades of transparency and opacity in the polished slabs, give them that magnificent aspect which consti- tutes their indescribable beauty. When the blocks are cut in the direction of their planes of stratification, the shades appear in the form of clouds, flames, and stains of all dimensions. The clouds at times appear simulating somewhat the form of cumuli, or that of cirrus. The combination of those extreme grades, and 168 PROCEEDINGS OF THE ACADEMY OF [1876. of other intermediaries, added to the difference of opacity in some portions of the same slab, produce the most beautiful and inimit- able effects. In some we find the figures of mountains, ruins, and several other objects which look very much like landscape sketches. The colors vary from the dark-green to the apple-green, and from the intense red to the lightest rose tint. There are also varieties of yellow and blue which intermingle with the former. The me- tallic oxides which produce this coloration are found in greater proportions towards the borders of the veins of some of the rocks, and through which was effected the infiltration of the waters which contained the coloring materials. The rocks of Tecalli admit of a higher polish than the common marble. This can be seen in the many specimens now on exhibi- tion in the Mexican Department of the Main Building, and which, by their brilliant surfaces, colors, and transparency, admirably imitate the agates and the true onyx. By the foregoing peculiarities we find that ‘the Mexican marble belongs to the group of the calcite, and from its physical proper- ties to the variety designated as Travertine, under which head is classified the calcareous alabaster or onyxite. The good reception of these rocks in the markets, the extent of their deposit, unequalled perhaps in this respect, give them sufficient interest to deserve the names of Onyx and Mexican Marble, a name which probably will be always adopted in com- mercial language. The beds of the rock are situated in the neigh- borhood of the town of Tecalli in the State of Puebla. In a report which the Mexican Engineer, Mr. Patricio Murphy, made two years ago, he mentioned three principal deposits which bear the names of “La Pedrera,” “Tlahualco,” and “Aratleta.” The most important of these is the first named, located at twenty miles from the city of Puebla. According to Mr. Murphy, the mountain where the Mexican marble is found is alternately formed of beds of this rock, argilleous calcareous rocks, and marls and sands. The quantity in which those rocks are found is very ex- tensive, and warrants the expectation of an almost unlimited sup- ply. It is to be hoped that the use of these rocks will be soon extended, because, as they are far more beautiful than marble, and resemble so much the true onyx and agate, they are appropriate for the richest and most splendid decorations. 1876. ] NATURAL SCIENCES OF PHILADELPHIA. 169 ON PHOTOGRAPHS OF TASMANIANS AT THE CENTENNIAL EXPOSITION. BY CHARLES PICKERING, M.D. During my visit to Australia, in or about 1840, every one at Sydney spoke of the Australians as a distinct people from the natives of Tasmania or Van Diemen’s Land; the Australians, it was said, are “straight-haired blacks,” and the Tasmanians are ““woolly-haired blacks ;” but, not meeting with a Tasmanian, I did not feel authorized to make a distinction on my Map. Recently, at the Centennial Exposition, photographs of Tas- manians, and especially of the last male survivor, have enabled me to form an opinion, and refer the originals to the Papuan Race or large New Guinea negro. Among the varieties of man, the Papuan is remarkable for his harsh skin; and it is on record in books of travel, that the skin of Tasmanians is not soft to the touch like that of Australians ; also, that the Tasmanians fill their hair with mud (a character- istic trait of Papuans). New Zealand was peopled by Polynesians from the tropics. The emigrants, leaving behind all tropical plants, yet carried along old familiar names, some of which they transferred to the productions of the colder climate; one instance I will quote from memory :— The Barringtonia of the tropics bears a large husky fruit, which is used by the natives to float their seines or nets; the Polynesian name of the tropical tree has been transferred in New Zealand to a tree of the pine kind; its wood, however, is very light, and made by the New Zealanders into seine-floats. Tasmania in a similar manner was peopled by Papuans from the tropics, by emigrants probably acquainted with agriculture, but who did not bring esculents suitable for cultivation in the cold climate of the new country. Two other important corrections have come to light since the publication of my Map :— One is the discovery by Schweinfurth, in Central Africa, of a country under the equator inhabited by the Hottentot race, iden- tified by him with the pigmy nation that, according to Homer, 12 170 PROCEEDINGS OF THE ACADEMY OF [1876. suffered from attacks by cranes; the true location even pointed out by Herodotus. The third correction is derived from photographs, showing that the Aino of Northern Japan, Yeddo, Saghalien, and the neighbor- ing islands belong to the White or Caucasian Race. The most eastern island bears the name of “ Yurup,” as though given by a land party journeying east in search of Europe, precisely as Columbus by sea journeyed west in search of Asia. The geo- graphical position of the Aino, and their maritime expeditions to the Aleutian Islands, accord with Mexican and South American tradition of an ancient intercourse with long-bearded white men from the west (see Humboldt). 1876.] NATURAL SCIENCES OF PHILADELPHIA. 171 SEPTEMBER 5. The President, Dr. RuscHENBERGER, in the chair. Twenty-nine members present. A paper entitled ‘“‘ Hexagonite, Goldsmith, a variety of Tremo- lite,” by Geo. A. Koenig, was presented for publication. Morphology of the Pear.—Dr. McGrartu placed on the table abnormal fruit of the pear, in appearance resembling huge acorns. Mr. THoMAS MEEHAN took occasion to note the recent advances of morphological knowledge as explaining such phenomena. Even recent text-books taught that a fruit was but modified leaves. The exact truth is that a fruit is leaves and branch. When a bud is being formed in the apple, pear, or similar fruits, it may finally be either a flower-bud or a bud producing a new branch. Varying phases of nutrition decide this question. Exactly the nature of this variation we do not know; but we do know that the growth- force in the bud is arrested by some law of nutrition, and, instead of an elongated branch, what would be its series of spirals are drawn together closely, and the whole modified and made to forma flower. Thus, in the pear, it takes five buds to form one full cycle on a pear branch. When growth is arrested to form a flower this first cycle is transformed into a five-lobed calyx, and generally this becomes much enlarged and fleshy, and covers all the other cycles of buds which go to make up the inner layer of flesh terminating in the petals, carpels or core, and so on. Now, in the case before the Academy, the arresting force was imperfect. It had succeeded in forming the outer or calycine verticillate series of buds into a fleshy matter, giving what here might be called the cup of the * acorn,” when the accelerating or branch-producing force gained a temporary advantage and pushed on, forming the acorn-like cen- tre, but only to be soon again arrested. This abnormal pear was indeed nothing more than an effort of the tree to produce a branch after a fruit had been decided on; a struggle which was finally de- cided in favor of the fruit, if we might speak metaphorically in explaining the case. Natural Hybrids.—Mr. MEEHAN said that modern naturalists were mostly convinced that new forms were evolved from old ones, but how much the new form had been influenced in its creation by a thus far mysterious law of change inherent in the old form, im- pelling it to bring forth the new one when nature’s own good time had come; or how far external influences acted in bringing about these changes, was still a matter for science to solve. He thought 172 PROCEEDINGS OF THE ACADEMY OF [1876. the innate power of change was much greater than many of our best naturalists were willing to grant. In illustration, he held a letter from a leading.botanist inclosing what he contended was a hybrid between Verbena stricta and V. urticefolia. Mr. M. de- scribed the structure of Verbena. The tube of the corolla was half an inch in length, and narrow, and only insects of a large size and long trunks could reach to the bottom for honey. The anthers were curved just above the stigma, and both organs ma- tured near together. Above all, and completely closing the en- trance to the tube, was a dense mass of hair. Supposing, on prevailing theories of cross fertilization by insect agency, that an insect should visit the verbena flower for honey, and the trunk get covered with pollen, the rather large trunk would get stripped clean of its pollen in wiping against the mass of hair on with- drawal; or, if a little did remain in spite of the brushing, would most likely get thoroughly cleaned on the visit to the next flower. Hybridization by this agency, and there appeared to be no other in this case in nature, was well nigh impossible. He had always regarded the dangers of hybridization, and consequent confusion of species, as an @ priori argument against the prevalent theories of cross fertilization by insect agency being any part of a great plan for the development of the races of plants. At any rate in Verbena, the mass of hair in the throat could not by any interpre- tation be regarded as an arrangement in the aid of cross breeding. It was an obstruction, and, in his opinion, an insurmountable one. The striking form of Verbena between V. stricta and V. urtice- folia, sent to him by his distinguished correspondent, he should regard as no hybrid, but as a form evolved in the due course of an inherent guidance from the former species, a power continu- ously at work, and which “external circumstances” tended as often to repress as to aid. SEPTEMBER 12. The President, Dr. RUSCHENBERGER, in the chair. Thirty-two members present. A paper entitled “ On the Lingual Dentition, Jaw and Genitalia of Carelia, Onchidella, and other Pulmonata,” by Wm.G. Binney, was presented for publication. Welwitschia mirabilis—Mr. THoMAS MEEHAN called attention to a specimen of Welwitschia mirabilis, exhibited in the Portu- guese African section of the Centennial Exhibition, as well worthy of the examination of members of the Academy. The trunk in this specimen is vase form, and about two feet across, and stands about two feet from the ground. 1876. ] NATURAL SCIENCES OF PHILADELPHIA. 173 Nocturnal flowering of Mentzelia ornata.—Mr.'THoMAS MEEHAN said this old species had only just found its way into cultivation, and afforded an opportunity to note its distinctive habits. His nephew, Mr. Joseph T. Meehan, had kindly watched for him, and found that the same flower opened on four successive nights; on the fifth it made a weak attempt to open, but soon faded away. The flower commenced to open soon after sundown (6 P.M.), very rapidly the first day, and commenced closing again in about three hours, becoming entirely closed by midnight. Thesecond night they opened more slowly, and commenced to close earlier, so that the final closing was again about midnight. The last two nights the motion was slower, but occupied about the same time on the whole. Mr. Redfield had noted, Mr. M. observed, that some Mentzelias opened by day and some by night, but he knew of no attempts to time the opening exactly. In order to tell whether these openings and closings by night had anything to do with fertilization by insect agency, he had in- closed one flower in a gauze bag, and found it to “have a seed ves- sel apparently as perfectly developed as the rest. The seed might possibly be imperfect when the seed vessel was mature, but this was hardly likely, as the instances where plants developed their capsules in the absence of fertilization were uncommon. » SEPTEMBER 19. The President, Dr. RuscHENBERGER, in the chair. Twenty-eight members present. Notes on the Coniferx.—Dr. ENGELMANN, of St. Louis, spoke about Abies Fraseri, the very local species of the highest moun- tains of North Carolina, which he had just visited, together with several botanical friends, members of this society. This is the tree which caused these mountains to be designated as the Black Mountains; giving their summits that sombre hue for which they are known. They seem to grow nowhere but on these mountains, and only on those that reach up to or above 6000 feet altitude. The northern localities claimed for the species, rest on confusion with forms of Abies balsamea, the common northern balsam, of which our tree may be claimed to be the southern representative. A. balsamea does not seem to extend southward further than the Virginian mountain region; and it would be interesting to as- certain how near both species approach each other. Besides the well-known characters of the cones and their cusps, excellent distinctions are found in the structure of the leaves of both species. It may not be generally known, though it is a fact to which, since several years, some European botanists have called attention, that the anatomical structure of the leaves of these 174 PROCEEDINGS OF THE ACADEMY OF [1876. species, as well as of conifers in general, are extremely various, and that this structure well characterizes many species, and is one of the safest means to arrange them in natural groups. Abies Fraseri and balsamea are so nearly allied, that without fruit they are constantly confounded; but the structure of the leaves will always distinguish them so well, that a single leaf, or even a frag- ment of one, will invariably solve all difficulty. The leaves of Abies have under the epidermis, and between it and the cells of the parenchyma, which are full of chlorophyll, an arrangement of cells of thick walls, elongate form, and destitute of chlorophyll, analogous to bast cells, which have been called hypodermic cells; we find them in all species of Abies on the edges and on the keel, where they strengthen the leaf; but their distribution under the epidermis of the upper side of the leaf is very different in differ- ent species—they may be wanting there altogether or may be differently grouped, or may extend over the whole upper surface. Now in all forms of A. balsamea they are there almost entirely absent, even in those of the highest New England mountains; while Fraseri exhibits under the microscope a continuous hypodermic stratun of them. These differences may seem minute and perhaps unimportant, but they remind us of similar structural differences in the higher or vascular cryptogams, in which on differences in variation and cell-structure much stress is laid, and justly so; while in higher developed plants the anatomical structure of the leaves is much more uniform. This leads to another and much more important question, the position of the conifers in the vegetable world. Conifers are usually placed at the bottom of the dicotyledonous plants, and Cycadez with the highest monocotyledons, near the Palms. Now, Robert Brown, more than fifty years ago, has shown that both differ from all other flowering plants, by bearing on open leaf-organs naked ovules; nor are their seeds inclosed in regular fruits, a peculiarity which has procured for them the name of gymnosperms. It must be admitted, however, that to this day — the question, though diligently ventilated, is not entirely settled, or, to express it more correctly, gymnospermy is not yet acknow- ledged by every botanist. Calling to our aid the investigations in another field of natural science, “Paleontology teaches us that the lowest forms appear in the oldest epochs of our globe’s history, and that only in the later periods the higher developed forms are found. Now, the fact is, that ages and ages before other flowering plants, angio- spermous plants are found, and almost coétaneous with the earliest cryptogamic land plants—in the Carboniferous and even in the Devonian periods conifers already made their appearance. Asin the development of the mammals, the prototypes of many of the orders are found anterior in their geological age, as well as 1876.] NATURAL SCIENCES OF PHILADELPHIA. 175 lower in grade of development; so the conifers, with their exoge- nous trunk and their often numerous cotyledons, will have to be considered the prototypes of the exogens, while the cycadez with endogenous trunk, and unequal or almost single cotyledons, are those of the endogens. Both together, comprised under the gene- ral term of gymnosperms, will eventually be acknowledged as a link intermediate between the vascular cryptogams and the flower- ing plants. Naturalization of Plants. —Mr. Martindale spoke of the various agencies by which foreign plants have been introduced into the country, also of the manner of their distribution, instan- cing the case of Rudbeckia hirta, L., now very abundant in the eastern section, having been introduced in grass seed from the west. He also mentioned anumber of plants that are common on the coast of Virginia and southward, which have been collected in the lower counties of New Jersey, evidently from seed carried by birds in their migrations coastwise. Within a few years large quantities of ballast have been de- posited in the neighborhood of Philadelphia, on which have been collected a large number of plants not found elsewhere in the vicinity. Some of the species occur every year, and in some in- stances spread into the waste grounds; others have not appeared the second season, although their seeds became fully matured. He stated that this subject of introduction and establishment of foreign plants was becoming of more and more importance, as the geographical distribution of species was being investigated, and where reasons could be assigned, as to the manner of introduction, they give it an additional interest. He had, within a few days, collected, near the mouth of Wissahickon Creek, a plant which had been determined to be Leonurus glaucescens. ee > f ! ; : Aa » Ay ‘Gee bay he ir, fol ip ine " PrAN.S.Phi41876. & Pheto-Lith. by J. CARBUTT, 624 N. 24th St, Phila W.G.B. del. Binney on Dentition &c.of Pulmonata. 1876. ] NATURAL SCIENCES OF PHILADELPHIA. 183 ON THE LINGUAL DENTITION, JAW, AND GENITALIA OF CARELIA, ONCHIDELLA, AND OTHER PULMONATA. BY W. G. BINNEY. Macrocyclis sportella, Gld. Oregon. Mr. O. B. Johnson. Jaw and lingual membrane as usual in the genus. (See Proc. Acad. Nat. Sci. Phila., 1875.) Teeth 22—1—22. The 6th tooth is the largest. The peculiar side spur noticed on the inner laterals of Macr. Vancouverensis is present in this species also. The central tooth is of same type as that of the last-named species, to which sportella is most nearly allied by its shell. Pl. VI., fig. aa. Zonites inornatus, Say. Pl. VL., fig. c, represents the dentition of this species, showing both planes of the cusps and cutting points. The dotted lines show the lower plane, 7.e., the part which rests on the base of attachment. This is what I have hitherto shown in my plates. From this lower plane the cusp and cutting point bulge out later- ally as they round upwards. The most outward margin is the other plane shown, giving the widest extension of the cutting point. Zonites fuliginosus, Griff. On pl. VL, fig. D, is a lateral tooth of this species showing the two planes described under Z. inornatus. Zonites(?) Bermudensis, Pfr. Bermuda. Mr. J. Matthew Jones to Mr. Bland. The specimens were living, enabling me to study advantageously the external characters of the animal. There is a distinct locomo- tive disk to the foot, but no caudal mucus pore, and no longitu- dinal furrows above the margin of the foot, so that the species cannot be placed in Zonites, which has the last two characters. The external orifice of generation is quite under the mantle, not behind the right eye-peduncle. The jaw and dentition I have already described. (Ann. Lyc. Nat. Hist. of N. Y., X., 221.) The genitalia present the following peculiarities. The genital bladder is small, globular, on a long duct. The penis sac is long, 184 PROCEEDINGS OF THE ACADEMY OF [1876. tapering to its apex, where it receives the vas deferens and the retractor muscle. There is a long, stout, dart sac, containing a delicate, arrow-like dart of the same form as figured by Leidy for Zonites ligerus (Terr. Moll., U.S. L). The absence of the caudal mucuspore removes the species from Zonites, nor can it be placed in any recognized genus. Limax Hewstoni, J. G. Coop. California. Dr. Cooper. PLVL., fig. F, represents the genitalia of this species, which I have recently drawn from specimens kindly furnished by Dr. Cooper. For description, see Ann. Lyc. Nat. Hist. of N. Y., XI., p. 22. Limax campestris, Binney, var. occidentalis. California. Dr. J. G. Cooper. (See Proc. Acad. Nat. Sci. of Phila., 1872, 146, pl. III., fig. c.) In outward appearance, in genitalia and in jaw, this form can- not be distinguished from the eastern form. Its lingual membrane has 85—1—35 teeth, 13 being laterals. On some of both the inner and outer marginals I can detect the side spur which in the eastern form I have only observed in the outer marginals. In this par- ticular, occidentalis is more nearly allied to LZ. montanus, Inger- soll,! but when the value of differences in such slight details becomes known, I believe all three species will be found identical. Pl. VL., fig. x, b, gives two inner marginals. Onchidella borealis, Dall. Alaska. Dr. W. H. Dall. In three specimens examined I found a jaw (pl. VL., fig. BB), low, wide, slightly arcuate, ends scarcely attenuated, blunt, anterior surface ribless. Lingual membrane (pl. VL., fig. EE) long and wide. Teeth about 61—1—61, arranged strongly en chevron. The central tooth is large, longer than wide, truncated above, expanded below its middle, and ineurved at the basal margin. The reflection is large, tricuspid, each cusp bearing a decided cutting point. The side teeth have a long, narrow base of attachment, a small portion of its upper portion thrown outwards, the balance curving inwards, giving an irregular bow-shape to the whole base of attachment— 1 This is the species indicated by meas L. Ingersolli, in Proc. Acad. Nat. | Sci. Phila., 1875, 176. 1876.] NATURAL SCIENCES OF PHILADELPHIA. 185 whose upper and lower edges are abruptly truncated. The reflec- tion is near the base, and consists of a very small, inner cusp, bearing a small conical cutting point, and another, outer, larger cusp, bearing an extraordinarily developed, wide, expanding, bluntly truncated cutting point. As the teeth pass outwards towards the outer margin of the membrane, they at first increase and then decrease in size, but retain the same shape quite to the edge. An outer lateral tooth is figured in c, an inner lateral in b. Fig. £, of plate VI., gives a view of the lower surface of the animal and also one of the head, showing the short, stout eye peduncles and curious oral appendages. The Onchidiide are described as agnathous, but I am confident of having observed the jaw figured. Ariolimax Columbianus, Gld. From Mr. O. B. Johnson, of Forest Grove, Oregon, I have received specimens of this species. On examining the genitalia, J find them to agree perfectly with what I have already figured in Proc. Acad. Nat. Sci. of Phila., 1874, pl. XI., fig. c. I am con- vinced, therefore, of the identity of the specimens there figured, of which some doubt then existed. Binneya notabilis, W. G. B. Sta. Barbara Island, California, Mr. Henry Hemphill. Pl. VI., fig. v, represents almost the whole of the genital system. The penis sac is long, narrow, tapering at its apex, where it receives the vas deferens: the retractor muscle is inserted below the entrance of the latter. The genital bladder is oval, on a long, narrow duct. There is a small, saclike, accessory organ, probably a dart sac. Carelia bicolor, Jay. Dr. W. H. Dall. Through the kindness of Dr. Dall, I have been able to examine this species, formerly known as Achatina bicolor. Thus I have increased the list of subgenera or groups of Achatinella of Gulick’s arrangement, whose jaw and lingual dentition is known, leaving still to be examined Newcombia only of the same arrangement. It will be seen from my description, that while Carelia (or at least this species) differs utterly in jaw and dentition from Gulick’s Achatinella s.s., Bulimella, Apex, Partulina, Auriculella, it agrees 13 186 PROCEEDINGS OF THE ACADEMY OF [1876. in dentition with his Laminella, Amastra, Leptachatina, but differs in having a costate jaw. Carelia, therefore, must stand distinct from any of the other groups of Achatinella. My description and figures should be studied in connection with my former papers on Achatinella in Annals of Lyceum of Natural History of New York, Vol. X., p. 331, pl. xv., and Vol. XI., p. 190, pl. xiv., in the preparation of which I was assisted by Mr. Bland. The animal is obtuse before, pointed behind. The mantle appears subcentral in the single individual examined, which is preserved in, alcohol. The orifice of respiration and anal orifice are as usual in the heliciform genera. The genital orifice as far as I can judge is somewhat removed from behind the right eye peduncle, rather under the mantle edge, but it is difficult to say what is its position in the living animal. There is no sign of a distinct locomotive disk or of a caudal mucus pore. The jaw (pl. VI., fig. G) is low, slightly arcuate, with but little attenuated, blunt ends: anterior surface with ten stout ribs, den- ticulating either margin. Lingual membrane (pl. VI., fig. cc) long and narrow. Teeth 37—1—37 of same type as I have formerly described (1. c.) for species of Laminella, Amastra, and Leptachatina, the marginals being irregularly and obliquely pectinate as in Achlla. obesa (1. c.). The digestive system, as would be anticipated from the shape of the shell, is characterized by the extreme length of the ceso- phagus. The salivary ducts are comparatively short. The sali- vary glands are small and ina globular mass around the cesophagus. The buccal mass with its pouch of the lingual membrane is as usual: its retractor muscle is attached to the retractor of the head. The genitalia are here figured (pl. VL, fig. 0). It will be seen that there is in the specimen examined a decided external swelling of both male and female (the former, female (/. 0.), large and horn- shaped, the latter, male (m.o.), small and globular) organs; owing, perhaps, to the sudden immersion of the individuals in alcohol. The gravid state of the uterus precludes the possibility of these swellings being preparatory to accouplement This condition of the external orifices accounts for the wide separation of the genital bladder from the vagina, and of the accessory organ (pr.) from the penissac. The figure is of life size, all the organs having been accurately measured. The testicle (¢.) is composed of short coca grouped in a globular mass. The epididymis (ep.) is short and 1876.] NATURAL SCIENCES OF PHILADELPHIA. 187 greatly convoluted. The ovary (0.) is obtusely tongue-shaped and lobate. The oviduct is sacciform and contained two well-developed embryonic shells, showing the species to be viviparous, as well as four masses, probably consisting of less mature embryos. The genital bladder is small, suboval, on a short duct. The penis sac (p.s.) is long, cylindrical, with a developed, extended median con- striction. The vas deferens (v.d.) enters the apex of the penis sac: the retractor muscle (7. p.) of the penis is inserted just above the entrance. There is a long, narrow, accessory organ (pr.) with an extended median constriction to the penis sac, perhaps a dart sac or prostate gland. There is a stout retractor muscle (r.) to the external horn-shaped swelling of the male orifice. Microphysa incrustata, Poey. Corpus Christi, Texas. A dried specimen collected over thirty years ago by Mr. Bartlett. Jaw low, wide, slightly arcuate, ends blunt, but little attenuated: anterior surface with numerous, crowded ribs, bluntly denticu- lating the lower margin. Lingual membrane (pl. VI., fig. ) with 13—1—13 teeth, 5 per fect laterals. The teeth are of same type as in other species of Microphysa, as Ingersolli (Ann. Lye. of N. H. of N. Y., XI., pl. Xviil., fig. c). The jaw also resembles that of Microphysa rather than Patula, to which I formerly referred the species. Von Mar- tens places it in Microphysa. Fig. b shows marginal teeth. Triodopsis inflecta, Say. Indiana. Mr. F. Stein. Genitalia as in 7. Rugeli. See Ann. Lyc. Nat. Hist. of N. Y.,. ME, pl. xvi., fic. 18. Turricula tuberculosa, Conr. Palestine. A dried specimen in Mr. Bland’s collection. Lingual membrane (pl. VLI., fig. 5) long and narrow. Teeth 28— 1—28. Centrals and laterals without decided. side cusps or cut- ting points, but the central cutting point has a decided lateral bulge. Marginals low, wide, with one inner, oblique, large bifid cutting point, and two outer smaller cutting points. A marginal is shown in /. Jaw with numerous, crowded, broad, flat ribs, denticulating either margin. 188 PROCEEDINGS OF THE ACADEMY OF [1876. Helix monodon, Rackett. Indiana. Mr. F. Stein. Genitalia (pl. VI., fig. q@) characterized especially by a very un- proportionally large penis sac, which is long, club-shaped, greatly enlarged above, where it receives the vas deferens and retractor muscle. The genital bladder is elongate-oval, small, on a short, delicate duct. The epididymis is convoluted throughout its length. Polygyra Postelliana, Bland. Charleston, S.C. Mr. W. G. Mazyck. Genitalia as in P. auriculata. (See Leidy in Binney’s Terr. Moll. U.S. I.) Jaw as usual in the genus: over 12 ribs. Lingual membrane (pl. VI., fig. z) asin P. Hazardi. (See Proc. Acad. Nat. Sci. Phila., 1875, pl. viii., fig. 5.) The change from laterals to marginals is very gradual, and formed without the splitting of the inner cutting point. There are 21—1—21 teeth with about 7 laterals. Extreme marginals are shown in b. Polygyra Dorfeuilleana, Lea. A dried specimen long preserved in my cabinet furnished the lingual membrane here described. Teeth (pl. VL, fig. vu) 20—1—20, with 9 laterals, the tenth tooth having its inner cutting point bifid. Base of attachment subequi- lateral of central and lateral teeth. All the teeth of same type asin P. auriculata. (See Ann. Lyc. of Nat. of N. Y., XI., pl. xviii., fig. E.) Polygyra avara, Say. Banks of St. John’s River, Florida. Mr. Chas. Dury. It is with peculiar satisfaction that I give these details, as it is | one of our rarest species. Jaw as usual in the genus, with over 12 ribs. (See Proc. Acad. Nat. Sci. Phila., 1875, p. 201.) Lingual membrane as usual in the genus (see same, p. 202). The change from laterals into marginals is shown in the 9th tooth, which is the first having a bifid inner cutting point. There are 17—1—17 teeth. , Pl. VI., fig. y. Caracolus sagemon, Beck. Gonave Island. Prof. Linden to Mr. Bland. On pl. B, fig. ac, I figure the dentition of the specimens described in full by Mr. Bland in Ann. Lye. Nat. Hist. of N. Y., XI, 197 (1875). eee 1876. ] NATURAL SCIENCES OF PHILADELPHIA. 189 Mesodon major, Binn. This species (or form of albolabris) was found by me near Aiken, 8. C., but still larger specimens, at Macon, Ga., in the City Ceme- tery, by Mr. H. S. Crooke. The form seems to inhabit a narrow strip of territory east of the mountains from Abbeville, S. C., to the Gulf of Mexico. The largest specimen I have ever seen is 48 mill. in its greater diameter. The jaw, lingual dentition, and genitalia agree with those of albolabris. Fig.1,of plate VI., represents the genital system of one individual examined, in which the ovary is very small, and the genital bladder unequally divided, both points differing from those of other individuals examined. This shows us we should allow some latitude of variation in the details of the genital system of any given species. Aglaja fidelis, Gray. Oregon. Mr. O. B. Johnson. On pl. VI., fig. p, I give a more satisfactory figure of the geni- talia of this species than formerly published by me. The organ x in the specimens recently examined was greatly developed. The organ is a dart sac, which contained a dart of the type described below under Arionta Mormonum. Arionta Mormonum, Pfr. Tulumne Co., California. Mr. A. W. Crawford. Pl. VLI., fig. 8, represents the genitalia. The general appearance is that of A. fidelis, as formerly described by me (see below), but there is an additional accessory organ (q.), of use unknown to me. The organ, 7, is a dart sac. The dart is short, stout, straight, swollen at its base, and with an enlarged acutely pointed apex (pl. VI., fig. kK). Upon the vagina, above the insertion of the penis sac, is a ridge-like process (s.) containing in three individuals examined one round, and one oblong calcareous nodule (pl. VI., fig.J). Isuspect the organ 14, noticed in fidelis (Proc. Acad. Nat. Sci. Phila., 1873, pl. I., fig. 5) corresponds with this process. Jaw as usual in Arionta: 7 ribs. Lingual membrane (pl. VI., fig. B) as usual in Arionta. Teeth 50—1—50, with 15 laterals, the 16th tooth having its inner cutting point bifid. Arionta sequoicola, J. G. Coop. Santa Cruz, California. Mr. H. Hemphill. The genital system (pl. VL., fig. R) is like that of Arionta Traski. 190 PROCEEDINGS OF THE ACADEMY OF [1876. (See-Ann. Liye: of Nat. Hist./of N. ¥.; XT, pl. Va, fiery.) ine accessory bulb upon the vaginal prostate is somewhat differently situated in this species. The extreme length of the genital system is eighty-seven millimetres. Jaw and lingual membrane already described. (See Proc. Acad. Nat. Sci. Phila., 1874, pl. XIV., fig. 5.) Arionta Californiensis, Lea. Monterey. Mr. H. Hemphill. Jaw already described. Lingual membrane with 53—1—53. Teeth as usual in the genus (see above). The side cusp and cutting point appears on the 9th tooth. The inner cutting point of the 25th is bifid, so that there are about 24 laterals (pl. VI., fig. w). The genitalia are as in A. Nickliniana already described. Arionta Dupetithouarsi, Desh. Monterey. Mr. H. Hemphill. Jaw as usual in the genus, with four, separated, stout ribs. Lingual membrane with 50—1—50 teeth. ‘here are no distinct side cusps or cutting points on the centrals or first laterals, though there is a lateral bulge on the large cutting point. The distinct side cusp and cutting point appears on the ninth tooth. There are about nineteen laterals, the twentieth tooth having its inner cutting point bifid. The marginals are as usual in the genus (pl. Vis ties 0): Genitalia as in A. Traski (l.c.). The penis sac is more slender and has no retractor muscle in the single individual examined by me. The oviduct is greatly convoluted. Glyptostoma Newberryanum, W. G. B. San Diego, Cal. Henry Hemphill. Genitalia (pl. VI., fig. H). a is a dart sac or prostate gland. Bulimulus Dormani, W. G. B. Port Orange, Florida. Mr. Chas. Dury. Jaw (pl. VI, fig. M, the central portion only) as usual in the genus, arcuate, thin, transparent, ends acuminated, anterior sur- face with about 54 plait-like ribs. The figure gives only a portion of the jaw. The upper median ribs are very oblique. Lingual membrane as in B. laticinctus, primularis, papyraceus, etc. Teeth 79—1—79. Pl. VI., fig. HH. This is the first species of 1876.] NATURAL SCIENCES OF PHILADELPHIA. 191 Bulimulus noticed within the United States having this peculiar type of dentition. Genitalia figured on pl. VI., fig. N. Penis sac very long and nar- row, ending in a flagellum: vas deferens entering at about the anterior fourth of its length. Genital bladder oval, on a long, narrow duct. No accessory organs. Bulimulus Edwardsi, Mor. Lake Titicaca. Prof. Alex. Agassiz. Jaw low, arcuate, ends rapidly acuminated, blunt: anterior sur- face with over ten distant ribs, some of the usual Helix type, others like the plait-like processes, common in Cylindrella, Bulimulus, Geotis, Amphibulima, ete. Lingual membrane (pl. VI., fig. pb) with 44—-1—44 teeth. Cen- trals of the usual Helicine type, tricuspid: laterals like centrals, unsymmetrical, and consequently bicuspid. The change to mar- ginals very gradual, and formed by the simple modification of the laterals, without any splitting of the inner cutting point. Succinea ovalis, Gould, not Say. Burlington, New Jersey. Teeth over 60—1—60. Fig. 6 represents extreme marginals (plo VI., fig: a). Jaw with smooth anterior surface and prominent median pro- jection to the cutting edge. EXPLANATION OF PLATE VI. Calcareous concretions of B. Jaw of Bulimulus Dormani, central portion. Fig. A. Lingual dentition of Succinea ovalis. Fig. B. te “ Arionta Mormonum. Fig. C. m - Zonites inornatus. hia.1). a ee “* fuliginosus. Fig. E. Onchidella borealis. Fig. F. Genitalia of Limax Hewstoni. Fig. G. Jaw of Carelia bicolor. Fig. H. Genitalia of Glyptostoma Newberryanum. mig.” I: . Mesodon major. Fig. J. Lingual dentition of Turricula tuberculosa. Fig. K. Dart of B. L. M. 192 PROCEEDINGS OF THE ACADEMY OF Fig. N. Genitalia of M. Fig. O. Bs Carelia bicolor. t. Testicle. ep. Epididymis. o. Ovary. ovid. Oviduct. g. b. Genital bladder. p. & Penis sac. r. p. Retractor penis. r. Retractor. pr. Prostate gland?. v.d. Vas deferens. m. 0. Male orifice. f.o. Female orifice. e. t. External tegument. Fig. P. Genitalia of Aglaja fidelis. Fig. Q. Ks Stenotrema monodon. Fig. R. ef Arionta sequoicola. Fig. 8. es: B. Fig. T. Lingual dentition of Microphysa incrustata. b. Marginals. Fig. U. Lingual dentition of Arionta Dupetithouarsi. Fig. V. Genitalia of Binneya notabilis. Fig. W. as Arionta Californiensis. Fig. X. 7 Limax occidentalis. b. Inner marginals. Fig. Y. Lingual dentition of Polygyra avara. Fig. Z Re ae of Postelliana. Wig. (AA: e. 3s Macrocyeclis sportella. Fig. BB. Jaw of E. Fig. CC. Lingual dentition of G. Fig. DD. aS Bulimulus Edwardsi. Fig. EE. c KE E. b. Inner marginals. ce. Outer marginals. Fig. FF. Lingual dentition of Polygyra Derfeuilleana. Fig. GG. = * Caracolus sagemon. Fig. HH. ¥ ee [1s76. 1876. ] NATURAL SCIENCES OF PHILADELPHIA. 193 OcTOBER 3. The President, Dr. RuscHENBERGER, in the chair. Thirty-six members present. A paper entitled ** On the Extrusion of the Seminal Products in Limpets, with some Remarks on the Phyllogeny of Docoglossa,” by W. H. Dall, was presented for publication. Bituminous Sediment of the Schuylkill River.—Prof. Lripy remarked that he had been recently invited by Dr. Josua Lindahl, Secretary of the Swedish Commission, who had at his command a small steamer, to make the experiment of dredging in the Schuyl- kill River. He had accepted the invitation in the expectation of finding abundance of the smaller aquatic animals, such as he had sparingly detected on stones near shore below low-water mark, just below Fairmount dam. The dredging was tried near the mouth of the Schuylkill, but no living thing whatever was drawn up, as the mud and sand were black and saturated with bitumi- nous oil. This latter fact was unexpected, and would appear to illustrate the mode of formation of more ancient bituminous shales. The refuse of the city gas-works, and probably of some coal-oil refineries, run into the river. The oils appear to have an affinity for the particles of clay carried down the river, and, precipitating, become bituminous sediments at the bottom. Im the same manner oils, from a profusion of decomposing animals, and probably also plants, supplied the sedimentary muds of ancient shales. Many even of the lowest plants contain abundance of oil, and it may be observed in such forms as Vaucheria, Diatomes, etc. Fertilization in Beans.—Mr. MEEHAN observed that in all the discussions on the injurious effect of close breeding in flowers, and the consequent theories of cross fertilization, nearly all the arguments were drawn from structure. We are asked to note certain arrangements, and then to believe that certain results must follow. He preferred to watch the plants in their actions, and in the results of their actions when excluded from external agencies, believing it the more practical way and preferable to the theoretical one. One of his friends who thought he was wrong in limiting insect agency to a few plants, and in questioning the injury from vegetable close breeding, had been giving for some months past a series of articles in proof of his side, which was the generally ac- cepted view. Of course the position of his friend was entitled to all the benefit to be derived from structural arrangement; but when he referred to actual behavior in plants, it came within the province he had marked out for himself. In the last paper there was an instance of this kind. After noting how the flowers of 194 PROCEEDINGS OF THE ACADEMY OF [1876. Phaseolus, the common bean, were formed; and the supposed im- possibility of fertilization by its own pollen, the paragraph con- cludes as follows: ‘* The machinery tells its own story plainly. The confirmation is familiar to all who know beans and their facility of mixing when different varieties are grown together.” Mr. M. said he claimed to “ know beans” for thirty years past ; and had grown large numbers of varieties side by side, saving seed from them and re-sowing, and had never known a single case of admixture from this close proximity. The various kinds of both Beans and Peas in cultivation were in all cases evolutions, or, as would be commonly said, “sports or accidents,’ or were the results of actual manipulations by skilful seed raisers. He had no hesitation in saying that his friend was utterly wrong in his impression of the facts; that he did not ‘*know beans ;” and the fact that beans would not mix, though so close together, and so freely visited by bees, was an excellent argument against in- stead of for the generally received theories of insect cross fertili- zation. Fruit of Akebia quinata.—Mr. THoMas MEEHAN exhibited a fruit from a plant grown by Mr. W. Canby, of Wilmington, Del., who had three fruits from two old plants, and they were the first fruits he had heard of, after twenty years of extensive cultivation in America. In China and Japan, where it is a native, it is regarded as an edible fruit, and, inferring from its having a ver- nacular name, Fugi-Kadsura-Akebi, the fruit is probably common there. Attempts had been made to induce fruitfulness here by cross fertilization, but they had failed. It was not, therefore, a question of fertilization, but one of nutrition. The fruit is as large and of the appearance of a papaw (Aszmina triloba), but opens on one side as in a follicle of Asclepias, disclosing the long column of parietal seeds. Mr. M. pointed out by it the difference between the Lardizabilaceous and Menispermaceous orders. Note on Phallus feetidus.—Mr. MEEHAN exhibited specimens of © what he supposed to be a variety of this fungus. It was very rare with him, the last time it had appeared on his grounds was seven years ago. Its brilliant scarlet color and strong fetid odor would have attracted attention had it been in existence during that time. It was doubtful if any existed in the vicinity, and it was an inte- resting question whether the spores or mycelium had been in the ground all that while, or whether it had been recently brought as a spore in the atmosphere. But the main point he wished to draw attention to was the attraction the fetid plant had for meat flies. They abounded on the plants. ‘The common toad plant of green- houses (Stapelia variegata) attracted these in the same way, and it was said to be a scheme to aid the plant in cross fertilization, the stench attracting the flies, and inducing them to deposit eggs under the impression it was rotten meat; though what benefit it ‘ 1876. ] NATURAL SCIENCES OF PHILADELPHIA. 195 was to the fly to be thus fooled had never been made clear to him. In the case of this fungus, however, it would hardly be contended that the flies had been deceived for the purposes of fertilization, nor could he understand why ‘“in-and-in breeding,” if bad for phenogams, should not be injurious to a fungus as “well. OcroBER 10. Mr. Vaux, Vice-President, in the chair. Thirty-two members present. Destructive Coleoptera.—Dr. LE ContE mentioned that a small Coleopterous insect had recently proved quite destructive to car- pets in houses in Albany and neighboring towns in New York. Mr. J. A. Lintner had sent him some specimens of the larve a few weeks ago, which proved to belong to some species of Dermestida, of unfamiliar form. Recently Mr. Lintner succeeded in rearing one of the larvze, and sent the imago for examination. It was immediately recognized as Anthrenus scrophulariz, a very com- mon European species, not before reported as occurring in the United States. Herbst, Kafer, vii. 328, mentions that the larve destroy natural history collections, clothes, furs, leather, and edi- bles (Esswaaren). Remarks on the Structure of Precious Opal.—Prof. Lripy stated that Signor A. G. Arevalo, proprietor of one of the opal mines in Queretaro, Mexico, had recently called upon him, and exhibited a large collection of cut opals of various kinds, comprising the milk-white opal with a rich harlequin display of colors, the less valued transparent glassy variety with rich hues, and the red fire opal of different shades, also displaying the play of colors of the spectrum. From among them he had selected several which he exhibited to the Academy as illustrating in an unusually distinct manner the structure of the precious opal. One of the specimens is white opal, emiting on one side from the free surface a brilliant cli ys of colors. These are reflected from facets ranging from } to 1 mm. in breadth, and of irregular poly hedral form, as represented in ficure rE The facets are distinctly separated by fis- sures, which, in the polishing of the stone, have ‘become more or less filled with dirt, and they appear to form the surface of a mosaic pavement laid on a basis of amor- phous opal, of which the other side of the specimen consists. The facets are distinctly striate; the strie being parallel on the same facet, but changing in direction on the differ- ent ones, though pursuing the same general course over comparatively large areas, as represented in the same 196 PROCEEDINGS OF THE ACADEMY OF [1876- figure. The striz, or tubes as Sir David Brewster considered them to be, vary in degree of fineness; some apparently being double or more the thickness of others. He had not attempted to measure them accurately, but they appear to be about the size of the lines in the ordinary micrometer eye-piece of the microscope. There appeared usually to be about 4 or 5 striz in the space of goth of a mm. Another specimen is a dark carnelian-hued fire-opal, which exhibits in directly looking upon it, just beneath the surface, a patch of round or oval spots of a deeper hue. The spots range from jth to 1 mm. in breadth, and are separated by interspaces from }th to 3th of amm. The appearance of a portion of the specimen magnified is represented in figure 2. The spots appear as lenticular disks with finely striated surfaces; the striz being parallel, and on the different spots pursuing nearly the same course. Viewed at a certain angle, they mainly emit a rich golden-green hue. In another opaque white specimen, emitting Fig. 2. rich hues, the striated facets are more or less isolated by amorphous opal, and vary much in size, as represented in the magnified figure 3. The smaller facets are generally irregularly oval; the larger ones appear to be made up of an aggregate of the smaller kind. Over comparatively large areas, the striz of the different facets pursue nearly the same direction, but in contigu- ous areas they even pursue quite opposite directions, as represented in figure 3. On the larger patches, also, as I have at- tempted to represent them, the striz are not perfectly continuous, but appear to be rather interrupted in bands. On another part of the same opal the brilliant patches would appear to per-. tain to cylindroid or fusiform rods of the striated opal imbedded in amorphous opal, as represented in figure 4. The striz in these rods appear to be arranged in regular parallel layers, so that either longitudinal or transverse sections give rise to the appearance of parallel striz. From these specimens precious opals would appear to be constituted of an aggregation of particles of a striated or finely tubular structure which may be imbedded in a basis of more amorphous opal. When isolated by the latter, the particles may appear as lenticular disks, round or oval balls, or cylindrical rods with rounded ends and of variable length. When closely aggregated, these particles become more or less 1876.] NATURAL SCIENCES OF PHILADELPHIA. 197 polyhedral. The particles in section in any direction present a striated appearance, and, according to the varying fineness of the strie, and their inclination, emit the varied hues for which the precious opal is so much admired. Observations on Rhizopods.—Prof. Lripy stated that last July, - in the sphagnum swamps of Tobyhanna, Pocono Mt., Monroe Co., Pa., he noticed an abundance of a Rhizopod which he thought he had not previously seen, and which he at first supposed to be an undescribed species, but which he now viewed as a variety of Hyalosphenia ligata. From this, as previously described, it differs in the test being of a pale sienna color, and perhaps of greater thickness, but otherwise is like it. The test is compressed pyriform, with the length and breadth nearly or about equal, and the thickness one-half. The lateral borders are obtusely rounded. The mouth is transversely oval. The sarcode is colorless, and attached to the inside of the test by diverging threads. The pseudopods are usually from two to three. Measurements, .08 mm. long and broad, and .036 thick, with the mouth .02 broad and .008 wide. Others varied from .06 long and .08 broad, to .092 long by .064 broad. In observing the Pocono variety of Hyalosphenia ligata, and the beautiful and well-marked species Hyalosphenia papilio, he detected an important point of structure which previously had escaped his notice. In the active condition of these, and other Diffilugians, they are seen with one or more pseudopods extended from the mouth of the test, to the margin of which the sarcode is attached, as well as by diverging threads to various points of the interior of the test. The interval between the body of the sarcode and the interior of the test is occupied with water. The extent of the interval increases with the increase in number and extent of protrusion of the pseudopods, and also varies according to the degree of emptiness or reple- tion with food of the sarcode body. When the pseudopods are withdrawn into the mouth of the test, the mass of the sarcode expands in a corresponding ratio, and the threads of attachment to the inside of the test contract in length. The intervening water appears to be displaced through small apertures of the lateral borders and fundus of the test, which exist in numbers usually from two to half a dozen or more, as represented in the figure. While speaking of Rhizopods, he would Hyalosphenia papilio. ask the indulgence of the Academy to listen The arrows are directed to some remarks on recent observations on Be ich ae wan, the habits of several species of Amoeba. : One of the species of Amcba which he escapes when the animal retracts its pseudopods. had most commonly seen, he took to be the 198 PROCEEDINGS OF THE ACADEMY OF [1876. Ameba verrucosa of Ehrenberg, with which the A. natans of Perty, and the A. terricola of Greef, appeared to him to be synonymous. This species he had found in many places: in the crevices of the brick pavement in the yard attached to his residence, in brick ponds, in the ooze of the rocky shores of the Schuylkill River, in sphagnum swamps, in marsh mud, ete. It is remarkable for its sluggish character; and in appearance reminds one of a little pile of epithelial scales, or fragment of dandruff from the head. Appearing quadrately oval or rounded, transparent, and more or less wrinkled, or marked with delicate wavy lines; the pseudopods rise in short obtuse mammillary eminences or wave- like ridges, the summits of which are composed of transparent ectosare, while the central portion of the body is occupied by a thin, pale, diffused, and finely granular entosare. This contains one or more vesicles, usually one, which very slowly enlarges, and then less slowly collapses. In addition, as part of the structure, an oval granular nucleus is sometimes visible. The food contents generally appear not to be abundant, and often the creature appears to be empty of food altogether. The character of its food is the same as with other species of Ameeba. It not unfrequently feeds on Difflugians. In a specimen from sphagnum water, from Vineland, N.J., last August, he observed an individual, about the jy of a millimetre, containing a Difflugia and a Trinema together. As observed by him, the species ranges from ,); to ¢ of a milli- metre in diameter. On the morning of August 27, from some mud adhering to the roots of Sparganium, obtained the day previously in a nearly dried-up marsh, at Bristol, Pa., he obtained a drop of material for examination with the microscope. After a few moments he observed an Amcba verrucosa, nearly motionless, empty of food, with a large central contractile vesicle, and measuring 3'; of a millimetre in diameter. Within a short distance of it, and moving directly towards it, was another and more active Amaba, the species of which he was not positive. It was, perhaps, the one described by Dujardin as A. lima, by which name, for the present purpose, it may be called. As first noticed, this Amaeba was limaciform, 3} of a millimetre long, with a number of conical pseudopods projecting from the front broader end, which was te of a mm. wide. The creature contained a number of spherical food vacuoles with sienna-colored contents, a large diatome filled with endochrome, besides several clear vacuoles, a posterior contractile vesicle, and the usual granular entosarce. The A. imax approached and came into contact with the motionless A. verrucosa. Moving to the right, it left a long finger-like pseudopod curved around its lower half, and then extended a similar one around the upper half until it met the first psendopod. After a few moments the ends of the two pseudopods actually became connate (the second time he had observed this phenomenon), and the A. verrucosa was inclosed 1876.] NATURAL SCIENCES OF PHILADELPHIA. 199 in the embrace of the A. limazx. The latter assumed a perfectly circular outline, and after awhile a uniformly smooth surface; but the central contractile vesicle remained in the same condition, nor did he once observe it enlarge or collapse.. The A. limaxr now moved away with its new capture, and after a short time what had been the head end contracted, became wrinkled and villous in appearance, while from what had been the tail end a number (ten) of conical pseudopods projected. The A. verrucosa assumed an oval form, and the contractile vesicle became indistinct, without collapsing. Moving on, the A. limax became more slug-like in shape, measuring about } m. long, by = m. broad. The A. verru- cosa now appeared inclosed in a large oval clear vacuole, was constricted so as to be gourd-shaped, and had lost all traces of its contractile vesicle. Subsequently, the A. verrucosa was doubled upon itself; and at this period, the A. limagx discharged from one side of the tail end, the siliceous case of the diatome, which now contained only a shrivelled cord of endochrome. Later the A. verrucosa was broken up into five spherical granular balls, and these gradually became obscured and apparently diffused among the granular contents of the entosare of the A. /imax. At one moment the five granular balls derived from the A. verrucosa appeared to be contained in three vacuoles, and the A. limax had a more contracted and radiate form, and then measured y'5 m. in diameter. The observation, from the time of the seizure of the A. verrucosa to its digestion, or disappearance among the granular matter of the entosare of the A. limax, occupied seven hours. From naked Ameebee, the test protected rhizopods were no doubt evolved, and it is a curious sight to observe them swallowed, home and all, to be digested out of their home, just as the con- tents of diatomes are digested. It was also interesting to observe the cannibal Amceba swallowing another, and appropriating its structure to its own, just as we might do a piece of flesh, com- pletely, without there being any excrementitious matter to be voided. Habits of Formica rufa.—Mr. McCook, speaking of the habits of Formica rufa, stated that the ants descending the tree-paths, with abdomens swollen with honey-dew (called by him Repletes), were arrested at the foot of the trees by workers from the hill seeking food. Galleries communicating with the hill, opened at these points, around and in which numbers of ants were huddled engaged in drawing or bestowing rations of honey-dew. Similar commissary stations were found under the stones near by. The replete reared upon her hind legs, and placed her mouth to the mouth of the pen- sioner, who assumed the same rampant posture. Frequently two, sometimes three pensioners were thus fed at once by one replete. Apparently the workers engaged in building at the hill and galleries 200 PROCEEDINGS OF THE ACADEMY OF [1876. had thus resorted to these feeding places to obtain ordinary food, in the same manner that queens, males, and young ants receive it, viz., by disgorgement from the abdomens of repletes. The latter commonly yielded the honey-dew complacently, but some- times were seized and arrested by the pensioners, occasionally with great vigor. A number of experiments were described leading to the con- clusion that there was complete amity between the ants of a large portion of the field, embracing some 1600 hills and countless mil- lions of creatures. Insects from hills widely separated always fraternized completely when transferred. A number of ants collected from various hills fraternized in an artificial nest, har- moniously building galleries and caring for the cocoons, It was found that ants immersed in water when replaced upon the hills were invariably attacked as enemies; the assailants, being immersed, were themselves in turn assaulted. A number of ex- periments were made which indicated that the bath had tempora- rily destroyed the peculiar odor or other property by which the insects recognized their fellows. The variety of #. rufa which had colonized in vast numbers on the cliff at Rockland opposite the steamboat landing, as observed for the last three summers, were found that morning to have aban- doned the place. No trace of them could be seen in the vicinity. The crowds of human beings who occupied the spot during the late International regatta had evidently dispersed the republic. OcrToBER 17. The President, Dr. RusCHENBERGER, in the chair. Thirty-six members present. A paper entitled “ Descriptions of some Vertebrate Remains from the Fort Union Beds of Montana,” by Edward D. Cope, was presented for publication. OcToBER 24. The President, Dr. RuSCHENBERGER, in the chair. . Thirty-seven members present. On Webs of New Species of Spiders.—Mr. McCook called attention to several new species of spiders, with the view to illustrate the existence of mixed habits in construction of the web. The first of the two great groups of the Aranee, viz., the 1876.] NATURAL SCIENCES OF PHILADELPHIA. 201 Sedentary Spiders, consists of the four sub-orders, (1) orb- weavers (Orbitelariz), (2) line-weavers (fetitelariz), (3) tube- weavers (Tubitelariz), and (4) tunnel-weavers ( Territelariz). The first web, that of petra triaranea, n. sp., exhibits quite distinctly the characteristics of the first three of the above sub-orders. The orb, which is the primary characteristic of the snare of this arachnid, is partially inclosed by a web having quite as distinctly the characteristics of the line-weavers. This secondary snare extends several inches above the orb. At the top is a tertiary snare characteristic of the third sub-order. It is a mortar-shaped tube, of white, close textured silk, opening down- ward. Within this the spider dwells, clasping with its fore-claws a thick thread or free radius which is attached to the centre of the orb. He had not been able to determine whether the secondary snare is used, as with the line-weavers, in taking prey, or is pos- sibly a simple protection against hymenopterous enemies. The tube or tent is quite frequent in connection with the orb-weaver’s snare, but the mixture of the line-weaver’s habit is rare, having been observed in but one other Epeiroid, Hpeira labyrinthea of Hentz, the architecture of which was described. * Yade during his remarks on this plant some weeks ag “ower which had produced a perfect cap- sule under a gau. to exclude insects, might yet not produce perfect seeds. The — sule was now ripe, and the seed perfect. Direct Growth Force in Roots.—Mr. MEEHAN spoke of the direct growth-force in roots, as illustrated by some specimens of the White Hickory (Carya tomentosa) exhibited. The Hickories during the first few years of their growth developed far more beneath than above the surface. He had seen Pecan Nuts (Carya oliveformis), with weak stems not two feet high, have tap roots six feet long. In the one year hickory now exhibited, the tap root was three times the length of thestem. In one plant, however, the young radicle, instead of pushing through the cleft made by the separated shell, had been directed into the shell, and in it> fruitless effort to penetrate the wall, had lingered so long, that thc upper portion had grown so large as to prevent egress. The root, therefore, instead of making a slender growth of eighteen inches long, had simply made a bulb of about three quarters of an inch in diameter with the shell of the nut attached to it. Interpretation of varying Forms.—Mr. THos. MEEHAN said that William Bartram, in the last century, had found forms of Lirio- dendron tulipifera on the Schuylkill River, as he had been informed by his son-in-law, with entire leaves, but only this year had he sue- ceeded in discovering them. Some of these leaves he exhibited. He observed that years ago, such discoveries had an interest in themselves. Now the botanist expected to find entire leaved forms among kinds usually lobed, or lobed ones among the entire leaved class; the only value now in these discoveries is in any lesson they might teach. As a rule, he hesitated to refer to the unpub- lished observations of others, preferring that the discoverers should in their own good time and way, report what they had found; but hoped to be pardoned on this occasion, for saying that ona recent visit to the Academy, the distinguished botanist Dr. Engel- 1876.] NATURAL SCTUNCES OF PHILADELPHIA. 203 mann had pointed out that some oaks had lobed leaves even in early infancy, while others had entire leaves, but that those which had the early lobed leaves assumed more entire leaves when mature, and those which had entire leaves when young, had lobed leaves when fully grown. In many oaks which he had examined he found Dr. Engelmann’s observation correct, and that it extended to many other plants. The mu. verries generally had lobed leaves in their younger years, but when ~ature the leaves were uniformly entire ; and this was especially we 10Wn in the case of the Brousso- netia. In young Japan H« — ysuckles the leaves were querci- form or variously lobed, while at maturity the tendency to union was often remarkable. In the common ivy the halbert-shaped leaves of youth, always gave place vo lobeless forms when of fruit- ing age. But it was in cruciferous , its,“ the differences were best seen. Here lyrate or pinnatifi } infancy often gave place to entire ones as the plant ¢ ulle there were numberless instances in which entire juven, __.t leaves gave place to pinnatifid ones in adolescence. Howc v, the point for the present evening was, that there was often a vast difference between the leaves of a plant’s early life, and their form in advanced age. In Coniferz he said this was well known. During the first few months from seed, the different species in their several subdivi- sions were so nearly alike, that it was almost impossible to tell any one apart till a little age had brought divergence from the original type. He exhibited some young Thujas to illustrate this. The early Thujas all had ericoid leaves. In the forms which we knew as Arbor Vites, the condition which we were familiar with was the secondary form. In these the leaves, which in juvenescence were free and heath-like, had become almost wholly , united with the branches. But there were cases where they. ©g Arbor Vitzs had never had power to leave their early condition. They were the analogues of what we know in human nature as imbeciles or feeble minded; and of this class were many so-called ** Retinesporas,” Riota Meldensis, and many Junipers and Thujas. He had known the Thuja ericoides of gardens remain fifteen years in this infantile state, and then only one of thousands to regain the pure adolescent or fan-like arbor vite form. In all these cases it is important to notice that a comparative feebleness of growth, and an absence more or less total of all disposition to produce flowers, go with these continuously juvenescent char- acters. With the appearance of sexual characters, there is a change of form; and,in proportion as this change is the more marked, is the relative productiveness. The White Oak (Quercus alba) which, during its first year, has entire leaves, has them lobed at maturity; and the trees which have them the most deeply lobed ure the most productive in acorns. He found these observations to hold good in the entire leaved Liriodendron. During the first year all tulip trees had entire 204 PROCEEDINGS OF THE ACADEMY OF [1876. leaves, or at least more or less so in comparison with those which they afterwards assume. These large trees with entire leaves had merely retained their juvenescent form. The other attendant characters of juvenescence were also present. The tree from which the large entire leaf exhibited was taken had no signs of ever having borne seeds. In one place he found two trees which, from surrounding circumstances, he should judge were probably about the same age, and in every circumstance relating to nutri- tion equally favored, one with very deeply cut leaves even to the most feeble branch was covered with seed cones, and was thirteen feet in circumference. The other had leaves almost entire, with but few fruit, and a trunk of only eight feet round. The danger was that in discussing laws of variation in connec- tion with the origin of species we may overlook these sexual and physiological changes. If one never having seen a Baltimore oriole should notice particularly the brilliant plumage of the male bird, and, without noticing the sex, compare it with the very dif- ferent looking female bird, he would be very apt to think he had found a “missing link” in a grand evolutionary chain. There were many differences in animals which were recognized as having their origin in obscure sexual laws, as well as many more unre- cognized but probable; and he believed these cases were far more numerous in vegetation, and they would have to be carefully eliminated from consideration in any study on the origin of spe- cies or the evolution of form in relation thereto. Edwin A. Barber, H. F. Whitman, and Dr. W. Forwood, U.S. A., were elected members. Col. W. L. Ludlow was elected a correspondent. The following papers were ordered to be printed :— 1876.] NATURAL SCIENCES OF PHILADELPHIA. 205 ON THE MARINE FAUNAL REGIONS OF THE NORTH PACIFIC; AN INTRODUCTORY NOTE TO THE REPORT ON ALASKAN HYDROIDS, BY MR. CLARK. BY W. H. DALL, U. S. COAST SURVEY. Mr. Clark’s paper is the first of what is hoped will form a series, by different specialists, on the collections of marine invertebrates, obtained by me, with the co-operation of my party and other per- sons interested, during a period extending over nearly ten years. The first explorations in that region were begun in 1865, under the direction of the late lamented Robert Kennicott, and by the courteous co-operation of the officers of the Western Union Tele- graph Company. Since the death of Mr. Kennicott the direction of the work has devolved upon me. By far the richest portion of the invertebrate collections has been obtained between 1871 and 1875, while engaged on hydrographic work for the U. 8. Coast Survey. During the whole period mentioned the work has been aided by the earnest co-operation of the Smithsonian Institution, a circumstance to which is due a large part of our success. Among those persons to whom we owe thanks for assistance in forming the collections, and to whom I beg to express my sense of indebtedness, are particularly to be mentioned Capt. E. E. Smith, of San Francisco, whose energetic dredgings in the Arctic Ocean have furnished nearly all our material from that region ; Mr. Bernhard Bendel, formerly stationed at Unalashka; and Messrs. W. G. Hall, E. P. Herendeen, A. R. Hodgkins, Sylvanus Bailey, Mark W. Harrington, Marcus Baker, and Wm. M. Noyes, attached for shorter or longer periods to the Coast Survey party under my charge. To the officers directing the U.S. Coast Survey I have been indebted for hearty co-operation. In April, 1873, I gave a short notice of the principal faunal regions into which the information gained in the field seemed to permit the division of the coast of Alaska. Mr. Clark’s independ- ent reasoning from a study of the hydroids alone, confirms in every particular the opinions then expressed, and information gained since 1873, seems to offer only additional confirmation of the views held by me at that time, with some interesting additions. A brief statement of these views will be in place here. The coast of Alaska and northwest America from Monterey, California, north and west may be divided into three faune. 206 PROCEEDINGS OF THE ACADEMY OF [1876. I. The Oregonian Fauna. This extends from Monterey to the Shumagin Islands. II. The Aleutian Fauna. The range of this province is from the Shumagins westward throughout the Aleutian chain, and northward to the winter line of floating ice in Bering Sea; a line extending westward from Cape Newenham toward and grazing the Pribiloff group, and thence to the western termination of the Aleutian chain, bounded by the depth of the water in Bering Sea, extending probably to no greater depth than five hundred fathoms, and entirely cut off from the adjacent coasts of Asia. Ill. The Arctic Fauna. This well-recognized fauna passes in water over five hundred fathoms in depth indefinitely southward on the ocean bottom. By the shores it is limited by the winter line of floating ice, or water of the temperature of thirty-two Fahrenheit at the surface, for a certain proportion of the year. The species belonging to this fauna creep southward along the shores to the northernmost islands of Japan on the west coast and Cape Newenham on the east coast of the ocean of this region. Many of them extend even further south; as the species of Arctic habitat have a greater facility of adaptation to other than their normal conditions than those of any other existing fauna. The material derived from the coasts of N. W. America, from Cook’s Inlet south and east, indicate a series of Arctic colonies in favored localities, the future exploration of which offers a labor of the highest interest. These colonies are situated where the depth of water, the drippings of glaciers, and the high and adja- eent shores of the Great Archipelago, combine to reduce the temperature of the water below its apparently normal isotherm. Cook’s Inlet affords one of them, one exists in the Gulf of Georgia, and others only await further exploration. In these colonies we find strictly Arctic species, such as nor- mally abound in the vicinity of Iey Cape; islands of polar life surrounded by shoaler water; forms altogether alien to them. In the absence of information as to depth and temperatures, collec- tions made at such localities would indicate to the student only inextricable confusion of different faunz. The species of each fauna are not, of course, rigidly bound 1876.] NATURAL SCIENCES OF PHILADELPHIA. 207 within the limits above set forth. According to their various degrees of adaptability to the surroundings, they creep south or north from their own proper region, until their limit of tempera- ture is reached. Nevertheless the course of currents, the changes in depth and the variation in temperature, are so far co-ordinate that the limits herein mentioned may be taken as approximately exact for the mass of species. I would here reiterate the view published by me in 1868, that temperature, and temperature alone, is the great factor in deter- mining the limits of marine faune. Depth, salinity, specific gravity, motion or quietness in the water, and geological character of the shores and sea bottom have their influence in determining the distribution and individual characters of particular species or small groups of species ; but for marine faune, all my field obser- vations lead to but one conclusion, that they are absolutely de- pendent on the water temperatures. It is hardly necessary to point out, in view of recent deep sea researches, that the ocean valleys which so sharply separate adjacent faunze, are in such cases valleys of depressed temperature as well as depressed sea-bottom. Leav- ing out strictly littoral or shore forms, restricted by the nature of their food to very moderate depths, no case is known to me in which a deep sea valley, not containing colder water than that on either side of it, separates two great marine faunal provinces. Local subfaunz are not here considered. The geological formation supplies the elements of plant life ; the phytophagous mollusks are distributed where they can obtain their favorite food. All formations supply some algze, and the zoophagous mollusks can find some food almost anywhere. They are therefore the best indices of faunal provinces in their own sub- kingdom. Something similar is probably true of other groups of marine animals. The mollusks are here referred to as the group with which I have the greatest familiarity. A striking instance of this local distribution is afforded by granitic areas. On the Alaskan coast these appear to afford special opportunities for the growth of the red or chlorospermous alge. In granitic districts they are quite abundant compared with what we know of their occurrence in sandstone or basaltic regions. Here also we find a number of species which prefer red algee as food, and a notable tendency to rosiness in the coloring of shells and annelids. 208 PROCEEDINGS OF THE ACADEMY OF [ 1876. Other details of a similar nature are reserved for future publica- tion. In regard to the collection of hydroids it may be remarked that the collection illustrating the Arctic province was very small, and by no means sufficient to represent it fairly. The Oregonian province is also less fully represented than is desirable. For the Aleutian region the collection is tolerably full, though it cannot be doubted that many of the more’ minute or delicate forms were overlooked. However, Mr. Clark’s paper forms a desirable contribution to our knowledge of a little known region, and must be regarded as a considerable advance on our previous information. It is to be expected that a fuller investiga- tion of the Arctic province will reveal many more circumpolar species, and in the Oregonian fauna a fuller representation of those already known from the Californian coast. The types of the species mentioned are deposited in the National Museum in charge of the Smithsonian Institution at Washington; a series has also been placed in the Peabody Museum of Yale College, and in the Museum of the University of Michigan. PROC.A.N.S.PHILA.1876. PLATE VII. S 3 F mn Clark P del. Sinclair & Son, Photo-lith. Clark on Alaskan Hydroids. S.F. Clark, del. Sinclair & Son , Photo-lith. Clark on Alaskan tydroids ; Gi re. 1arl TK on Al 1a E alk 9 pf = ie 14 an Hy rdr PROC. A.N.S.PHILA.1876. PLATE XI. onn ] 7.4 7 hp Ya es aYr aust Son clair & So Shite ols )-£.ULaArK GEL. Sinclair & Son, , Photo-lith. Clark on Alaskan Hvdroids. PROC. A.N.S.PHILA.1876. PLATE XI. 5:F. Clark, del. Sinclar 2 Son, Photo-lith. Clark on Alaskan Hydroids. PROC. A.N.S.PHILA.1876. PLATE Xml. = 2 F : Clark, del. Sinclair & Son , Photo -lith Clark on Alaskan Hydroids. a si¥ PROC. A.N.S.PHILA.1876. . PLATE XIV. Clark on Alaskan Hydroids. PLATE XVI. Sinclair & Son , Photo-lith. Clark on Alaskan Hydroids. PROC. A.N.S.PHILA.1876. S.F. Clark, del. 1876.] NATURAL SCIENCES OF PHILADELPHIA. 209 REPORT ON THE HYDROIDS COLLECTED ON THE COAST OF ALASKA AND THE ALEUTIAN ISLANDS, BY W. H. DALL, U.S. COAST SURVEY, AND PARTY, FROM 1871 TO 1874 INCLUSIVE. ; BY S. F. CLARK, YALE COLLEGE, NEW HAVEN. The Hydroids collected on the Alaskan coast by Mr. Dall, rep- resent the fauna more or less completely from the Sea Horse Islands southwest of Point Barrow in latitude about 71° north, to Kyska Harbor 52° north, and from St. Paul Island, Pribiloff group, longi- tude 170° west, and Kyska Harbor 182° west to Sitka in longitude 135° west. This region includes a coast line of about 4000 miles naturally divided into three great divisions. The Arctic region, ex- tending from Point Barrow to Cape Prince of Wales, washed by the Arctic Ocean; the western region, including all of the western coast of Alaska from Cape Prince of Wales tothe Aleutian Islands, borders on Bering Sea, and the southern region, extending from the Aleu- tian Islands to Sitka, washed by the North Pacific. As the north- ern region isonly represented by two species, one from the Sea Horse Islands and Cape Prince of Wales, and one from Icy Cape, we have no opportunity of comparing the Hydroid-fauna of that region with those of the other two. The region most abundantly repre- sented in the collection is the southern, and it is here also that we find the most strongly marked fauna; for of the forty-two species in the collection, twenty-four are from the southern coast east of the Shumagin Islands, and of these twenty-four, fourteen are peculiar to this southern region. From the shores of the Aleutian Islands, from Unimak to Kyska, there are fifteen species repre- sented, six of which are not found elsewhere, and four are found both to the northward in Bering Sea, and to the eastward in the Northern Pacific. The collections from these two regions (the Aleutian Islands, and the southern Alaskan coast, from the Shu- magin Islands east to Sitka) contain thirty species, or fully three- fourths of the known species from Alaska. While this result is in part due to the fact that the greater amount of collecting has been done in these regions, it also indicates a richer fauna, for some important genera of the southern fauna are not represented north of the Aleutian Islands. The most strongly marked barrier on the coast, as indicated by 210 PROCEEDINGS OF THE ACADEMY OF [1876. the hydroids, is the Shumagin Islands on the southern shore, which is apparently the dividing line between the northern and southern forms. As in all the divisions of nature, there is, of course, no sharp line of demarcation, but a number of the species of each group have a range extending into the region of the other. Of the forty-two species represented, sixteen have been recorded from the English coast, and of this latter number, all but two are found on the shores of New England; of the remaining twenty- six, one is identical with a New England form and the rest are new. The great majority belong to the group Thecaphora of Hincks, there being but four representatives of the Athecata. The following table contains a list of all the Hydroids in the collection, and gives their range upon the Alaskan coast :— THECAPHORA. Obelia longissima Hincks (Pallas). Clytia Johnstoni Hincks (Alder). Campanularia denticulata, sp. nov. ee circula, sp. nov. 3s turgida, sp. noy. se compressa, sp. noy. et speciosus, sp. noy. ee urceolata, sp. nov. Se integra Macgillivray. Gonothyrea hyalina Hincks. Lafoéa pocillum ? Hincks. ‘© gracillima Sars. ‘* dumosa Sars. ‘* fruticosa Sars. Calycella syringa Hincks (Linn.). Coppinia arcta Hincks (Dalyell). Halecium muricatum Johnst. ‘¢ ? plumularioides, sp. nov. ne scutum, sp. nov. Diphasia mirabilis Verrill. Sertularia filicula E. and §S. ce similis, sp. noy. eS cupressoides, sp. nov. Ue variabilis, sp. nov. Os inconstans, sp. Noy. “t thuiarioides, sp. nov. Sertularella tricuspidata Hincks. eS rugosa Gray (Linn.). fa polyzonias Gray. Tliuliuk Harbor, Unalashka. Lituya Bay to Popoff Straits. Port Etches. Port Etches. Port Etches. Shumagin Islands. Shumagin Islands. Lituya Bay. Lituya Bay to Semidi Islands. Semidi Islands to Nunivak Island. _ Nunivak Island. Sitka Harbor to Shumagin Islands. Port Etches. Shumagin Islands to Kyska Island. Shumagin Islands. Shumagin Islands. Unalashka. Nunivak Island. Semidi Islands to Unalashka. Port Moller to Shumagin Islands. Shumagin Islands to St. Paul Island. Hagmeister Island. Shumagin Islands to Hagmeister Id. San Miguel Id., Cal., to Nunivak Id. Unalashka. Chignik Bay to Nunivak Island. Port Etches to Kyska Harbor. Shumagin Islands to Nunivak Island. Port Etches to Nunivak Island. 1876.] NATURAL SCIENCES OF PHILADELPHIA. 211 Sertularella robusta, sp. nov. Shumagin Islands. es pinnata, sp. nov. Lituya Bay to Unalashka. Thuiaria cylindrica, sp. nov. Port Méller to Hagmeister Island. ‘* robusta, sp. nov. Hagmeister Island to Seahorse Ids. ‘* plumosa, sp. noy. Nunivak Id. to Icy Cape, Arctic Sea. ‘* turgida, sp. nov. Lituya Bay to Kyska Island and Hagmeister Island. ut gigantea, sp. nov. Kyska Island to Hagmeister Island. Macrorhynchia Dallii, sp. nov. Akutan Pass. ATHECATA. Rhizonema carnea, sp. nov. St. Michael’s, Norton Sound. Tubularia indivisa (Linn.). St. Michael’s. Tubularia borealis, sp. nov. Hagmeister Island. Eudendrium pygmeeum, sp. noy. Akutan Pass. It is interesting to note that of the ten species of Campanu- lariidz represented, one only occurs to the northward of the Aleu-. tian Islands; and as this one, viz. Gonothyrea hyalina, is re- corded by Hincks from the Shetland Islands, by Sars from Lofoten, and by Professor Verrill from Eastport and St. George’s Bank, it is apparently a northern or cold-water form. Both the species from the Arctic Sea belong to the genus Thuzaria, and of the five species of this genus in the collection, but one of them occurs south of Bering Sea. The genus is essentially a northern cold- water one. Hincks says of 7. thuia, “it is a prevalent northern form, ranging to the North Cape,” and Allman describes some species from very deep: water, that were taken on the Porcupine expedition. The thickness of the perisare seems to protect them from the dangers incident to living in cold deep waters. A very noticeable feature, and a very general one, is the re- markable stoutness and large size of the specimens, especially in the Sertulariide. The main points of interest then derived from the study of this collection are—the strong indication of a faunal limit at the Shumagin Islands; the Hydroid-fauna to the south of that point being chiefly characterized by the large number of Campanulariide, while the fauna to the northward is almost entirely destitute of that family and contains a larger number of Thuiarie ; the luxu- riant growth and the robustness of nearly every species; the specimens of those species that are also found upon the New Eng- land shores being of larger size and stouter form than the eastern 212 PROCEEDINGS OF THE ACADEMY OF [1876. specimens; thirdly, that while the fauna is quite distinct, as is indicated by the twenty-three new species, it has yet some simi- larities with the New England and British fauns, which are shown in the fifteen species that are common to those three regions; fourthly, the small number of Athecata, which may be partly accounted for by the possibility of their having been overlooked, owing to the small size and obscure places of growth common to so many of the species of this group. And, lastly, the small number of species that are common to the Alaskan coast and the western shores of the United States from Vancouver Island south- ward. Of the twenty-three species recorded from the latter region one only, Lafoéa dumosa, is known from the coast of Alaska. DESCRIPTIONS OF THE SPECIES. THECAPHORA. Obelia longissima, Hincks (Pallas). This species is the most abundant member of the family in the collection, but, although some of the specimens are 150 mm. in length, and have a very luxuriant growth, a diligent search has - failed to reveal any gonangia. It is possible that these forms may prove to be different from QO. longissima, but the trophosomes agree so closely in every particular, that I think it quite safe to credit them to this species. Hab. Nliuliuk, Unalashka; 3 fathoms, shingly bottom. Unalash- ka; 6 fathoms, November 11th, among sticks and beach-refuse, washed along the bottom. Unalashka; 80 fathoms, sand, and shells. Unalashka; 9 to 15 fathoms, September 10th. Una- lashka; 15 fathoms, gray sand. Clytia Johnstoni ? Hincks (Alder). Plate ix., fig. 12. The collection contains specimens of a creeping campanularian from three localities which I have decided to call C. Johnstoni, for the present, at least. The gonangia are not present upon any of the specimens, and when known will enable us to decide whether these trophosomes have been placed in the right genus. The specimens from Lituya Bay correspond very closely with the New England forms of this species, while those from the other locali- ties are more deeply campanulate, and some of them are much less tapering; the pedicels vary greatly in length and in the amount 1876.] NATURAL SCIENCES OF PHILADELPHIA. 213 of annulation which they bear. The character of the denticulation varies but little, if any, and the hydrothecz, which show the greatest variation in size and shape, are connected by intermedi- ate forms. Hab. Lituya Bay; 9 fathoms, sandy-mud. Port Etches; 5 to 8 fathoms, gravel and stones, May 30th. Shumagin Islands, Popoff Straits; 6 fathoms, rocky, July. Campanularia denticulata, sp. nov. Plate vii., fig. 4. Trophosome. Hydrocaulus simple, creeping, giving origin to the pedicels at irregular intervals ; pedicels of very variable length, from five to ten annulations at the base, and from three to eight at the base of the hydrothece, usually bearing but one hydro- theca, occasionally branched and bearing two. Hydrothece deeply campanulate, tapering from the distal end, quite slender near the base, rim ornamented with about fifteen large, acutely-pointed teeth. Gonosome. Gonangia unknown. Hab. Port Etches, Alaska; 10 to 18 fathoms, clayey mud. Campanularia circula, sp. nov. Plate vii., fig. 3. Trophosome. Hydrocaulus erect, compound, composed of a number of slender united tubes, unbranched. Hydrothece large, deeply campanulate, rounded at the base, rim ornamented with from ten to twelve large denticulations, some of which are square- cut, others have slightly rounded edges, and are very shallow; the pedicels supporting the hydrothec are long and slender, a single distinct annulation at the base of the hydrotheca, the re- mainder of the pedicel more or less twisted, arranged in verticils of four to six pedicels, at regular intervals on the stem. Gono- some. Gonangia unknown. Hab. Port Etches, Alaska; 12 to 18 fathoms, clayey mud. This well-marked form is represented by a single small speci- men, which, unfortunately, is destitute of gonangia. Its nearest ally is C. verticillata, Lamk, from which it may be distinguished by the size and form of the hydrothecz, and by the ornamentation of the rim. Campaunularia turgida, sp. nov. Plate viil., fig. 8. Trophosome. Hydrocaulus simple, creeping, giving rise, at short intervals, to long pedicels bearing the hydrothece. Hydro- thece large, turgid, rounded at the base, the rim ornamented with from twelve to sixteen roundly pointed or sometimes square- 214 PROCEEDINGS OF THE ACADEMY OF [1876. topped teeth, borne on long, slender pedicels with a wavy outline, or oceasionally a slight twist in them, a single well-marked annu- lation at the base of each hydrotheca, and from three to six annu- lations at the base of each pedicel. Gonosome. Gonangia borne on short pedicels consisting of five or six annulations springing from the creeping stem, flask-shaped, largest in the middle, taper- ing but slightly to the rounded base, produced into a neck dis- tally, aperture terminal, discoidal. Hab. Port Etches, Alaska; 12 to 18 fathoms, mud. Campanulari compressa, sp. nov. Plate viii., figs. 5, 6. Trophosome. Hydrocaulus creeping, simple, giving origin to the pedicels at irregular intervals. Hydrothece large, deeply campanulate, tapering to the base, the walls very thick, especially at the base, where they project inwards, forming a sort of dia- phragm, upon which the polyp rests, rim entire; pedicels of medium length, with a single well-marked annulation at the base of the hydrothece, and usually two or three constrictions just beneath the annulation, not annulated at the base. Gonosome. Gonangia turgid, sessile, or with a very short pedicel, largest at the distal end, rounded at the base, very much compressed late- raliy. Hab. Yukon Harbor, Shumagin Islands; 6 to 20 fathoms, sand and rocks, July 7th. Growing on a piece of Laminaria. This form belongs in the same group with C. calyculata, Hincks, from which it may be distinguished by the gonangia, and by the base of the hydrothece. Campanularia speciosa, sp. nov. Plate ix., fig. 11. Trophosome. Hydrocaulus simple, creeping, twisted, bearing the pedicels at irregular intervals; pedicels short, more or less annulated, bearing each a single hydrotheca. Hydrothece very large, deeply campanulate, urceolate, the rim ornamented with about ten shallow teeth, and with an internal ridge extending from each tooth for about one-fourth the distance, to the base of the hydrotheca. Gonosome. Gonangia unknown. Hab. Yukon Harbor, Big Koniushi, Shumagin Islands; 6 to 20 fathoms, gravel, July 7th. This is the largest creeping Campanularian known, and is as noticeable for its beauty as for its size. The intrathecal ridges and the character of the denticulations make it a well-marked 1876.] NATURAL SCIENCES OF PHILADELPHIA. 215 form, readily distinguishable, without the gonangia, from any known species on the American coast. Campanularia urceolata, sp. nov. Plate viii., fig. 7. Trophosome. Hydrocaulus simple, creeping, rather stout, with a wavy outline, giving origin to the pedicels at irregular inter- vals; pedicels short, never more than twice the length of the hydrothece, usually annulated or twisted throughout, and always one annulation at the base of each hydrotheca more distinctly marked than the rest. Hydrothece large, deep, urceolate, rounded or slightly tapering at the base, with an internal support in the base of the hydrotheca upon which the polyp rests, rim ornamented with from thirteen to eighteen large rounded teeth. Gonosome. Gonangia small, fusiform, occasionally a trifle obo- vate, orifice small, terminal, discoidal, supported on very short pedicels consisting of but two or three annulations. Hab. Lituya Bay, Alaska; 9 fathoms, sandy mud. Campanularia integra, Macgillivray. Plate ix., figs. 9, 10. This species is represented by two fine specimens, which are in an excellent state of preservation, and have three or four fully developed gonangia. The latter are a little larger than usual. Hab. Semidi Islands; 15 to 25 fathoms, gravel, June 10th. Lituya Bay; 9 fathoms, sandy mud. The specimen from the Semidi Islands was growing upon a stem of Sertularella tricuspidata. Gonothyrea hyalina, Hincks. Plate vii., figs. 1, 2. This is apparently one of the most common species of the family Campanulariide on the Alaskan coast. Very good speci- mens were obtained from five different localities; those from the Semidi Islands being of especial value, as they bear extra-capsular medusoids at the distal ends of the gonangia. The medusoids vary in number from two to six, are slender and pyriform, which is probably, in part, owing to the contraction due to the alcohol. Hab. Semidi Islands, Alaska; 15 to 25 fathoms, gravel, June 10th. Port Moller, Aliaska Peninsula; 13 fathoms, gravel; 17 fathoms, sand; August. Five miles southwest of the west cape of Nunivak Island; 30 fathoms, sand. Lafoéa pocillum? Hincks. Plate xi., fig. 21. There are two specimens of creeping forms of Zafoéa in the collection, to the examination of which I have given considerable 216 PROCEEDINGS OF THE ACADEMY OF [1876. time. Number 1 has short, stout hydrothecz of variable shape, borne upon short pedicels of from three to six annulations, the latter showing a good deal of difference in the stoutness, some being half as wide as the hydrothece, others not more than a third; most of the hydrothecz are urceolate, like Hincks’s figures of L. pocillum ; others are regularly cylindrical, like Hincks’s figure of LZ. parvula, and between these two are forms which make a connecting series between the urceolate and cylindrical types. Number 2 has the hydrothecz of about the same width, but longer, the pedicels average a little longer, and it agrees more closely with Z. pocillum than the more variable form of number 1. The perisare of both these forms is very thick, and dark-brown colored. Hab. Number 1 is from Cape Etolin, Nunivak Island, Alaska ; 8 to 10 fathoms, stony. Number 2 is from Bering Sea, 5 miles west of west cape of Nunivak; 30 fathoms, sand. Lafoéa gracillima, Sars. Plate xii., fig. 24. Very fine specimens of this delicate form were collected, which show no variations from the specimens found on the eastern shores of North America. Gonangia unknown. Hab. Coal Harbor, Shumagin Islands, beach; July 15th. Sitka Harbor; gravel and mud, 15 fathoms, May Ist. Lafoéa dumosa, Sars. Plate xii., fig. 23. This widely distributed species is also a member of the Alaskan Hydroid Fauna. ‘The specimens are larger and more robust than those from the eastern shores of North America, and the hydro- thece are more deeply merged in the stem. It is very singular that we are still obliged to record, for this common and widely distributed species, gonangia unknown. Hab. Port Etches; 12 to 18 fathoms, clayey mud. Lafoéa fruticosa, Sars. Plate xii., fig. 22. This appears to be the most common of the four species of this genus in the collection. It differs only from the New England specimens in being more robust. Gonangia unknown. Hab. Kyska Harbor; 10 fathoms, rocky, July 15th. Popoff Straits, Shumagin Islands; near edge of reef, 6 fathoms. Yukon Harbor, Big Koniushi, Shumagin Islands; 6 to 20 fathoms, sand and rocks, July 7th. 1876.] NATURAL SCIENCES OF PHILADELPHIA. 217 . Calycella syringa, Hincks (Linn.). Plate xii., fig. 25. A very fine specimen of this species occurs on a colony of Lafoéa gracillima. It is in very fine condition, and has the gonangia with extracapsular pouches in considerable abundance. Hab. Coal Harbor, Shumagin Islands; beach, July, about the 15th. Coppinia arcta, Hincks (Dalyell). A very fine specimen of this peculiar form was collected at the Shumagin Islands. The hydrothecz are very long, and most of them curved near the distal end. Growing on the stem of a colony of Lafoéa gracillima. The largest hydrothecs are 2 mm. long. Hab. Coal Harbor, Shumagin Islands; beach, July 15th. Halecium muricatum, Johnston (E.andS$). Plate x., fig. 15. A single specimen of this species with the characteristic gon- angia, was collected on Unalashka beach. The trophosome is about 50 mm. in height, but is in very poor condition, none of the hydrothecze being present. The gonangia, however, are very abundant, are irregularly arranged on the basal half of the com- pound stem, and:are in a good state of preservation. Halecium (2). plumularioides, sp. nov. Plate x., figs. 16, 17. Trophosome. Hydrocaulus erect, simple, straight, divided by transverse joints into internodes of considerable length, regularly branched, and with a few annulations at the base; branches arranged alternately on opposite sides of the stem, one to each internode, having their origin in a small shoulder-like process just below each joint, divided usually into regular internodes, though, in some cases, short internodes occur between the longer ones. Hydrothece arranged uniserially, usually one to each internode, partly adherent to the stem, or entirely free, shallow, tapering slightly to the base, with an entire rim. Gonosome. Gonangia unknown. Hab. Cape Etolin, Nunivak Island; 8 to 10 fathoms. Height of largest specimen 20 mm. I refer this species to the genus Halecium provisionally, for, the gonangia being absent, and the hydrothecze haying a different arrangement from any known Halecium, make it quite doubtful whether it belongs in this genus. It is the most delicate species in the collection. It closely resembles, in many particulars, the 15 218 PROCEEDINGS OF THE ACADEMY OF [1876. . . hiet,waje Plumulariz, from which it is separated on account of the absence of nematophores. Halecium scutum, sp. nov. Plate x., figs. 13, 14. Trophosome. Hydrocaulus erect, compound, exceedingly stout, rough, with an irregular outline, attached by a thick mass of in- terlaced stolons, much and irregularly branched; branches of two kinds, the larger ones stout, black, and like the main stem undi- vided by joints, the smaller are light horn-color, sub-erect, short, divided into long internodes, each giving origin to a single branch- let; branchlets divided by oblique joints into short, stout, wedge- shaped internodes, each of which bears at least one hydrotheca, often two. Hydrothecz tubular, margin everted, arranged alter- nately, and occasionally a second one is borne in the axil of the first. Gonosome. Gonangia very large, obovate, with the orifice on one side; the latter varies much in position, occurring anywhere from the middle to near the distal end; it has an irregular outline, and is made very ornamental by the thickening of the perisare around it; there is a thickened border around the upper edge, and below the orifice is a shield-shaped thickening in which are two ellipsoidal markings, where the chitin is only of the usual thickness. Height of largest specimen 150 mm. Hab. Unalashka; beach, low water, after gale, September. Coal Harbor, Shumagin Islands; low water, April; Gonangia abundant. Coal Harbor, Shumagin Islands; Gonangiaabundant. Unalashka; beach, May Ist; Gonangia abundant. Semidi Islands, Alaska; 15 to 25 fathoms, gravel, June 10; Gonangia. Sanborn Harbor, Shumagin Islands; Gonangia abundant The specimen from which the above description is taken is a remarkably stout, coarse form, more closely resembling Hinck’s figure of Hudendrium rameum, Pallas (vide frontispiece to Hinck’s British Hydroid Zodphytes, vol. i.), than any hydroid that I am acquainted with. The diameter of the mass of stolons at the base is from 15 mm.to 25mm. The largest stem is 6 mm. thick at the base, and tapers very gradually to the distal end. The variation which this species shows in the mode of growth is so remarkable that I will mention some of the most divergent forms. The specimens from Sanborn Harbor, Shumagin Islands, consist of tufts of light horn-colored stems about 50 mm. in height, rather slender and compound only for a very short dis- 1876.] NATURAL SCIENCES OF PHILADELPHIA, 219 tance at the base, branches very short. Gonangia present, and exactly like those of the typical form. Another style is from 20 mm. to 60 mm. high, from dark horn-color to black, stem stout, coarse, branches numerous and short. Gonangia very abundant ; has a crowded look; specimens of this form are from Unalashka; beach. Semidi Islands; 15 to 25 fathoms, gravel. Coal Harbor, Shumagin Islands; beach, low water, after a gale in September. Diphasia mirabilis, Verrill. Plate xiii., fig. 36. American Journal of. Science, iii., vol. v. p. 9, December, 1872. Connecticut Academy of Arts and Sciences, vol. iii., Part L., p. 58. Two specimens of this remarkable form are the only representa- tives of this genus in the collection. The specimens are in very good condition, and show no variation from Professor Verrill’s type specimen from Le Have Bank, with which I have compared them. Gonangia unknown. Hab. Hagmeister Island, Bering Sea; beach. Popoff Straits, Shumagin Islands. Sertularia filicula, E. and S. Plate xii., fig. 30. This species grows very luxuriantly, and is apparently quite common on the beaches. There is a good supply of it in the col- lection, mostly from Unalashka beach. It grows there in very dense masses from 50 to 80 mm. in height, is usually of a dark horn-color, and attached to algz or sponge. The gonangia vary somewhat from the figure given by Hincks, but not enough to warrant a separation of this form from the British. The Alaskan form has the gonangia sessile, largest at the distal end, tapering to the base, aperture terminal, small, discoidal. In the British form they are more fusiform or are pear-shaped, largest near the middle, with a short tubular aperture. The trophosomes agree perfectly. Hab. Unalashka; beach after gale, September. Coal Harbor; Popoff Straits, Shumagin Islands. St. Paul Island (Pribiloff group); 9 fathoms, sand, July 24. Hagmeister Island; beach. San Miguel Island, California. Nunivak Island; 8 to 10 fathoms. ,Con- stantine Harbor, Amchitka Island; 6 to 10 fathoms, sand and stones, July 20. Chirikoff Island; beach. Sertularia similis, sp. nov. Plate xv., fig. 56. Trophosome. Hydrocaulus erect, simple, slender, straight, jointed, pinnately branched, internodes of equal length and bear- 220 PROCEEDINGS OF THE ACADEMY OF [1876. ing three hydrothece and a branch; branches short, slender, di- vided by transverse joints into short internodes, bearing two, sometimes three pairs of hydrothece, occasionally bearing one or two branchlets, constricted at the base; branchlets jointed like the branches, and like them constricted at the base, diverging at a wide angle from the branches. Hydrothecz opposite, tubular, curved strongly outwards with a bilabiate orifice, the broad side being turned towards the stem; on the main stem there are three on each internode, a pair placed opposite to each other, and one in the axil of the branch; on the branches and branchlets they are arranged oppositely. Gonosome. Gonangia unknown. Height of largest specimen, 85 mm. Hab. Hagmeister Island; 8 to 15 fathoms, gravel. This is a very interesting species, as it combines some of the characters of three other species of the genus. In mode of growth it approaches S. cupressina, in the shape of the hydrothece it is similar to S. argentea, and in the arrangement of the latter it is like S. pumila. Considerable variation is shown in the extent to which the hydrothece curve outwards; upon some of the branches the mouth opens at right angles to the stem, while upon others they open upwards. Sertularia cupressoides, sp. noy. Plate xiii., fig. 37. Trophosome. Hydrocaulus simple, erect, slender, two or three annulations at the base, divided by oblique joints into internodes of variable length, pinnately branched; branches arranged alter- nately, an even number to an internode, attached to the stem by quite a prominent process, annulated and slender at the base, the broader side facing the stem; the basal portion is sharply curved outward, the distal portion is nearly straight, and lies about at right angles with the stem, bearing but very few branch- lets; branchlets short and diverging at a wide angle from the branches. Hydrothece tubular, deeply immersed in the stem, curving slightly outwards; orifice bilabiate, with the broader side facing the stem, arranged snb-alternately upon the branches and branchlets, none upon the main stem. Gonosome. Gonangia unknown. Height of finest specimen, 80 mm. Hab. Shumagin Islands, Popoff Straits; 6 fathoms, rocky bot- tom, July. Port Moller, Aliaska Peninsula; 13 fathoms, sand, August. 1876. ] NATURAL SCIENCES OF PHILADELPHIA. 221 This species is quite similar to S. cupressina in some respects, but may be distinguished by the entire absence of hydrothecze upon the main stem, and by having an even number of branches to an internode; the branches are also usually stouter. Sertularia variabilis, sp. nov. Plate xiv., figs. 40 to 48. Plate xv., figs. 49, 50. Trophosome. Hydrocaulus erect, simple, stout, flexuous, di- vided by transverse joints into short internodes, usually bearing a pair of hydrothece, those giving origin to a branch bearing one hydrotheca on one side and two hydrothece and the branch on the other, regularly branched ; branches arranged alternately on opposite sides of the stem, short, stout, suberect, occasionally bearing a few short branchlets; the latter usually divided into regular internodes, bearing each a pair of hydrothece, sometimes occurring undivided. Hydrothece large, subalternate, the widest portion, the lower two-thirds, is immersed in the stem, the upper portion is narrower and curved strongly outwards and upwards; aperture large, discoidal, rim entire. Gonosome. Gonangia of two forms; No.1 is pyriform, tapering rapidly to the base, ses- sile; orifice large, terminal, discoidal, ornamented with a number of chitinous teeth which project downwards into the gonangia; No. 2 is obovate, sessile, aperture terminal, large, provided with an internal collar, the latter ornamented with a number of acute teeth, which project downwards; borne in two rows on the upper sides of the branches. Height of largest specimen, 100 mm. Hab. Unalashka; beach. Lituya Bay; 112 fathoms. Hagmeister Island, Bering Sea. Sanborn Harbor, Shumagin Islands; beach. Captain’s Harbor, Unalashka; 60 to 80 fathoms, sand, September 13. Port Etches, Alaska; 12 to 18 fathoms, clayey-mud. Five miles southwest of the west cape of Nunivak, Bering Sea; 30 fathoms sand. Popoff Straits. Semidi Islands; 15 to 28 fathoms, gravel, June 10. Unalashka; 6 fathoms, Nov. 11th. St. Paul Island, Pribiloff group; 9 fathoms, sand, Kelp ground, July 24th. Akutan Pass, near Unalashka; beach. Big Koniushi, Shumagin Islands; 6 to 20 fathoms, sand and rocks in Yukon Harbor, July 7th. San Miguel Island, California; W. H. Dall. This is the most variable form of hydroid that I am acquainted with. Besides the great variation which is shown within the ordinary limits of specific differences, there are two extreme forms which, without as complete a series of connecting forms as there 222 PROCEEDINGS OF THE ACADEMY OF [1876. is in Mr. Dall’s collection, would undoubtedly be called distinct species. One of these two varieties is represented by only two specimens, one of which is somewhat worn and mutilated, while the other is in good condition, and bears a number of gonangia. This variety is much more robust than any of the normal forms, the branches being an eighth of an inch wide; the hydrothece are very large and swollen in the middle portion; the gonangia are of the kind given as No.2 in the description. The other variety has slender hydrothece which are free for more than half their length, are not swollen in the middle, and the outline from the aperture of the hydrotheca to the stem forms a curve which projects into the hydrotheca, while in the robust form it projects outward ; most of the hydrothece also have a projection in the shape of a small horn at the inner, inferior angle; some of those on the distal ends of the branches have a well-defined notch in the rim, on the opposite side from the stem, forming a blunt tooth on each outer corner, and between each tooth and the inner margin of the rim there is a slight sinuosity. This character of the rim decreases towards the lower portion of the stems and branches to such an extent, that many of the hydrothece have a rim that is entire, or nearly so. This is not only the most variable, but apparently the most abundant form on the Alaskan coast. In some of its variations it is quite similar to S. abielina of the New England shores, Green- land, and the North Cape, which also shows considerable specific variation, Sertularia inconstans, sp. nov. Plate xv., figs. 51, 52. Trophosome. Uydrocaulus erect, simple, constricted at the base, jointed obliquely, internodes of uniform size, densely branched; branches mostly short, arranged alternately, one to each internode, erect, lying close to each other, a few of the larger shoots bear one or two large branches similar to the main stem, divided by transverse joints into internodes of very variable length, constricted at the base, attached to the stem by quite a prominent process, but little branched ; branchlets few, short, erect. Hydro- thecz large, swollen at base, a constriction near the distal end, aperture discoidal, rim entire, arranged alternately upon the branches and branchlets; on the lower part of the stem, below the branches, there are two to each internode ; on the upper portion of the stem there are usually three to each internode, one on one side 1876.] NATURAL SCIENCES OF PHILADELPHIA. 223 and two on the other; one of the latter being in the axil of the branch. Gonosome. Gonangia sessile, large, orifice terminal, small, discoidal; outline very irregular, tapering usually at the base; borne in two close-set rows on the distal portion of the main stem. Height of specimen 45 mm. Hab. Unalashka ; beach. From the character of the trophosome, this species evidently belongs in the same group wlth S. abietina and S. filicula, the hydrothece agreeing very well in form and arrangement. The mode of growth, however, is quite different, the number and close- ness of the braiches and branchlets giving to the colony a very dense, plumose appearance. The gonangia show the greatest amount of variation of any species that I know of; it is impossible to describe their form, for there is not one of them which seems to agree with any other. Sertularia thuiarioides, sp. nov. Plate xiii., figs. 38, 39. Trophosome. Hydrocaulus erect, simple, very slender at the base, largest at the distal end, the middle portion slender and of uniform size, jointed transversely, internodes of variable length, regularly branched; branches sub-erect, short, springing from opposite sides of the stem, but spirally arranged owing to the stem being twisted, much branched, on some of the largest speci- mens two or three large branches occur, which resemble the main stem in every particular; branchlets short, spreading widely, bearing a few small subdivisions. Hydrothece tubular, deeply immersed, with a constriction on the inner side of the distal end, aperture semilunar shape, arranged alternately upon the branches and branchlets, and basal part of the stem; on the upper branched portion the internodes usually bear one hydrotheca on one side, and two hydrothecz and a branch on the other. Gonosome. Gonangia large, sessile, tapering at the base, ornamented with two pointed horns placed opposite to each other, near the distal end; aperture terminal, discoidal, orna- mented with a row of teeth projecting into the gonotheca, borne in single rows on the upper sides of the branches and branchlets. Height of largest specimen 180 mm. Hab. Bering Sea, 5 miles west of the West Cape of Nunivak Id.; 24 fathoms, sand. Chignik Bay, Aliaska; 11 to 16 fathoms, sand, I have not been able to make out any distinct opercula, but in 224 PROCEEDINGS OF THE ACADEMY OF [1876. one or two instances have noticed a minute piece of membrane, with a ragged edge, hanging from the rim of a hydrotheca. The hydrocaulus is very characteristic, the distal part being often twice the size of the basal portion. Sertularella tricuspidata, Hincks. Plate xii., figs. 26, 27. There are specimens of a Sertularella, collected at four or five different localities, which I at first thought to be a new species, and closely allied to S. tricuspidata, but upon examining them more closely, I find them to be robust forms of the above-named species. The gonangia are very abundant, and are borne in rows on the upper side of the branches. Hab. Semidi Islands, Alaska; 15 to 25 fathoms, gravel, June 10th; gonangia abundant. Popoff Straits, Shumagin Islands. Unalashka; beach. Port Etches, Alaska; 12 to 18 fathoms, clayey mud. Yukon Harbor, Big Koniushi, Shumagin Islands; 6 to 20 fathoms, gravel, July 7th. Kyska Harbor; 10 fathoms, rocky, July 15th. Mliuliuk, Unalashka; 13 fathoms, stony. There is one specimen which is much more delicate than any of the others, but differs in no essential characters. The gonangia are not present. Hab. Semidi Islands, Alaska; 15 to 25 fathoms, gravel, June 10th. Sertularella rugosa, Gray. Plate xiii., fig. 31. This species, which has only been found upon the New England coast at low water, is represented on the shores of Alaska by a stout form, which was found in from six to twenty fathoms. Al- though the gonangia are not present, the trophosomes are so characteristic that I do not hesitate to refer them to this species. Height of the largest shoot 30 mm. Hab. Vliuliuk, Unalashka; on kelp, Oct. 23,1871. -Yukon Har- bor, Big Koniushi, Shumagin Islands; 6 to 20 fathoms, sand and rocks, July 17th. St. Paul Island (Pribiloff group); 9 fathoms, sand, on kelp ground. Cape Etolin, Nunivak Island; 8 fathoms, stony. Sertularella polyzonias, Gray. Plate xiii., figs. 34, 35. A number of very fine specimens of this widely distributed species are in the Alaskan collection. They vary but very slightly from the New England specimens, the hydrothece and gonangia 1876.] NATURAL SCIENCES OF PHILADELPHIA. 225 being on the average a trifle stouter, and the whole colony has a more luxuriant growth. - The gonangia are very abundant, and are borne on the sides of the stems, midway between two hydrothecs. Our specimens are all from two localities. Height of largest specimen 70 mm. Port Etches, Alaska; 12 to 18 fathoms, clayey mud. Five miles southwest of the West Cape of Nunivak Id.; 30 fathoms, sand. Sertularella robusta, sp. nov. Plate xiii., figs. 32, 33. Trophosome. Hydrocaulus simple, erect, stout, flexuous, four or five annulations at the base, divided by transverse joints into internodes of variable length, sparingly and regularly branched ; branches erect, varying greatly in length, those near the base of the hydrocaulus being longest, and like the upper and shorter ones extending to the distal end of the stem, flexuous, constricted at the base, the larger ones bearing a few branchlets. Hydrothecze very large, operculated, deeply immersed in the stem, only enough of the distal end to include the teeth being free, curving slightly outward, the inner angle of the base somewhat produced down- wards toward the centre of the stem, the rim armed with four stout teeth; operculum consists of four segments. Gonosome. Gonangia axillary, very large, sessile, ovate, marked with about eight very prominent transverse bands; orifice ter- minal at the extremity of a short tube, with an entire rim. Hab. Yukon Harbor, Big Koniushi, Shumagin Islands; 6-to 20 fathoms, sand and rocks, July 7th. This is one of the stoutest forms of all the numerous Sertu- lariide from the Alaskan coast; and the large size and conspicu- ous position of the gonangia contribute to make it the most imposing of all the known members of the family. It has a very rigid, angulated habit, more like some of the stouter species of Sertularia, e. g., S. abietina, than the graceful curved mode of growth usually found in Sertularella. The shape and arrange- ment of the hydrothece is also similar to that usually found in the genus Sertularia, and the deep immersion of the hydrothece in the stem remind one of the forms belonging to the genus Thuiaria. The stem, branches, and branchlets are all of about the same width, 1mm. Height of largest colony 50 mm. Length of gon- angia 5 mm., width 2 mm. 226 PROCEEDINGS OF THE ACADEMY OF [1876. It is quite interesting to note that while this species is undoubt- edly a good Sertularella, as is indicated by the form and structure of the gonangia and the operculated hydrothece, it also possesses some of the characteristics of the genera Sertularia and Thuiaria, thus still more closely connecting these different members of the family Sertulariide. Sertularella pinnata, sp. nov. Plate xii., figs. 28, 29. Trophosome. Hydrocaulus simple, erect, straight, much and pinnately branched, divided by transverse joints into short inter- nodes, each of which bears a single branch; shoots occurring in dense clusters; each shoot widest in the middle and tapering more rapidly towards the base than to the distal extremity; branches short, sub-erect, not all in the same plane, inclining towards each other on the upper side of the stem, divided into short internodes, but little subdivided, occasionally a long branch occurs near the base, which is similar to the main stem in all respects. Hydro- theese short, tubular, wide-mouthed, rim ornamented with three large teeth, two of which are usually on the outer side, not all in the same plane, but inclining towards each other, so that in a general view they appear to be arranged uniserially ; hydrothecs on the pinne arranged alternately, one to each internode and on the main stem one in each axil. Gonangia ovate, sessile, axillary. marked with about eight very strong transverse ridges, which, in most of the specimens, have an irregular, wavy outline, orifice terminal, central, discoidal; borne in two rows, in the axils, on the basal half of the stems. Height of finest specimens 35 mm. Hab. Unalashka; beach, low water, after gale, September; grow- ing in dense tufts on sea-weeds, gonangia abundant. Coal Har- bor, Shumagin Islands; low water, attached to fuci and sponges, gonangia abundant. Lituya Bay; 9 fathoms, sandy mud; gonan- gia present. Lituya Bay; 112 fathoms. This is a very distinct form, well characterized by the pinnate arrangement of the branches, the arrangement of the hydrothece, and by the structure and arrangement of the gonangia. Thuiaria cylindrica, sp. nov. Plate xvi., fig. 57. Trophosome. Hydrocaulus erect, simple, stout, gradually taper- ing from the distal end to the base, divided by oblique joints into internodes of very variable length, three or four annulations at 1876. ] NATURAL SCIENCES OF PHILADELPHIA. 227 the base, regularly branched ; branches cylindrical or polygonal, arranged alternately, bearing from one to three branchlets near the base which are of equal size and nearly equal length with the branches, or unbranched; constricted at the base; occasionally a large branch occurs which resembles the main stem in every par- ticular. Hydrothece tubular, entirely immersed, tapering at the distal end, curved slightly outwards, aperture oval, those upon the stem are arranged in two opposite rows on the same sides with the branches, three between each two branches; those upon the branches and branchlets are in regular rows of from four to six innumber. Gonosome. Gonangia unknown. ~ Height of largest specimen 130 mm. Hab. Port Moller, Aliaska Peninsula; 5 to 17 fathoms, sand, August. Hagmeister Island, Bering Sea; beach. Chirikoff Island ; beach. Chiachi Islands; 8 to 15 fathoms, gravel. There is considerable variation in the mode of growth of this species. The largest specimen has a straight stem with short pinnate branches, not over half an inch (13 mm.) long, and _ bear- ing but few very short branchlets. Another specimen has a twisted stem, giving a very graceful, spiral form to the colony; and four or five of the specimens in which the branches bear long spreading branchlets have a stout plumose form as if the branches orignated from all sides of the stem. Thuiaria robusta, sp. nov. Plate xv., figs. 53, 54, 55. Trophosome. Hydrocaulus simple, erect, slender at the base, gradually increasing in size to the distal end, divided by trans- verse joints into internodes of uniform size, a few annulations at the base, regularly branched; branches short, spreading, curving outwards and downwards, springing from all sides of the stem, one to each internode, bearing four or five branehlets, internodes of unequal size; branchlets few, short and diverging at a wide angle. Hydrothece vary greatly in form, those upon the branch- lets and extremities of the branches curve quite strongly out- wards, may be immersed up to the aperture in the stem, or the distal third may be free, aperture large, bi-labiate, with the broad side towards the stem; those upon the median portions of the branches are long, completely immersed, aperture smaller and not as distinctly bi-labiate as those upon the branchlets; those upon the proximal portion of the branches are shorter than the others, much smaller, aperture large, slightly bi-labiate with a singular 228 PROCEEDINGS OF THE ACADEMY OF [1876. process of the perisare in the shape of a two-pointed pyramid at the base of each hydrotheca; all the hydrothecz upon the branches and branchlets are arranged sub-alternately ; those upon the main stem are similar to those of the proximal portions of the branches, usually two to each internode which are placed about opposite to each other, occasionally a third one occurs in the axil of the branch. The perisarc is unusually thick, and especially so in the basal third of the hydrocaulus where the diameter of the cavity of the coenosarc is not more than a third of that of the stem. Gonosome. Gonangia largest at distal end tapering to the base, sessile, about twice the length of the hydrothecz, not including the horns, armed with two stout, cylindrical, truncate horns placed on opposite sides of the aperture near the distal end, aperture terminal, discoidal. Hab. Sea Horse Islands, Arctic Ocean; 23 fathoms, mud and gravel. Hagmeister Island, Bering Sea; beach. Cape Prince of Wales, Arctic Ocean; mud. Bering Sea, 12 miles east of King’s Island; 17 fathoms, mud. Thuiaria plumosa, sp. nov. Plate xvi., fig. 62. Trophosome. Hydrocaulus simple, erect, very slender at the base, increasing in size to the distal end, somewhat twisted, jointed transversely, internodes of the proximal portion of very unequal length, some being three times the length of others, those of the upper portion are quite uniform, regularly branched; branches short, arranged alternately, one to each internode, but owing to the twist in the stem take on a spiral form, the upper- most erect, lying close to the stem, the lower ones curve out- wards, attached to the stem by a very prominent process, bearing a few branchlets, regularly jointed; branchlets do not extend beyond the ends of the branches, and lie close to the latter. Hydrothece largest at the base, tapering slightly outwards, en- tirely immersed, aperture towards the stem, the outer side pro- duced, rim ornamented with two large teeth placed on the outer side, two tooth-like processes of the perisare also occur in the base of each hydrotheca, arranged subalternately upon the branches and branchlets ; upon the stem there are three to each internode, two placed opposite to each other, and one in the axil of the branch. Gonosome. Gonangia sessile, very long and nar- row, tapering gradually to the base, ornamented with two short 1876. ] NATURAL SCIENCES OF PHILADELPHIA. 229 horns placed on opposite sides of the orifice near the distal end, orifice terminal large; borne in single rows on the upper side of the branches and branchlets. Height of largest specimen, 40 mm. Hab. Bering Sea, 5 miles southwest of the west cape of Nuni- vak Island; 30 fathoms, sand. Icy Cape, Arctic Ocean; 15 fathoms, sand. In general appearance this species cannot be distinguished from Sertularia thuiarioides, and even in some of the details of struc- ture they bear a very close resemblance to each other; the best distinguishing characteristic in the trophosomes is the form of the aperture in the hydrothece, and in the gonosome the size and relative proportions of the gonangia. The twist in the stem and the erect position of the branches give to this species a very graceful mode of growth, which bears a striking resemblance to a feather. Thuiaria turgida, sp. nov. Plate xvi., figs. 58 to 61. Trophosome. Hydrocaulus simple, erect, stout, straight or slightly flexuous, of nearly uniform size throughout, joints oblique, internodes short, of equal size, annulated at the base, the lower portion without branches, the upper or distal part regularly branched; branches broad, short, arranged alternately, one to each internode, constricted at the base, attached to quite a promi- nent process from the stem, with one annulation, divided by trans- verse joints into internodes of variable length, sparingly branched ; branchlets diverging from the branches at a wide angle, usually curving towards each other. Hydrothece large, tubular, deeply immersed in the stem, curving slightly outwards, aperture large, rim entire, arranged oppositely on the branches and branchlets ; on the upper portion of the stem there are three to each inter- node, a pair opposite to each other, and one odd one in the’ axil of the branch; on the lower part of the stem there are two to each internode. Gonosome. Gonangia large, swollen, sessile, with three to five stout, longitudinal ridges, orifice terminal, small, discoidal; arranged in two closely set rows on the upper portion of the main stem. Height of largest specimen, 140 mm. Hab. Port Etches; 5 to 8 fathoms, gravel and stones, May 30. Popoff Straits, Shumagin Islands; near edge of reef in 6 fathoms, July. Semidi Islands; 15 to 28 fathoms, gravel, June 10. Coal 230 PROCEEDINGS OF THE ACADEMY OF [1876. Harbor, Shumagin Islands; beach. Hider village, Unalashka; 25 to 30 fathoms, sandy mud, June 4. Hagmeister Island, beach. Unalashka; 6 fathoms, Nov. 11. Kyska Harbor, Aleutian Islands. Lituya Bay; 9 fathoms, sandy mud. Akutan Pass, near Una- lashka. St. Paul Island (Pribiloff group); 9 fathoms, in kelp, July 24. Middleton Island; 12 fathoms, gravel, June 2. This species is one of the most abundant in the collection. It is a showy form, and has quite a stout appearance, owing to the width of the branches and stem throughout, and the large gono- thecee forming a double, close-set row along the distal third of the stem add not a little to its showiness. Thuiaria gigantea, sp. nov. Plate xvi., figs. 63, 64. Trophosome. Hydrocaulus simple, erect, rooted by a creeping stolon, stout, straight, divided by transverse joints into inter- nodes of variable length, much and quite regularly branched ; branches suberect, short, stout, usually unjointed, seldom branched all in one plane, arranged alternately on opposite sides of the stem from within an inch of the base to the very tip, constricted at the base. Hydrothece large, deeply immersed, curving outwards, orifice large, somewhat elliptical, arranged subalternately upon the stems and branches. Gonosome. Gonangia borne in two rows on the upper sides of the branches and branchlets, usually occur- ring towards the distal ends of the stems, sessile, obovate, with an irregular outline, orifice terminal, large, discoidal. Height of largest specimen, 165 mm. Hab. St. Paul Island, Bering Sea. Hagmeister Island; beach. Akutan Pass, near Unalashka. Kyska Harbor; 10 fathoms, rocky, July 15. The finest specimens consist of a dense cluster of about 350 shoots, averaging six inches in length, attached to a large barna- cle; it is much the largest single specimen in the collection, con- taining just about one million individuals, exclusive of the repro- ductive zooids, and it can just be crowded into a two-quart jar. The conditions for the existence of life must be very favorable where such a luxuriant growth as this is obtained from a root- stock that covers only a piece of an old barnacle shell. Macrorhyuchia Dallii, sp. nov. Plate xi., figs. 18, 19, 20. Trophosome. Hydrocaulus erect, compound, very stout, black, straight or gracefully curved at the distal end, not divided by 1876.] NATURAL SCIENCES OF PHILADELPHIA. 231 joints, the lower portion sometimes as much as the lower third, bearing no pinne, but give origin to two or three branches which often equal the main stem in size, and resemble the latter in every particular, the upper portion bears a double row of closely set pinnz. Pinne arranged alternately on opposite sides of the stem and branches, gracefully curved, more or less, towards each other, giving off near their origin from one to three branches, which are exact copies of the main pinnee, equal the latter in length, and lie so closely upon each other, that they are not noticed in a casual glance; both the pinnz and their branches are divided by trans- verse joints into short internodes. Hydrothece arranged uniserially upon the pinne and their branches, one to each internode, narrowest at the base, rim entire and slightly flaring. Nematophores simple, very large, the distal portion free, semicylindrical, very broad, one on either side and at the upper edge of the hydrothece, facing inwards, one just below each hydrotheca, and on the main pinne, sometimes two, one directly below the other, there are also two or three near the base of the gonangia irregularly arranged. Gonosome. Gonangia very large, quite regularly cylindrical, tapering at the base, sessile, mouth discoidal and the full size of the gonangia, rim entire; scattered over the pinne and their branches. Height of finest specimen 225 mm. Width of largest hydro- caulus at base5 mm. Length of largest gonangium 4 mm. Hab. Unalashka; beach. Akutan Pass, near Unalashka; beach. This is one of the largest, stoutest, and by far the showiest and most elegant species in the collection, and I take pleasure in naming it after Mr. Dall, through whose untiring labor and skilful care this fine collection has been made, and kept in a good state of preservation. In the mode of growth and external characters this species has all the appearances of a true Aglaophenia, and the large cylindrical gonangia partially hidden by the dark-colored pinne are readily mistaken for corbute. ATHECATA. Tubularia borealis, sp. nov. Trophosome. Hydrocaulus simple, erect, slightly annulated or twisted at the base, largest at the distal end and tapering gradu- ally to the base, smooth, not forming a collar-like expansion below 232 PROCEEDINGS OF THE ACADEMY OF [1876. the hydranth, light straw-color. Hydranths large, drooping; proxi- mal tentacles thirty to thirty-two in number, arranged in a single verticil ; when expanded forming a circle with a diameter of twenty to twenty-four mm.; distal tentacles fifty to sixty, arranged in a double row so closely as to form a single verticil. Gonosome. Gonophores oviform with four crest-shaped, laterally compressed, tentaculiform processes, arranged in pendant racemes of six to nine in number, which, when mature, are twice the length of the hydranth, and bear from thirty to seventy sporosacs each. No radiating canals are discernible in these alcoholic specimens, yet they may exist. Length of stem 60 mm. Hab. Hagmeister Island; beach, low-water. In general appearance this species bears quite a close resem- blance to Tubularia indivisa; the light-yellow, stout stems, and the large heads of both would hardly fail to mislead one at a casual glance. If there really are no gastrovascular canals in the sporosacs this form belongs in the sub-genus Parypha of Agassiz, but if the canals are present it makes it a still more interesting form, it then being intermediate between the sub-genera Tubularia proper of Agassiz, and Parypha of Agassiz. Tubularia indivisa, Linne. A number of very characteristic specimens of this widely-dis- tributed species have been received from Alaska. The stems are very much interlaced, and many younger ones have attached themselves to older stems, thereby producing a branched appear- ance. Where the young stems have become closely twined about the older ones, it gives to the latter an appearance like that of the large confluent stem of Halecitum muricatum. Hab. St. Michael’s, Norton Sound; collected by Mr. L. M. Turner, who describes them as very abundant in small pools left by extreme low tides. | Eudendrium pygmezum, sp. nov. Trophosome. Hydrocaulus simple, erect, stout, rooted by a creeping stolon, annulated throughout, irregularly branched ; branches erect, and bearing but few branchlets. Hydranths large, the stout tentacles, which vary in number from sixteen to twenty, are arranged in a single verticil. Gonosome. Sporosacs arranged in crowded rows beneath the tentacles, nearly spherical or pointed 1876.] NATURAL SCIENCES OF PHILADELPHIA. 233 at the distal end, and from thirty to forty-five or even fifty in a cluster. Height of specimen 20 mm. Hab. Akutan Pass, near Unalashka. This is a short, stout form, of a blackish-brown color at the base, becoming lighter towards the distal ends of the branches. It resembles the dried stems of a Eudendrium that occurs at Santa Cruz, California, in being annulated throughout, and may prove to be identical. Nov. Fam. (?) RHIZONEMIDA, S. F. Clark. Polypites attached by numerous thread-like fibres. Tentacule apparently of two kinds; the inner verticil of aboral tentacles branched. Nov. Genus RHIZONEMA, Clark. Polypes solitary, unconnected. Basal portion of the polypite swollen, mammillate, with the thread-like processes for attach- ment developed therefrom. Type Rhizonema carnea, sp. nov. Stems stout, unbranched, smallest at the distal end; of a nearly uniform size for two-thirds of the distance toward the base, at which point they begin to increase in diameter rapidly to twice the diameter of the distal end, then taper rapidiy to quite a sharp point like an acorn. The processes for attachment are de- veloped in large numbers (hundreds) from the basal surface of the enlarged portion of the stem. They are of a light-brown color, and form a matted mass which extends beyond the sharp-pointed base. The polype is large and turgid; its length much greater than its width. The aboral tentacles are about forty in number, very slender and delicate, reaching a trifle beyond the end of the proboscis. Just within these tentacles is situated another circle of processes, the exact nature of which can be determined only from fresh specimens. The proboscis is very large and swollen, and bears around its distal end the proboscidial tentacles, which are as delicate as the finest thread, very numerous, and so matted together in the speci- men before me that it is impossible to form any correct estimate of their number. The mouth, situated at the extremity of the 16 234 PROCEEDINGS OF THE ACADEMY OF [1876. proboscis, is very large. Length of head, 13 mm. Length of swollen basal portion, 21 mm. Total length of perfect specimen, 68 mm. The specimens from which the above description was written were collected at St. Michael’s, Norton Sound, Alaska, Oct. 17, 1875, by Mr. Lucien M. Turner, U. S. Signal Service, who appends the following note: ‘*These specimens were of a deep coral red when found. They are not common. From the sea.” They are two in number, one of which is perfect—the other is without a head, but bears at the distal end a thin chitinous mem- brane surrounding the stem; its edges recurved and marked with a few faint radiating lines. From the appearance of the individual, [ am of the opinion that the head had been thrown off, and that another was about to be developed. The matted masses of delicate fibres about the basal portion present a very peculiar appearance. When cleared away so as to expose the pointed basal end of the stem, that part has a close resemblance in miniature to a beet-root with an unusual number of fibrous rootlets. Under the microscope, each fibrous process appears to be de- veloped from a small rounded papilla; some papille which bore no fibres exhibited an opaque milk-white nucleus. The nature and development of these processes is a matter of considerable interest, but I think that little could be done even with a large supply of only alcoholic specimens. The nature of the inner verticil of aboral tentacles (7) is also a very interesting question. From their position, and from their compound appearance, they would naturally appear to be clusters of reproductive bodies. On the other hand, the alcoholic specimens under the microscope do not show the structure characteristic of such bodies. They appear to be thin, flattened, branched tentacles, and have no swelled or thickened portions such as would indicate anything like repro- ductive organs. It is, of course, impossible to determine their nature positively without further material. This is certainly a very peculiar and very interesting form, on account of its peculiarly shaped base, its apparently compound tentacule, and the thread-like processes for attachment, which seem, on account of the pointed base, to be necessary for its secure anchorage. 1876. ] NATURAL SCIENCES OF PHILADELPHIA. 235 OrpER LUCERNARIZA, Family ELEUTHEROCARPID A, H. J. Clark. Ealyclystus auricula, H. J. Clark. Twenty or thirty good specimens of this interesting form have been collected at St. Michael’s. They are in good preservation, and represent various stages of development. In some of the larger specimens the ovaries are very far advanced, much en- larged, nearly filling the entire cavity, and greatly distending the body walls. In others the ovaries show no enlargement, and between these two conditions all intermediate stages are repre- sented. The color is light brown, with a bluish tinge, which becomes darker with the development of the ovaries. Three of the speci- mens have ten arms and three have twelve, showing a marked tendency to variation in this respect. Geographical distribution: St. Michael’s, Norton Sound, Alaska; Mr. L. M. Turner, Oct. 17,1875. Vardée Islands, Norway ; Rathke. Faroe Islands; Steenstrup. English coast; Montague, Fleming, Johnston, and others. South coast of Greenland; Steenstrup. Anticosti; Hyatt, Verrill,and Shaler. Massachusetts Bay; H. J. Clark. EXPLANATION OF PLATES. The figures on plates vii. to xi., inclusive, are enlarged 30 diameters, with the exception of, Nos. 16, 19e and 19g; the extent to which the latter are magnified is indicated on the plates. The figures on plates xii. to xvi., inclusive, are magnified 20 diameters, with the exception of No. 33, which is enlarged 7 diameters. Puate VII. Fig. 1. Gonothyrea hyalina; a, hydrothece; 6, gonangium; ec, extra-capsular medusoids with tentacles ; d, ccenosarc, or fleshy axis. Fig. 2. The same; portion of a branch, showing the arrangement of the hydrothece. 236 PROCEEDINGS OF THE ACADEMY OF [1876. Fig. 3. Campanularia circula ; showing, a, hydrotheca ; 6, main stem, and the verticillate arrangement of the pedicels around the stem. Fig. 4. Campanularia denticulata ; the hydrothecz, showing the variation in shape and size. Specimen from Port Ktches; creeping on Lafoéa. PuiateE VIII. Fig. 5. Campanularia compressa; a, gonangium; r, rootstock or creeping stem. Fig. 6. The same; showing the variation in size and form of the hydrothece. Fig. 7. Campanularia urceolata ; a, hydrothece ; 6, gonangium. Fig. 8. Campanularia turgida ; a, hydrotheca; 6, gonangium; 7, rootstock. PLATE IX. Fig. 9. Campanularia integra ; showing the variation in the hy- drothece. Fig. 10. The same; }, gonangium; 7, rootstock. Fig. 11. Campanularia speciosa; a, hydrothece; 1, rootstock, or creeping stem. Fig. 12. Clytia Johnstoni ; showing the variations in the stems and hydrothece. PLATE X. Fig. 13. Halecium scutum ; a, hydrothece ; b, gonangia; c, ova; d, aperture of gonangia. Fig. 14. The same; a, portion of a branch; 6, portion of main stem. Fig. 15. Haleciwm muricatum ; gonangium. Fig. 16. Halecium plumularioides; a, portion of a branch; 8, portion of main stem; c, hydrothece. Fig. 17. The same; a, branch; b, main stem; 7, rootstock. PLATE XI. Fig. 18. Macrorhynchia Dallii ; b, main stem ; a, pinne; c, hydro- thecze; d, nematophores. Fig. 19. The same; e, a cross section of main stem near the base ; g, gonangium ; the other letters as in fig. 18. 1876. ] NATURAL SCIENCES OF PHILADELPHIA. 237 ig. 20. The same; the letters as before. Fig. 21. Lafoéa secant? 2; a, hydrothece ; 7, rootstock. PiLate XII. Fig. 22. Lafoéa fruticosa; a branch with hydrothece. Shuma- gin Islands, 6 to 20 fathoms. Fig. 23. Lafoea dumosa; a, main stem; 6, hydrothece. Fig. 24. Lafoéa gracillima; a, main stem; b, hydrothece. Fig. 25. Calycella syringa; a, hydrothece; 6b, opercula; 7, root- stock. Fig. 26. Sertularella tricuspidata; slender variety, from the Semidi Islands. Fig. 27. The same; stout variety, also from the Semidi Islands. c=) Fig. 28. Sertularella pinnata ; portion of a branch. Fig. 29. The same; a, portion of a branch; b, gonangium ; 3, inter- nal chamber. Fig. 30. Sertularia filicula ; a, main stem; b, branches. PLATE XIII. Fig. 31. Sertularella rugosa; portion of a branch with hydro- theese, from the Shumagin Islands. Fig. 32. Sertularella robusta; portion of a branch; a, hydrothece ; b, opercula. Fig. 33. The same; gonangium. Fig. 34. Sertularella polyzonias; a, hydrothece. Fig. 35. The same; gonangium; 7, rootstock. Fig. 36. Diphasia erebatee portion of a branch. Fig. 37. Sertularia cupressoides; a, portion of a branch; b, por- tion of main stem. Fig. 38. Sertularia thuiarioides; a, gonangia; b, portions of branches. Fig. 39. The same; a, portion of a branch ; b, gonangium. Prave XIV. Fig. 40. Sertularia variabilis; portion of a branch. Fig. 41. The same; a stouter form. Fig. 42. The same; a form in which the hydrothece are more elongated. Fig. 43. The same; a slender form in which the hydrothece are arranged more in pairs; a, the apertures where the gonangia were attached. 238 PROCEEDINGS OF THE ACADEMY OF [1876. Fig. 44. The same; a, portion of a branch; g, gonangia from same colony. Fig. 45. The same; a stouter form, in which ‘the hydrothece are quite divergent. Fig. 46. The same; the stoutest of the many varieties; the three pairs of hydrothece are all from the same branch. Fig. 47. The same; gonangia. Fig. 48. The same; still another form, the divergent characters of which are not constant; not even in different portions of the same colony. PLATE XV. Fig. 49. Sertularia variabilis; the three pairs of hydrothece are all from the same stem. Fig. 50. The same; the most extreme of the many forms. Fig. 51. Sertularia inconstans; three gonangia which grew next to each other, showing how variable they are. Fig. 52. The same; portion of a branch. Fig. 53. Thuiaria robusta; a, portion of main stem, showing the thickness of the perisare or chitinous walls; b, side view of basal portion of a branch; c¢, side view of portion of stem. Fig. 54. The same; d and e, portions of branches. Fig. 55. The same; gonangia. Fig. 56. Sertularia similis; portion of a branch. PLATE XVI. Fig. 57. Thuiaria cylindrica; showing the unusual arrangement of the hydrothecz and the mode of branching. Fig. 58. Thuiaria turgida; gonangium. Fig. 59. The same; portion of a branch and branchlet. Fig. 60. The same; portion of main stem. Fig. 61. The same; portion of a branch. Fig. 62. Thuiaria plumosa; b, portion of a branch; g, gonangia. Fig. 68. Thuiaria gigantea; a side view of main stem; 6, gonan- gia; c, hydrothece. Fig. 64. The same; portion of a branch. 1876.] NATURAL SCIENCES OF PHILADELPHIA. 239 ON THE EXTRUSION OF THE SEMINAL PRODUCTS IN LIMPETS, WITH SOME REMARKS ON THE PHYLLOGENY OF THE DOCOGLOSSA. BY W. H. DALL, SMITHSONIAN INSTITUTION. In a paper published in the American Journal of Conchology, Part III., 1871, I brought together a summary of the various details published from time to time by various naturalists, upon the an- atomy and physiology of this group. In that paper it was shown that the manner in which the seminal products were freed from the ovary and testis, and the passage by which they reached the exterior, was unknown, and from the investigations of Lankester and myself, that the existence of the oviduct figured by Cuvier (Mém. sur les Moll., 15, 1817), if not actually disproved, was at least a matter of grave doubt, and had not been confirmed by any subsequent examination. Lankester (Ann. Mag., N. H., xx. p. 334, 1867) had suggested that the passage of the ova to the ex- terior was made through two orifices first described by him and termed “capitopedal orifices.” These were said to open, “one on each side of the head in the angle formed by its junction with the muscular foot, and (internally) opening into the blood sinus surrounding the pharyngeal viscera.” He also described an open- ing communicating between the “pericardium and the supra-anal articulated sac,’’ or accessory renal organ. The latter I have never been able to demonstrate to my own satisfaction, but I do not assume to dispute its possible existence. In the brief notice of his work published by Mr. Lankester, which has not been fol- lowed by any more detailed communication, the terms used were somewhat misleading, or at least not clear. Instead of opening externally in the angle formed by the head and the foot, the “capitopedal orifices,’ if I have correctly identified them, are situated on the back of the neck, so to speak, or more properly on the transverse portion of the integument above the head and in front of the main pericardial chamber in the angle formed by the neck and the inferior surface of the mantle over the head. Mr. Lankester found them in Patella vulgata, but I have never been able to detect them in the few alcoholic specimens of that species which I have been able to examine. In fresh specimens of Acmeza patina and testudinalis, I have generally been able to 240 A PROCEEDINGS OF THE ACADEMY OF [1876. find them, and in the living animal they are of an orange color. In Ancistromesus mexicanus, they are quite prominent in some cases and almost imperceptible in others. They also differ in character. In Ancistromesus (one of the Patellidz), they appear as true orifices, in the acmeeas they present the appearance of an elongate, narrow, glandular mass, from which, internally, q duct is not always traceable. In some individuals they appear entirely absent or abortive. My own opinion of their function is, that they are aquiferous pores, such as are common to many mollusks, | through which water passes into the circulation directly in the Patellide and by a process of straining through the glandular mass in the Acmeidxe. Whatever their office, it can hardly be of fundamental importance, or they would not be so frequently found in an abortive condition. Whether in some cases they may be indirectly in communication with the renal sac is of little conse- quence, as, in the paper alluded to, I have shown that in some genera the pericardium is so situated that there can hardly be any such communication, and in so homogeneous a group as the limpets it is unlikely that such an anatomical character, if important, should be inconstant. Moreover, through the intricate channels alluded to, the ova which are of considerable size could hardly be propelled without some special muscular arrangement which does not seem to be present in any case examined. Anxious to set at rest a question of so much interest, and which for so many years had puzzled anatomists, I have lost no opportunity of dissecting animals of this group, especially the large species in which the characters might be supposed to be more evident. The opacity of the shell and the impossibility of getting at even the external orifices of the viscera without destroying the life of the individual, proved effectual obstacles to the study of these functions in the living animal. While in the field, from 1871 to 1874 inclusive, I made dissections of many hundreds of acmeeas with no definite result, except that of finding that the sexual products appeared ripe in only a small portion of the ovary at any one time, and in the acmeas the portion most usually in that condition was the ex- treme right hand part of the anterior end, immediately below the floor of the larger renal sac. No oviduct or opening was in any case demonstrated. Somewhat discouraged by repeated failure, on leaving the field- 1876. ] NATURAL SCIENCES OF PHILADELPHIA. 241 work in which I had been engaged, the matter was deferred until a better opportunity should arise. Some time since, a large number of specimens of the giant limpet of Central America, Ancistromesus mexicanus, were obtained by the Museum of Com- parative Zoology from the naturalists of the Hassler Expedition. By the courtesy of Prof. Alex. Agassiz a number of these were turned over to me for dissection. In this species the right supra-renal sac is quite large, covering ‘the entire superior surface of the animal between the muscular attachments. The viscera are coiled below it in the usual manner, except that in ripe individuals the upper outer edge of the ovary or testis extends rather more beyond the peripheral coil of the intestine than in most species. A section then discloses the mem- branes in the following order from above. First, the external delicate layer of the mantle covering every- thing else, and very intimately bound together by tough connec- tive tissue with, Second, the superior wall of the right hand (and only fully developed) renal sac. By means of delicate, but tough columnar walls of tissue, forming connected cellular cavities, overlaid with semi-glandular tissue for the elimination of the renal secretions, the upper wall of this sac is connected with, Third, the floor of the sac, of similar constitution and tough- ness. The two are readily separated owing to the greater delicacy of the connecting tissues, but the upper wall and the mantle, and the lower wall and the tissues below it, are very intimately con- nected by membranous fibres of such toughness as to render their separation without injury very difficult. A muscular band or mesentery of considerable strength, having, in the specimens of Ancistromesus examined, a width equal to nearly one-twenty-fifth of its length; extends completely around the internal viscera which are compactly bound together by similar tissue. From the floor of the renal sac similar but short mesenteric bands extend downward to the peripheral band, radiating from the apex of the shell, and having, when in their natural position, a somewhat triangular form; the short sides of the triangles cor- responding to the distal ends of the radii, and their plane surfaces being nearly vertical to the horizontal plane of the visceral mass. In the specimen under consideration there were one posterior and 242 PROCEEDINGS OF THE ACADEMY OF [1876. ten lateral bands of this nature, five on each side. In details of form and dimensions these vary in different individuals. They widen at their junction with the tissues above and below, and send off numerous fibres in all directions, and especially to the peripheral band. We thus have as it were the entire visceral mass suspended in the perivisceral cavity, free of the floor and sides of the latter (except a delicate anchoring membrane, lying vertically in the median line and connecting the median line of the visceral mass with that of the muscles of the foot), but in contact or close con- nection with its roof which is composed of the floor of the larger renal sac. This sac opens externally by a prominent papilla to the right of the anal papilla, while the smaller (and usually almost abortive) left renal sac, opens by a BEOpOE one smaller papilla to the left of the anal. The specimens were examined by cutting away the solid mus- cular foot, and thus exposing the perivisceral cavity without in any way lacerating its contents, sides, or upper surface. A number of individuals were dissected without coming any nearer to the object in view. At last, however, a specimen was taken up which appeared to solve the difficulties and afford the long sought for explanation. It wasamale. The surface of the viscera with one exception was perfectly normal. On the right-hand posterior portion of the periphery of the testis, covered with its usual delicate invest- ing membrane, for the space of an inch from the posterior end of the median line, forward, the ducts were swollen and enlarged. They projected in a marked manner from the smooth and evenly rounded normal surface, like ‘‘ varicose veins,” except that the ducts are nearly parallel. In the ripest portions the delicate investing membrane of the testis had become ruptured or perforated, and the seminal matter exuding from these punctures had been solidi- fied by the alcohol in little rounded grains or particles, which had not been disturbed by the careful manipulation of dissection. At those points where the congested or enlarged ducts were in mechanical contact with the roof of the perivisceral cavity, that is to say, the floor of the renal sac, numerous minute, but plainly visible, oval perforations appeared. These were oblique to the general plane of the membrane, the opening on the side adjacent to the testis being usually directed somewhat backward instead of vertically downward. They had also something of a funnel shape, being larger on the side toward the testis, and some of them 1876.] NATURAL SCIENCES OF PHILADELPHIA. 243 were twice as large as others. The largest had a diameter of .015 in., and would admit the passage of a fine bristle into the renal sac. On applying slight pressure from above, the fluids con- tained in the renal sac passed through in a minute jet. They were irregularly distributed, corresponding in locality to the ripeness of the ducts of the testis. Except where the testis in its ripe condition was in immediate proximity or actual contact with the membranes of the renal sac, no such orifices or pores were to be found. In the other specimens in which the testis or ovary showed none of these signs of maturity, no such orifices could be detected. The membranes in such cases presented a smooth and practically impervious surface in every part. It would seem as if these facts gave a final solution to the diffi- culty as follows :— When the ovary or testis is ready to discharge its products, that portion of it which is ripe evinces its condition by an en- largement of the ducts, continuing until dehiscence takes place. Coincidently, the superincumbent membranes of the renal sac (whether by sympathy with the congestion of the seminal organ or otherwise) become lax and perforations make their appearance immediately adjacent to the dehiscent ducts. Through these orifices the seminal products make their way. A contraction of the pedal muscles would be sufficient to cause the ejection. After reaching the renal sac, the question of the extrusion of the ova or semen presents no difficulties. The same agency which empties the sac of its secretions through the renal papilla would suffice to eject the seminal products, which floating in the water would cause the fertilization of the ova as in the case of Chiton. The rarity of individuals in a ripe condition in collections may be due to their repairing below tide marks at such times, and hence avoiding the collector. The method above suggested is paralleled in numerous other in- vertebrates, and even some fishes, with non-essential differences of detail. The specimen referred to has been submitted to several naturalists who agree as to the facts. While additional evidence is desirable in corroboration, I feel tolerably confident of the correctness of the inferences drawn from the above facts, which furnish an explanation at once simple and in accordance with experience in other cases, of a very puzzling question. 244 PROCEEDINGS OF THE ACADEMY OF [1876. I may add, that the localized turgidity or swelling of the ripe seminal ducts had been previously observed by me on other occa- sions among specimens of Acmzxa patina; but having dissected them in most cases from above, removing the membranes not con- nected by tissue with the ovary, and looking more particularly for a permanent duct or passage, the perforations of the renal mem- branes were likely to, and did, entirely escape my notice. Additional notes on the genera of Limpets.—In the paper before referred to, I was unable, for want of material, to obtain data in relation to the dentition of the typical species of Helcion and Scurria. The former I have lately obtained from a dry specimen kindly communicated by Dr. Carpenter, and Mr. 8. A. L. Brannan, of San Francisco presented me with an alcoholic specimen of Scurria scurra obtained by him at Valparaiso. The result of an examination of the two forms shows that Helcion has the dentition of the typical Pafelle such as P. vul- gata, except that the third or outer cusp of the third lateral tooth is obsolete. The gills are interrupted over the head as in Helcio- niscus, from which it is sufficiently distinguished by the dentition. Scurria scurra agrees in all essentials of branchiz and denti- tion with Scurria mesoleuca described by me as above, so that no change of the arrangement I then adopted is necessary. A careful examination of the soft parts and dentition of some of the typical scutellinas is still a desideratum. Having now nearly complete data in regard to the principal groups of the Docoglossa, a few observations may be permitted on the relations of the different subordinate groups. I will pre- mise, that, for reasons which I hope in a short period to publish in extenso, I lave come to the conclusion that the northwest coast of America has been a great centre of distribution for molluscan species; or of forms which, as they migrated south or east from their original habitat, changed or added to their original char- acters, until at present they are termed nearly related rather than identical forms. In many eases their paths have become dry land, and the track must be followed rather by organic relations than contiguity in distribution. Were the foregoing views correct, we should look to find in this region—I1st, a maximum development of the lower or parent forms of Docoglossa; 2d, a local abund- ance and radiating distribution of the next higher genera; and lastly, in the nearest region where conditions of temperature, food, and station were most favorable (and the migrating organ- 1876. ] NATURAL SCIENCES OF PHILADELPHIA. 245 isms might be supposed to have been longer exposed to these favorable conditions than those subjected to the vicissitudes of more distant migration), we should expect to find instances where the group had reached its highest form of specialization. This is exactly the real state of the case. Whether we consider the dentition, the mechanism of respira- tion, or the development of special organs, or the total bulk of the organism, the Abranchiata are unquestionably the lowest forms of the order. Without eyes, branchiee, or lateral teeth, sluggish in their motions; relying on buccal tentacule and the cuticular nerv- ous system for outward impressions, and protected by the uniform conditions of their deep water station, they stand at the foot of the genealogical tree. In the Alaskan region they are represented by two or three species, which reach a larger size than any of their congeners. Pilidium and Lepeta have reached the east coast’ of America and the Hebrides; the latter only has penetrated to the Mediter- ranean if identifications of Italian naturalists are to be accepted. The rhachidian tooth, representing the type of a radula, and disproportionately developed when compared with the uncini in this group, may by natural selection have given place to the strong subequal ranks of laterals characteristic of the Acmeide, and the buccal tentacles, rendered unnecessary by the presence of eyes, dis- appeared, or are only represented by the smooth frill of the muzzle of Acmza drawn down to a corner, while in the remainder of the family they are totally absent. The development of the radula, of a cervical branchia, of eyes, and of general bulk, marks the progress of the group in the Acmezide. From uselessness the uncini become abortive. In the northwest American region, more than in all the world beside, is this group developed in species, in size, and in indi- viduals. Strong in the possession of their new organs, they have invaded the littoral zone, and only the smaller and weaker forms tarry in deep water. On the west they have, through favorable conditions, reached Japan, China, and south to Amboyna. On the south, their un- broken ranks stud the beaches from California to Tierra del Fuego, and thence north on the east coast of South America to Rio de Janeiro. The eastern barriers at the north are not so easily over- come, and Acmeza testudinalis and virginea have alone reached northern Europe. 246 PROCEEDINGS OF THE ACADEMY OF [1876, In the present state of our knowledge, it is easy to trace the steps of development. Greater knowledge would doubtless in- crease the complications. In the warm waters of California Lottia grandis, having reached an enormous size, is also enabled to develop an incomplete bran- chial cordon in addition to its cervical plume. Further south Scurria completes the cordon and apparently reaches the highest stage of development short of a rejection of useless parts. This soon occurs in the disappearance of the cer- vical plume, whose oflice is abundantly filled by the development of the cordon. This brings us to the Patellidz. Here the devel- opment of the radula has so far progressed that its median line, in the highest type of the family, is now supplied with a rhachi- dian tooth of properly proportioned size, and the abortive uncini of the Acmexidx have given place to teeth which are capable of fulfilling a useful purpose. At the same time,.the plain muzzle frill of Acmza is replaced by a crop of arborescent tactile papilla, and in Ancistromesus, the highest development of total bulk known to the order, is added to the greatest known specialization of the other characters. This occurs on the Mexican coast in the direct line of migration from the northwest coast. So far as we yet know, the representa- tives of this family in more distant regions have not yet rivalled it in development. All want the median tooth; the other char- acters, but with much smaller bulk, are developed in Patella vulgata of Europe and some Indian species. Patina cannot complete its cordon, inhabiting the British Isles. Nacella, an equally distant traveller, in Patagonia, barely completes its cordon, while its asso- ciate, Patinella, is more successful, and both sport a frill around the foot. Helcion and Helcioniscus of the African coasts, have the cordon interrupted, and the dentition is less uniform and effective than in Ancistromesus, which, however, they resemble in dispensing with the foot frill. In the rich Indo-Pacific region it seems probable that the higher types prevail more abundantly, and there is reason to believe that Scutellina is a weakly offshoot from the acmean stem. Without verging greatly on the speculative, we may construct a genealogical tree, which cannot greatly differ from the following scheme :— 1876.] NATURAL SCIENCES OF PHILADELPHIA. NorrTH. Lepetide tt bse Cryptobranchia Lepeta ee Pilidium Acmeidse \ WEST a BN A Collisella Acmea eb Lottia Collisellina E Scurria. Scutellina ? Patellide. Patella 5a Pa Nacella Patina a | ans Patinella Helcion Helcioniscus Ancistromesus East 248 PROCEEDINGS OF THE ACADEMY OF [1876. DESCRIPTIONS OF SOME VERTEBRATE REMAINS FROM THE FORT UNION BEDS OF MONTANA. =? BY E. D. COPE. Se Os A Lavy, Aublysodon lateralis, sp. nov. _ Established on some teeth, one of which is of the size of those of the A. horridus, and which differ in some important particu- lars. The posterior crenate ridge is as in that species, lateral in position, separating a posterior face from the lateral ata right angle. The posterior face is separated from that of the other side by a very obtuse angle. The anterior aspect of the crown is without crenate cutting edge, but the latter is present as a border to the front, passing along the front of the side opposite to that which bears the posterior angle. It is directed laterally, and projects beyond an open groove which follows its posterior base. The base of the crown is broad elliptic in section. Enamel smooth. A much smaller tooth was found with the preceding, and pre- sented similar characters, excepting that the posterior face is not so strongly truncate. Measurements. M. Length of crown preserved : : b ; ; : 025 Diameter of base of crown { 10n8 ; 1 : 4 pe short . : : - .010 Width of posterior face ; : , 5 5 , : .006 Length of smaller crown . : : : ; : : O11 Long diameter of base of do... : : : 5 : .006 The apices of both crowns are considerably worn by use. Both were found by Charles H. Sternberg of my exploring party. Lelaps incrassatus, sp. nov. Represented by two teeth, a larger and a smaller, which were found near each other, but not sufficiently so as to warrant the belief that they pertain to the same individual. The characteristic feature of these teeth is, that the transverse diameter of the base of the crown exceeds its anteroposterior, a point in which it differs from all the other carnivorous dinosau- rians yet known from the formation. Nevertheless, the posterior cutting edge is median, and is denticulated. The anterior cutting edge, which is also denticulated, is nearly median at the apex, but 1876.] NATURAL SCIENCES OF PHILADELPHIA. 249 continues along one side of the widening anterior face to the base of the crown. The posterior cutting edge is nearly straight, while the anterior is rather abrubtly curved at the apex. The anterior and posterior edges are not lateral in position as in Aublysodon lateralis. Measurements. M. No.1 No. 2. Length of crown . : ; 5 = : F 025 .014 Mamcioeat tase { antero-posterior . : - .012 .006 transverse : A : .0135 .008 A large species. Discovered by Jno. C. Isaac. Lelaps explanatus, sp. nov. An abundant species, but as yet represented only by teeth which are about the size of those of the largest of living Varanide. The crowns are strongly compressed and curved; one side is flat, the other gently convex; the posterior cutting edge is median and concave. The anterior edge is not continued to the base of the crown, and disappears before attaining the apex; it is feebly denticulate, and only at its convex curvature towards the apex ; its course is median. ‘The flat face has a slight bevei to the pos- terior edge. Surface smooth, without transverse undulations. Measurements. M. 2 : .0110 antero-posterior - ; 2 .0066 transverse 5 : 3 : .0028 Length of crown . : : a : - Diameter crown at base { Lelaps falculus, sp. nov. Represented by several teeth of about half the size of those of the last described reptile. They differ in form in several respects, being relatively shorter and stouter, and less sectorial in character. The lateral surfaces are about equally convex, while the anterior face is narrowly obtuse, and without cutting edge. The posterior edge is concave and furnished with a serration of smaller denticles than in the ZL. explanatus; it is median in position. Measurements. M. Length of crown : ; A - : 3 : .0090 Diameter of base of crown EI c :0UB8 transverse . b 2 . .0040 Found by Jno. C. Isaac. 17 250 PROCEEDINGS OF THE ACADEMY OF [1876. Dysganus encaustus, gen. et sp. nov. Char. Gen.—A large number of teeth exhibit the characters of this genus, which is a peculiar form of herbivorous Dinosauria. The crowns are compressed, so that the fore and aft diameter much exceeds the transverse. The body of the crown is a flattened shaft of dentine, one face of which is the denser, and produces the cutting edge. This face is flat or weakly keeled, while there are two other faces uniting at an open angle, thus giving a subtri- angular section. On each of these faces is adherent a shaft of cementum-like material of a dense character, whose external face is longitudinally concave. These inclose between them on the median line a deep groove, which expands below into a wide con- cavity, which appears to be enlarged as the age of the tooth in- creases preparatory to shedding. The other parts of the base of the crown below the cutting face, are inclosed in a rather thick deposit of rugose cementum, which rises a distance on the sides of the tooth. The method of replacement of the teeth in this genus appears to resemble that of Cionodon, except that there is no indication of the existence of as many series in the transverse direction. The longitudinal grooves in the anterior and posterior cement columns are probably occupied by the borders of the apices of successional teeth. The presence of these columns, etc, distinguishes this genus from that and other allied genera. Char. Specif.—The cutting face is more or less concave, and is impressed or sunken, its lateral borders, and the cement of the basis, projecting beyond it. The infericr border is also usually oblique, that of one of the sides rising diagonally. In the same proportion, a weak keel is also unsymmetrically placed, lying close to the opposite border, and dividing ‘the face into a wide and a narrow concavity. The oblique border is also incurved, the edge of the posterior cement column curving round the cutting face of the dentine. The latter is delicately rugose in unworn specimens. The external basal cementum rises highest on the incurved border of the crown; its surface is minutely rugose, the rugosity being generally punctiform. It is also of a different color from the dentine in the specimens as preserved, and is occasionally found nearly worn away. ‘The edge of unworn teeth is not serrate. 1876. ] NATURAL SCIENCES OF PHILADELPHIA. 251 Measurements. M. Length of basis of tooth . ° : - : ; Seotiek U1l2e Dj rat antero-posterior . : - Bo MUS) eer On crown ' transverse . - . - . 004 Transyerse diameter below crown . ‘ : : . .008 The teeth are rather smaller than those of Hadrosaurus foulket. The borders present no indication of the crenation seen in that and other species, either in worn or unworn specimens. Dysganus haydenianus, nov. sp. Represented by a number of teeth found in such relation that they are supposed to belong to two individuals. They differ materially in form from those of the D. encaustus, and exceed any of them in size. The base of the tooth possesses the thick investment of rough cementum, and has a slope away from the base of the crown. The form of the crown is peculiar in possessing a lateral face placed at a strong angle to the usual face, and separated from it by a strong protuberant angular ridge. This angular cutting face would resemble that of the Diclonii were it not that the body of dentine of which it is composed is a flat plate instead of a triangular seg- ment of a subquadrate prism. Each face has a separate plate, which is separated from the other by a suture. A solid mass fills the angle between them, which is divided by a groove produced by the pressure of the angle of the face of the succeeding tooth which fits it. The wider of the “front” faces is divided by a low longitudinal ridge. Both of the faces are bounded by an external incurved ridge which cause them to have a concave surface. A tooth of a size equal to that of the one just described was found with it, has a form more nearly like that of D. encaustus, in the less degree of prominence of the lateral angle. It displays but a single posterior cementum-like mass, which presents considerable lateral faces as well as a posterior one, as in the first described tooth. Measurements. M. Length of base of crown : : , ’ : =| 010 Elevation of remaining part of crown . : : . .006 ( antero-posterior . : r . O15 Diameter of crown 2 transverse, total . : : 2 010 ( es dentine ; } . 004 Dedicated to Doctor F. V. Hayden, U. 8. Geologist. 252 PROCEEDINGS OF THE ACADEMY OF [1876. Dysganus bicarinatus, sp. nov. This dinosaurian is represented in the collections by some of the teeth of three individuals. Two of the teeth represent immature stages, while the others are worn by continued use. They all present characters not found in the D. encaustus, from which they differ in a direction the opposite of that which characterizes the D. haydenianus. The crowns present a nearly flat face without incurved lateral angles, nor prominent median keel. The basis is wide, projects in a rim beyond the face, and is invested with rough cementum. ‘The face is peculiar in being divided into three planes by two low angular ridges, and its surface is smooth. The dentinal column is triangular, and there are two posterior columns separated by a fissure, in mature teeth. The absence of the lateral incurved angle, and the presence of the two median ones distinguish this species from the D. encaustus. Measurements. M. Length of basis : - : ; ‘ : : . .009 Width. «‘* : : : : ; ; : «fn Old Length of worn face ¢ : : : ‘ : . 006 : , antero-posterior . : - Oller Disuieter on erown ieee a. 6 C ; . s 200% Dysganus peiganus, sp. nov. In the typical tooth of this species the form approaches the genus Palzoscincus, Leidy, in the compression of the crown, and the contraction of the base; it is a limital species of Dysganus if really properly placed in that genus. The widest portion of the crown is above the base; from this expansion it contracts in both directions, and in the unworn tooth forms an angular median apex. This is not the case in D. encaustus, which is regularly rounded. The margin of the crown is narrowed, expanding but little towards the expansion, and is quite rugose. From these rugosities low ridges descend on the face of the tooth, whose surface is also minutely rugose. ‘The face is divided by a prominent median rib, which extends to the apex. No cementum is visible on the basis, in the only specimen in which this part is preserved. Measurements. M. Length of crown . : 4 ; : : : . .008 transverse. 2 ; ‘ so 8005 at base. =») O08 greatest . Bare)! iameter of crown : Dia chee {antero-posterior } 1876.] NATURAL SCIENCES OF PHILADELPHIA. 253 Diclonius pentagonus, gen. et sp. nov. Char. Gen.—Herbivorous dinosaurians, in which the teeth are elongate and without distinct root, and present dense material only on one side of the crown (the “ front”), whose section pro- duces a cutting edge. The other face of the tooth (the ‘ back’’) is coated with cementum, and is absorbed during the protru- sion of the successional tooth from below, which thus rises from “behind.” In the antero-posterior direction the teeth are pro- truded alternately, and the lower parts of the crowns are con- tracted to give space for the apices of the adjacent young teeth. In the type of the genus there is but a single series of teeth. In the known species of this genus, the dense face (“front’’) of the crown presents a longitudinal keel, but this is not necessarily a generic character. The terms “front” and “ back” are not in- tended to be accurate, as the faces so termed are either external or internal, the direction being probably reversed in the two jaws. This genus is allied to Hadrosaurus and Cionodon. From the former it differs in the mode of succession of the teeth, which, as determined by Prof. Leidy in that genus, is from the ‘ front” of the base of the tooth, whereas, in Diclonius, the succession is as in Cionodon, from the ‘posterior’ base of the tooth. This ar- rangement allows of a more continuous use of the dense face than in Hadrosaurus, where that face terminates as the young crown rises into functional position. A species from the Fort Union bad lands of the Judith River was described by Dr. Leidy as Tra- chodon mirabilis. Specimens of this species from the locality furnishing those of Diclonius, present the mode of succession ascribed by that author to Hadrosaurus, to which genus he after- wards referred the species under the name of H. mirabilis. The dentition of species of this genus shows that but one tooth in mature functional use existed in a line transverse to the axis of the jaw at one time, and that alternating with these, one partially protruded crown, and one stump of a crown, present masticating surfaces in transverse relation. The formula for this genus should then be written 2—1, while in Czonodon it is 3—3—2. The type of this genus exhibits a mode of nutrition of the young teeth similar to that seen in the genus Saurocephalus among fishes. The bone is perforated by a series of foramina, each of which conveyed an artery directly into the base of the growing crown. 254 PROCEEDINGS OF THE ACADEMY OF [1876. Char. Specif.The front of the crown is divided longitudinally by a prominent median keel and the borders are not serrate. The keel is only moderately prominent at the lower part of the crown. The back of the crown is divided into three faces by two straight longitudinal parallel solid angles, and the crown is contracted near the base by the lateral bevels for the adjacent growing teeth. All these faces are covered by cementum, whose roughness is granular in character. The external surface of the jaw-bone has precisely the same character, so that the apices of the teeth only appear as prominences of its border. The typical specimen is that of an individual of moderate dimen- sions; measurements of a tooth of a gigantic individual are given below. Measurements. M. Length of a series of five teeth . : - : : : .023 Protrusion of crown of largest tooth “ < : : 006 Diameter &S ti a , : : é : 006 Length of crown above lateral apical facets of larger animal -013 Diameter of crown at same point ' SAUER COS Ns - On transverse . : ‘ .009 Width of median face of ‘* back”’ : : : ; ; .005 Diclonius perangulatus, sp. nov. This abundant species of herbivorous dinosaur has left its shed teeth in many localities of the Fort Union horizon, in company with those of the Trachodon mirabilis, Palxoscincus costatus, and other large reptiles. Teeth with complete apices are rare. The marked character of the species is seen in the prominence of the median angular ridge which divides equally the cutting face of the crown from apex to base. The prominence increases down- wards so that the transverse diameter becomes greater than the antero-posterior, in some cases being diamond-shaped in the trans- verse direction. Its position is symmetrical, or nearly so. The lateral borders are smooth, one specimen displaying a faint trace of crenation near the apex. There is no shank or root in any of the teeth preserved, and the basis is excavated on the side away from the cutting edge for the apex of the successional tooth. A band of roughened cementum extends round the base, and is con- tinued upwards on each side opposite the cutting face. This side presents three faces, a narrow median, and two wider lateral. The latter are slightly concave, and are probably adapted to the apices ied 1876.] NATURAL SCIENCES OF PHILADELPHIA. 255 of the successional teeth; the former is often slightly concave, and is the seat of most rapid attrition. The lateral facets disap- pear at a distance below the apex, where the non-cutting side is strongly convex, and covered with a coarsely rugose cementum ; the rugosity including pits. Measurements. M. Length ofa shed tooth . c e : : , o 200d : antero-posterior . : = = OLO See ELOWe | transverse. . : A ule Width of facet for successional crown . é F 5 (Ue Width of posterior facet . : - : - : > )-005 Width of cutting face of another near apex . : . .008 Antero-posterior diameter of do. at do. . : : PecOL0 The prominence of the median angle with other points distin- guishes this species from the Cionodon arctalus. The size is larger than that of the known specimens of that species, equalling that of the largest of the order. (See Report of U.S. Geological Surv. Terrs. II., 4to, for description of genus Cionodon.) Specimens of this species have been referred by Dr. Leidy to his Trachodon mirabilis. Diclonius calamarius, sp. nov. This species, as represented by teeth, is the smallest of the genus, but the adult size is a point, however, not easily deter- mined among extinct reptiles. The teeth are slender, and the front has parallel borders and a median keel. The borders are entire, and, in two of the crowns, twisted slightly round the long axis of the tooth. The keel is thus twisted also, and towards the base, when it becomes quite low, is nearer one border than the other. The back of the tooth displays two lateral facets, sepa- rated by a narrow median facet. ‘The former have a thin, deli- cately rugose, cement investment, with a minute rugosity; the latter is smooth in the specimens, apparently from friction. The characters of this saurian readily distinguish it from its congeners. Measurements. M. Length of portion of crown . ‘ : ; 4 2012 , antero-posterior . : : . .004 i) AE at Rea inboe ‘ , d . . .C04 Monoclonius crassus, gen. et sp. nov. Char. Gen.—Teeth with obliquely truncate face and distinet root, which is grooved for the successional tooth on the front. 256 PROCEEDINGS OF THE ACADEMY OF [1876 No external cementum layer, caudal vertebre biconcave, and brim narrow. Fore limbs large and massive. The teeth of this genus resemble those of Hadrosaurus, and like them, are replaced from the * front,” an arrangement which pre- cludes the possibility of more than one series of teeth being in functional use at one time. The robust fore limbs and elongate ilium distinguish Diclonius from Hadrosaurus. From Trachodon it differs in the absence of the rough cementum layer on the back of the tooth. Char. Specif.—The faces of the teeth are acuminate oval in form, and are divided by an elevated keel, which is median above, but turns to one side at the base. Margin crenate, the grooves ex- tending more or less on the convex “back,’’ which is otherwise smooth. Sacrum with ten vertebrze, the last centrum much compressed, the diapophyses extending horizontally from the neural arch above, and connected by a vertical lamina with the iliae supports ; length 27.33 inches. The bones of the limbs are robust, the hinder the longer, but not so much so as in some other genera. Length of femur 22 inches; width, proximally, 7.4 inches; distally 6 inches. Leneth of tibia 20 inches; greatest diameter, proximally, 8 inches; distally 7.25 inches. The three anterior dorsal vertebree are co- ossified, and the first exhibits a deep cup for articulation with the preceding vertebra. The episternum is a T-shaped bone, thin and keeled on the median line below. Length of transverse portion 21 inches. Paronychodon lacustris, gen. et sp. nov. Char. Gen.—The teeth which characterize this genus have the general character of those of Plestosaurus, Elasmosaurus, ete. The crowns are subconic, and the enamel is thrown into longitu- dinal plice. The special characters of the genus are seen in the form of the crown, one side of which is convex, and the other side plane, so that the section instead of being circular is semicircular. It is also strongly curved in the Girection of its plane face. Char. Specif.—Both anterior and posterior edges are curved, and are not acute nor denticulate. There are four plice on the flat face, only two of which approach the apex. There are six keels on the convex face, all of which approach the apex. All the caring are rather obtuse, and the enamel is otherwise smooth. The apex is very acute. 1876. ] NATURAL SCIENCES OF PHILADELPHIA. 257 Measurements. M. Length of tooth . : 5 - - - . .0130 : antero-posterior : : - . .0040 Diameter at base 1 transverse 0024 Length of crown . : : : : : : . 0100 It is probable that portions of skeleton of this reptile are in my possession, but the means of positive identification are yet wanting. Compsemys imbricarius, sp. nov. This species, like the others of the genus, has the scutal sutures well defined, and the superficial surface of the carapace sculptured. The character of this sculpture distinguishes the species, and in the present instance in a special manner. It consists, in the C. imbricarius, of excavations bounded on the sides by a short ridge each, which alternate with each other. Thus each bounding ridge terminates abruptly at the fundus of one of the fossz, while the other end of the fossa rises and contracts to another ridge. The result is precisely that seen in the interior sculpture of Sara- cenic domes or niches, and is one which is quite unique among tortoises. The direction of the ridges is at right angles to the costal dermal sutures. This species was about as large as the snapping tortoise (Chelydra serpentina). Measurements. M. Thickness of a costal bone . : i é : . 0050 lengthwise 5 ; - . 0065 Three fossze measure : » =e i crosswise . ‘ : ‘ . .0050 Compsemys variolosus, sp. nov. One of the most abundant, and the largest species of the Fort Union beds. The carapace is convex and the plastron flat; the marginal bones are heavy and strongly convex on the inferior side. The margin of the plastron is thickened and heavy, char- acters which also belong to all parts of the carapace. The sutures of the dermal scuta are deeply impressed, and the surface of the bone is strongly sculptured above and below, and even on the superior face of the thickened margins of the free lobes of the plastron. The sculpture consists of round fosse, which are deeply impressed and are arranged quincuncially, so that their borders never form straight lines. The latter are also more or less angu- late on the edge, so that the surface has a more than usually ru- gose character. 258 PROCEEDINGS OF THE ACADEMY OF [ 1876. The typical specimen equals those of the large land tortoises of the Eocene in dimensions. Discovered by C. H. Sternberg. Polythorax missuriensis, gen. et sp. nov. Char. Gen.—Plastron with contracted fixed lobes and wide bridge; carapace with well-developed marginal bones; mandibular ramus narrow; alveolar face with acute external margin; the symphysis neither produced nor recurved. Dermal scuta every- where distinct, those of the plastron the usual ones, with the addi- tion of the two marginal intergulars, and two large interhumerals. The latter scuta are separated from the humerals by sutures run- ning parallel with the humeral margin of the anterior lobe between the gular and pectoral scuta. In the possession of interhumeral scuta, Polythorazx differs from any known genus of Testudinata. The general structure is much like that of Adocus and Baéna, with nearer resemblance to the latter in its double intergular scuta. It is impossible to ascertain whether there are intersternal bones, as the plastron is coossified throughout. The presence or absence of intermarginal scuta can- not yet be determined, although it is clear, that if existing, their position is quite external. This genus is interesting as connecting in its stratigraphical position allied types of Cretaceous No. 5 (Adocus), with those of the Wahsatch and Bridger Eocenes (Baéna). Char. Specif.cCarapace with openly dentate posterior border. The surface is irregularly swollen, especially on the median line near the margins of the vertebral scuta. The vertebral scuta are wide, the costals short, and the marginals narrow. The anterior lobe of the plastron is a little shorter and more contracted than the posterior; its base is narrower than the antero-posterior extent of the bridge. Its extremity is rounded, while that of the pos- terior lobe is truncate with rounded angles. The gular and in- tergular scuta are each wider than long, while the interhumerals are much longer than wide. The humerals are narrow, while the pectorals are wide from the anterior position of the pectoro- humeral suture. Each anal scutum is longer than wide. The surface of the plastron is obsoletely but coarsely rugose ; the roughness greatest anteriorly, where it consists of short raised lines irregularly disposed. 1876.] NATURAL SCIENCES OF PHILADELPHIA. 259 Measurements. M. Length of plastron ‘ : ; : : : - 183 Length of anterior lobe 5 : : 5 : i .049 Length of bridge . : : : : : : ; .076 Width of bridge . ; ; : : : ‘ Z .076 Width of extremity of posterior lobe . F : 5 .035 Thickness at inguinal region : : . : : .010 Hedronchus sternbergii, gen. et sp. nov. Char. Gen.—The bone on which this genus reposes has the ap- pearance of the crown of a young tooth. Its central cavity is large and expands to the margin of the basis; its apex is unworn. It appears to be too protuberant for the position of a dermal tubercle. It may be distinguished as a short crown on a shorter slightly constricted portion orneck. The crown culminates in three crests, which together form a letter T, and which descend towards the neck. There is no investment of enamel or cement, and the ma- terial of which it is composed resembles dense bone. Char. Specif.—The faces on each side of the stem of the T, are concave and divided by an oblique crest, which descends from the common apex. The other face is gently convex, and the inferior part of each of its bounding crests projects ear-like. The base is an oval. Measurements. M. Elevation of crown ; A j ; F 4 .006 Digmicter of base ‘ longitudinal . 0 : : - .005 transverse ® : - ‘ ‘ 004 Discovered by Charles H. Sternberg. Ceratodus eruciferus, sp. nov. A basal lamina separable from the dentigerous lamina. The latter supports ribs which diverge from a single marginal rib which extends along one side. The marginal rib is separated by a deep groove from the radiating ribs, which is continuous with the grooves between the latter. The ribs are of irregular diameter and not perfectly straight; they are interrupted by weak trans- verse ridges which project beyond the margins. The ridges rises abruptly from their common base and are separated distally by notches of the margin. 260 PROCEEDINGS OF THE ACADEMY OF [1876. Measurements. M. Long diameter of dental surface . : - 5 - O11 Short diameter of dental surface . E 5 ci é .007 Thickness of plate j ‘ ‘ ; : : c 008 There are six ridges in the length. Ceratodus hieroglyphus, sp nov. This species is materially different from the last, and was more abundant, judging from the occurrence of its remains. The dentigerous plate is thin and dense, and has the appearance of a short toothed comb with a handle. The tooth-like points are the extremities of low ridges, which are arranged nearly at right angles to a wide longitudinal elevated half of the osseous base. They are separated by shallow grooves from each other, and are not continuous with the basis just mentioned, which rises abruptly above them. They are smooth. The “handle” above alluded to is triangular in section having two bevels on the side supporting the tooth ridges. The lower face of the bone is smooth. Measurements. M. Total length 3 : 2 : : . : 5 .018 Length of dentigerous portion . : : . ° .010 Total width . P ; : : : : : 5 0045 Width of dentigerous portion. : : - : .0020 There are thirteen teeth in the length. Myledaphus bipartitus, gen. et sp. nov. Char. Gen.—Crowns of the teeth molar in character, truncate, wider than long, standing table-like on the root. The latter par- taking of the shape of the crown, short, straight, split equally and at right angles to the greatest diameter of the tooth. The crowns form a pavement having a regularly hexagonal outline. Their composition is different in the halves on each side of a line which divides the crown equally, running in the long direction. On one side the dentine is striate at right angles to the long diameter; the structure is not distinguishable by the hand lens on the oppo-. site side of the line. The affinities of this genus cannot now be stated, but the form of the root recalls the Llosmobranchii, and that of the crown, some of the rays. Char. Specif.—The staining on opposite sides of the line that divides the crown, is different, on the one paler than on the other. 1876. ] NATURAL SCIENCES OF PHILADELPHIA. 261 The face of the crown is nearly plane, and its border is vertical and overhangs the root all round in a narrow ledge; it is vertically striate, as is also the root. The antero-posterior diameter exceeds the transverse, and the facets are subequal, and are continued less perfectly on the root. The fissure of the latter does not reach the base of the crown. Measurements. M. Length of tooth . ; : 2 : 5 : : 0058 anicter of Growl { antero-posterior : : - .0060 transverse ; : é ‘ 0045 Long diameter of root é : : : : ‘ .0050 Length of root . : : = : ¢ - : .6030 Discovered by Charles H. Sternberg. ho (or) bo PROCEEDINGS OF THE ACADEMY OF [1876. NOVEMBER 7. The President, Dr. RuscHENBERGER, in the chair. Twenty-five members present. A paper entitled “ Notes on American Cretaceous Fossils, with descriptions of some New Species,” by Wm. M. Gabb, was presented for publication. On Conglomerate No. XIT.—Mr. Youne described the Con- glomerate No. XII. as it appears upon the New River in West Virginia. The formation consists of alternate members of shale and sand- stone; the latter numbering five, which are massive, but not con- glomeritic, and form cliffs upon the sides of the hills which flank the river. The shaly members of the group contain workable coal-beds. There are four beds, ranging in thickness from three to five feet. Small seams are also present. The total thickness of the formation is about one thousand feet, half of which is represented in the sandstone cliffs. The formation as above described extends from Hinton to Hawk’s Nest, the latter point being a bold cliff formed of one of the sandstone layers of the formation. The New River at Hinton falls over a barrier made by one of the sandstone members. The falls of the Kanawha are made by the upper plate of the conglomerate. The Australians.—Dr. PickERING, having recently made a communication to the Academy on the sources of the native population of New Zealand and Tasmania, now proposed to speak of Australia. The zoological character of Australia precludes the origin there of a member of the human family, and the Australians are intruding strangers ; but where they come from is a mystery. The most prominent photographs at the Centennial Exposition are unsatisfactory, with the exception. of two life-sized heads of clearly pure-blooded natives; while the many excellent small photographs require closer inspection than is usually afforded to visitors. At the Fiji Islands, he had been informed by a chief of the existence of “long-haired” people in the interior of the main island; similar accounts are given of other large islands westward, and there are inland people in the Malayan archipelago about whom very little is known; yet it does not seem probable that 1876. ] NATURAL SCIENCES OF PHILADELPHIA. 263 any island in the whole series in question contains straight-haired blacks resembling Australians. Though unprepared to cancel the Australian as a distinct physical race, he admits that afiinity may possibly be found in the Telingan or Black Hindu; and, notwithstanding the general Caucasian features of Telingans, and the broad, flat nose and darker complexion of Australians, a match could probably be found of individuals not very dissimilar in personal appearance. From eastern Hindustan, Telingans continue migrating - by thousands to the Malayan archipelago, but, being all males, make very little impression on the resident population. He did not, while among them, apply the Caucasian test of the divided carti- lage at the nasal extremity. On Sonomaite.—Mr. E. GotpsMirH stated that he had found among other undetermined minerals collected by Prof. F. V. Hayden in Sonoma County, Cal., near the geysers, one for which he proposed the name Sonomaite. This is the composition of the first specimen— Al = 7.66 per cent. = 3.56 per cent. oxygen. He ==- 2.01 Wy Oe $6 uC Matsor 714 fe = 38.21 os ce Ss = 88.78 6 = 23.26 6s 6c Ee —— 4 ad =o = 39.00 st ts A second specimen from another spot probably, but from the same locality, gave but a slightly different result, as the analysis showed— Al = 8.56 per cent. = 3.89 percent oxygen. Fe = 1.56 HY = 0.34 ve s Nine — ei ioot ue = 3.00 a . 1 a8i8 std == 22.98 a 3] H = 44.27 re = 39.35 “ ce The oxygen ratios of both analyses are— Al: Mg (Fe): S : H. By oe Sy qe) SPBBE which result may be expressed in the formula— 41 8,, 3Mg $+ 33H. The alumina was in these analyses precipitated twice in order to effect a complete separation of the magnesia. ‘The water was found by the difference. In regard to the oxidation of the iron, he ascertained that, if the watery solution of the salt was tested with a solution of sulphocyanide of potassium and well mixed, no red coloration appeared, but, on adding a few drops of diluted sulphurie acid, a reddish coloration became visible. It seems reasonable to assume that a small quantity of the iron was oxidized to sesquioxide, but had no acid with which to form the sesquisalt. The truth of this view becomes apparent if a few hundred milligrammes are dis- 264 PROCEEDINGS OF THE ACADEMY OF [1876. solved in much water, in which case a small quantity of sesqui- oxide of iron drops to the bottom of the vessel; if, however, the solution of the salt is concentrated, the separation of this oxide seems not to take place. The iron in this mineral varies in quantity, and he thought it might at times be entirely wanting, for magnesia and protoxide of iron may substitute each other, and for this reason he did not introduce it into the formula. When he first determined the mineral, it was supposed to be Pickeringite, because the general appearance, the reactions with the blowpipe, its solubility, and all the elements contained in it are the same; only the quantitative analysis showed the differ- ences in the ratios of the constituents. Sonomaite occurs in silky, colorless crystals. Specific gravity in alcohol of 95 per cent. — 1.982; in water it would therefore be — 1.604. Klauer described (Gmelin’s Handbuch der Chemie, 2, 315) a salt which differs from this only in having 3 eq. of water more. Explorations in South America.—Prof. Core stated that an expedition had been planned in this city for the exploration of the sources of the Madeira River, and of the eastern slopes of the Andes in Bolivia. Prof. James Orton had taken charge of the party, which included a corps of scientific assistants. As the region in question is the least known in South America, important results are anticipated. It was hoped that the Academy would be able to avail itself of these in the increase of its collections, etc. The expedition sailed on the 25th of October last. NoveEMBER 14. The President, Dr. RuscHENBERGER, in the chair. Thirty-six members present. A paper entitled “ Note on a Cirripede of the Californian Mio- cene, with remarks on Fossil Shells,” by T. A. Conrad, was pre- sented for publication. On Boussingaultite and other Minerals from Sonoma County, California.—Mr. E. GoupsmitH stated that among the minerals brought by Dr. F. V. Hayden from Sonoma County, Cal., was one which he thought proper to cail Boussingaultite. Although he had not been able to find in the current literature an analysis of the mineral to which Bechi had given this name in 1864, still he presumed that it might be that. It is stated, however, in Dana’s Descriptive Min., p. 635, that Boussingaultite is mascag- nite with some sulphate magnesia; whereas the mineral which Mr. G. analyzed seems to be sulphate magnesia ammonia. The 1876. ] NATURAL SCIENCES OF PHILADELPHIA. 265 mineral occurs in irregular granular masses, is soft, and easily rubbed to a perfectly white powder. If heated in the tube, closed at one end, it affords water and a white sublimate, which latter is sulphate ammonia; in the bottom remained a white residue. On coal it gave, with solution of cobalt and strong ignition, the reddish coloration indicating the presence of magnesia. It is soluble in water. The solution showed the presence of sulphuric acid, magnesia, and ammonia. The quantitative determination of the sulphuric acid and the magnesia was done with the air-dry substance; the amount of ammonium-oxide and water were calculated by means of those obtained data stéchiometrically. S = 38.86 percent. = 23.31 oxygen. Mg = 15.56 = 6.22 * AmO = 5.03 $f ee legds a H = 40.55 bia = 36.04 ‘* The oxygen ratios of the acid and bases are— S : Mg : AmO : H. 15.18: 4.03: 1 > 24. Here are evidently five equivalents of sulphuric acid, and also the same number of equivalents of bases, hence the formulated expression— Rly ge if [ 4Mgs, AmO S$ + 24H may be proposed. The substance is nearly insoluble in alcohol of .818 specific gravity, at 70° F., it was therefore weighed in it, and its specific gravity found to be = 2.037; in water it would have the specific gravity = 1.666. Mr. Goldsmith further called attention to the following minerals, which were all collected by Prof. Hayden in the same locality as those described above :— Geyserite intermixed with a basic sulphate of iron and an oil, which is probably petroleum. Epsomite or native sulphate magnesia occurs there, sometimes pure, occasionally mixed with geyserite. Geyserite containing some sonomaite. Mascagnite or native sulphate ammonia in white, irregular- shaped fragments. Nodular: geyserite seems to have been ground by the action of the motion of the geyser. Some of the nodules are nearly spheri- cal; others spheroidal; a few in the collection are flattened, but always smoothly rounded; color white. They are nearly pure silica. Sulphur is also a product of the geyser region. This element was noticed to be in very small crystals, which, when burned away, left at first a black carbonaceous matter; on heating to a high temperature, the carbon disappeared and a white ash re- mained. 18 266 PROCEEDINGS OF THE ACADEMY OF [1876. Iron ochre containing a small quantity of arsenic. The reddish- brown powder has a peculiar disagreeable odor. Kaolinite in the form of a pale blue, soft powder; on heating, the blue color disappears ; if this substance is heated in the glass- tube, closed at one end, water is expelled which reacts alkaline; but on heating strongly, that is, to near redness, the reaction on litmus-paper indicates the presence of an acid. Earthy geyserite containing some gypsum, and, at least, the flame-reaction of the presence of a minute quantity of potassa. Although Mr. G. searched for chlorine or soluble chlorides, which as usual are widely distributed over the globe, in these cases, however, they seem to be absent. Whether in Sonoma County no chloride of sodium is found cannot be said at present with certainty ; it is singular that none was noticed among those minerals which he had the opportunity to determine. Cretaceous Vertebrates of the Upper Missouri.—Prof. Cope stated that he had recently returned from an exploration of the Judith River beds of the Upper Missouri, which were discovered by Dr. Hayden in 1855. Attention was given to the relation of this formation to the underlying marine cretaceous beds, and to the respective faunz of the two as compared with that of the early eocene period. The fauna was found to be terrestrial and lacustrine, including great numbers of Unionide, Lepidosteus, Myledophus (a form probably of rays); of tailed Batrachia, crocodiles, fresh-water turtles, Rhynchocephalia, and Dinosaurian reptiles. The Dinosauria constitute the most abundant and cha- racteristic form of life, eighteen species having been found, of which eight were of the carnivorous (Goniopodous) and ten of the herbivorous (Orthopodous) type. The predominant genus of the former is Lelaps, and of the latter Dysganus, of both of which several species were found. The facies of this fauna is thus plainly mesozoic and cretaceous, adding weight to the arguments already adduced to this effect. But the change from the fauna of the underlying cretaceous num- bers four and five is very striking, the genera and often higher groups being quite different. The types of the marine beds were found to be Pythonomorpha, Elasmosaurus, a genus allied to Polycotylus, Enchodus, chimerids, and sharks, with marine Cephalopoda, etc. Nevertheless, the physical transition between the marine and lacustrine formations appears to be complete, as indicated by Prof. Hayden. Dr. Le Conte read the following report from the committee appointed, at the request of the Centennial Commission, to inves- tigate and report upon the introduction of noxious insects and plants through the medium of the foreign exhibits in the exhi- bition :— 1876. ] NATURAL SCIENCES OF PHILADELPHIA. 267 REPORT ON INSECTS INTRODUCED BY MEANS OF THE INTERNATIONAL EXHIBITION. On behalf of the Committee appointed by the Academy of Na- tural Sciences of Philadelphia, at the meeting held October 10, 1876, “to investigate and report upon the introduction of new species of insects and plants through the medium of foreign ex- hibits at the Centennial Exhibition,’ I have the honor to present the following report, with the desire that it may be forwarded to the proper authorities of the Centennial Commission, at whose instance the Committee was appointed. The Committee is composed of the following members of the Academy :— Dr. Joseph Leidy, Dr. George H. Horn, Mr. Thomas Meehan, Dr. J. Gibbons Hunt, and Dr. John L. Le Conte, Chairman. It was apparent that while the labors of the botanists of the Committee could not properly commence until next spring, when careful observation will recognize any new introductions of plants, the entomological investigations should be made as speedily as possible. Accordingly, Dr. Horn and myself, availing ourselves of the admission cards which had, with great liberality, been sent to the members of the Committee, went frequently to the exhibits in the Main Building and Agricultural Hall, and made collections in all the agricultural products from foreign countries, which were found to be infected. Most of the species which we obtained have been already dis- tributed over the globe by the ordinary channels of trade, and nothing is to be apprehended from the addition of a few hundred thousand specimens, to the incalculable millions of individuals of the same kind, that we have now domiciled amongst us. I am happy to add that the species found, which have not been previously observed in the United States, will be innocuous; they are dependent for their support upon plants which do not grow here, and which would be of no commercial value to us if they were cultivated. I may therefore announce, with moderate certainty, that no evil result will occur to our agricultural interests, from any intro- duction of foreign insects, by means of the Centennial Exhibits. 268 PROCEEDINGS OF THE ACADEMY OF [1876. Before concluding this report, by a list of the insects collected in the buildings, it is our duty to notice some remarkable differ- ences between the exhibits from different countries, indicating the care with which the specimens had been prepared, and the means taken to prevent depredation by insects. All those exhibits which had been moist when packed, or had become moist or mouldy on the voyage or during the Exhibition, abounded in Bruchus, Calandra, and Tineide ; while those which were protected against moisture were unattacked. It stands to reason, in fact, that insects dependent on a circulating fluid for their vitality, and having, during their early stages as larve, a very soft and moist body, cannot obtain in properly dried grains the requisite amount of moisture for their sustenance, and the egg, if previously deposited, will remain, like an ungerminating seed, for a favorable moment to develop, or if hatched, the larva will die at an early stage. It was, therefore, with great pleasure that we recognized the appreciation of this almost self-evident proposition by the De- partment of Agriculture of Portugal. The exhibits in bottles were entirely free from all mould and infection, and in each bottle was a small quantity of caustic lime,' wrapped in paper, which, by its hygrometric power, had kept the specimens perfectly dry. We do not intend to have it inferred, from what is above stated, that all the other exhibits were in a condition inferior to that of Portugal; on the contrary, many of them, as well as many from our own States, were in most admirable order; but, so far as we could learn, this good condition had been produced by great per- sonal care, and the removal from time to time of the infected parts; not by the use of a preventive agent. While investigating the occurrence of a small species of Tineide in the Italian exhibit of Leghorn straw, I learned that some im- portations of straw goods, by Messrs. Albinola and Bailey, of New York, had been attacked by insects. I immediately wrote to those gentlemen, who, with great courtesy, sent me two collections of the insects infesting a recent importation which had become mouldy from being packed in a moist condition. The names of the species contained in this set are appended ; they are all either carnivorous or fungivorous, and can therefore do no harm; some of them have ! The nature of the powder was suspected by the Committee, but the determination was made through the analysis of Mr. Edward Goldsmith. 1876.] NATURAL SCIENCES OF PHILADELPHIA. 269 not been before observed in the United States, or their habits have not been noted. What is more important, however, is that none of the straw goods were attacked by moths either on this or previous oceasions. It is therefore to be inferred that the moth in the Italian exhibit was the grain-moth of the seed of the grass which produced the straw used in the manufacture of the Italian goods. What confirms this inference is that the moths occurred in but one case, in which were exhibited several bunches of the straw with the heads of grain still remaining. Prof. C. V. Riley, in the Proceedings of the Academy of Science of St. Louis, Oct. 2, 1876, has given a list of the species which he collected at the Centennial Exhibition, with very useful and suggestive remarks. We have obtained specimens of all the species mentioned by him except one Crambide Lepidopteron, from the Egyptian exhibit, for which we sought without success. At an earlier period in the season, and with smaller attendance of visitors, the number of species in our list would perhaps have been larger, but no additional advantage would have been ob- tained therefrom. The species, with the few exceptions noted, are either innocuous or previously introduced. J. L. Le Conte, Chairman, Gro. H. Horn, JOSEPH LeEIDy. List of Species collected in the Centennial Buildings in Foreign Exhibits. COLEOPTERA. Silvanus surinamensis. Argentine Confederation and Brazil, in various materials. Lemophleus ferrugineus. In beans, Brazil. These two species lived upon the debris of Bruchus, and were accompanied by a species of Psocus. Bruchus picturatus, Fahreus. Argentine Confederation; in seeds of two Leguminous plants, one of which produces a screw bean, resembling Strombocarpus of Arizona. Bruchus, sp. Allied to B. prosopis, of Arizona and New Mexico. Argentine Confederation; also in the screw bean. These two Bruchi are depredated upon by three small species of Ichneumonide. 270 PROCEEDINGS OF THE ACADEMY OF [1876. Bruchus, sp. Of larger size and more uniform color. Argentine Confederation, in the seeds of another Leguminous plant, allied to Prosopis. Bruchus, sp. Of larger size and more mottled color; in the seeds of three other Leguminous plants of the Argentine Confederation. Bruchus scutellaris. Venezuela, in beans. Bruchus obsoletus. In beans from various countries of both continents. Bruchus pisi. In peas; Spain and Portugal. Bruchus, sp. A small broad species, with transverse prothorax; % rather uniformly clothed with gray-brown pubescence; antenne as long as the body; @ black, with a grayish-brown broad dorsal stripe on the prothorax, and a small transverse white band on each elytron, extending from the side margin nearly to the suture, a little in front of the middle; thighs not toothed. Length .09 inch. Brazil, in a bluish-gray variety of bean. I cannot identify this species among those described in Schénherr’s work; it is of the same form, and belongs to the same division as B. pisz, but is much smaller, and quite different in other characters. It is the only one of the species here mentioned which is capable of being introduced; and I have, therefore, given such a description as will enable it to be recognized. The antenne are only feebly ser- rate. This species is mentioned by Mr. Riley as B. granarius, but it does not agree with the figure of Olivier. Rhizopertha pusilla. Victoria, Australia; in wheat. This insect has been previously introduced into the United States in Persian wheat, distributed by the Patent office. (Vide Lec. Class, Col. N. Am. p. 208.) Calandra oryze, This destructive insect abounded in exhibits of corn (maize), wheat, and rice from every part of the globe. I also observed it in arrowroot from Brazil. 1876.] NATURAL SCIENCES OF PHILADELPHIA. 271 Areocerus coffee. Eating the thin shell of cacao-nuts from Brazil, but apparently not attacking the interior of the nut. Previously introduced both in the Atlantic and Pacific States. LEPIDOPTERA. The ordinary and well-known Tineide, which affect wheat and corn (maize) (Butalis cerealella, Ephestia Zex), abounded in ex- hibits from various countries. There was a smaller form which is mentioned above, as coming from the grass seeds of the Leg- horn straw. Specimens have been identified by Prof. C. V. Riley as the common grain moth, B. cerealella. HYMENOPTERA. Besides the three Ichneumonide parasitic on the Bruchi in the Argentine Confederation exhibit, I observed a small species of Pteromalus parasitic on the Tinea, Bruchus obsoletus, or Calandra oryze which infested a small bag of Brazilian wheat. List of the Species found in Mouldy Specimens of Straw Goods from Italy. These species were collected by Messrs. Albinola and Bailey, in New York. They are either carnivorous or fungivorous; those of the latter kind live upon the mould, which, as determined by Dr. J. G. Hunt, is a species of Aspergillus, previously known in this country. Lathridius filiformis. Lathridius striatus. Corticaria, sp. (Not identified.) Holoparamecus singularis. Has not been previously observed in the United States. Silvanus surinamensis. Silvanus advena. Lemophleus ferrugineus. Murmidius ovalis. Habits not previously observed in the United States, though its occurrence was known. Tribolium ferrugineum, 272 PROCEEDINGS OF THE ACADEMY OF [1876. NoveMBer 21. The President, Dr. RuscHENBERGER, in the chair. a Thirty-six members present. NOVEMBER 28. The President, Dr. RUSCHENBERGER, in the chair. Fifty-three members present. A paper entitled “Notes on Fishes from the Isthmus of Panama, collected by Dr. J. F. Bransford, U. 8. N.,” by Theodore Gill, was presented for publication. Louis F. Benson and Walter H. Ashmead were elected members. Dr. A. S. Packard, of Salem, Mass., W. H. Holmes, U. S. Geol. Surv., and Laurenco Malheiro, of Lisbon, were elected corre- spondents. The following papers were ordered to be printed :— 1876.] NATURAL SCIENCES OF PHILADELPHIA. 2 NOTE ON A CIRRIPEDE OF THE CALIFORNIA MIOCENE, WITH REMARKS ON FOSSIL SHELLS. BY T. A. CONRAD. BALANUS. H. Estrellanus, Con. This fossil of the Californian Miocene, Tamiosma gregaria, Con- rad, I supposed at one time to be a member of the Rudiste, and I also described it as Balanus estrallanus; but not satisfied that, as one of the Rudistz, it should be in the Miocene formation, I have further studied its characters, and now conclusively refer it to the Balanidex. The only difference I can find to distinguish it, except specifically, from other species of the genus Balanus is that its basis is filled the entire length with septa. These septa do not essentially differ from those of Balanus levis, Brug. In the only specimens found, the opercular valves are wanting, but a portion of the basis on which they rested is well preserved, and shows the same kind of surface as in other Balani. HELIX. H. Strangulata, Adams. A very perfect specimen of this species is in the collection of the Academy of Natural Sciences, which I obtained at Yorktown, Virginia, while collecting Miocene fossils at that locality, although I do not recollect whether I found it in the marl or on the surface, probably the latter. It cannot be proved to be a Miocene fossil. INOCERAMUS, Sow. This genus is distinguished from Haploscapha (Catillus, Brong.) by a straight hinge line and the crenulations on the hinge, partly internal; while Haploscapha has an irregular or waved hinge, the right valve being alate about the beaks and having a sinus posteriorly, as represented in D’Orbigny’s figure, pl. 412, of his “ Paleon. France.” The ligament is wholly external, situated in crenulations more numerous than in Jnoceramus, and often in an irregular line. Pictet describes IJnoceramus as “lamelleux,” and says “ La principale différence qui existe entre 274 PROCEEDINGS OF THE ACADEMY OF [1876. ces coquilles et celles des Inocérames consiste dans la structure du test, qui chez les Catillus est fibreux dans sa couche externe, repellant presque celui des TricuirEs.” Mr. Meek adopts Catillus as a subgenus of Inoceramus without stating a distin- guishing character, but I cannot find one species of Catillus among those he describes as species of it excepting I. deformis: One characteristic difference between the two genera is the ex- tremely thin shell of Catillus over the middle portion of the disk and the gradual thickening towards the margin; indeed, the shell of the two species I have described is so thin that it has only been preserved entire by the adhesion of multitudes of Ostrea congesta on the back. This thinness is not in consequence of any loss of the original test, for the pearly layer is well preserved. Dr. C. A. White has given a figure of I. deformis, Meek, which is a true Catillus, as a section of the shell shows. ‘ Report upon Geog. and Geolog. Explor., pl. xv., fig. 1.’ Catillus attains a far larger size than Jnoceramus, and is known only in the chalk. Although the interior of the valves is well preserved, no trace of a muscular impression is seen. The laminated structure of Inoceramus, where the shell is preserved, will readily distinguish it from the coarsely fibrous structure of Haploscapha ( Catillus). The latter originated near the close of the chalk period, while the former is found in the lias as well as in the chalk. APHRODINA, Conrad. Mr. Meek makes this cretaceous genus a subgenus of Callista, which I think an error. Callista did not exist in the creta- ceous period, nor Dosiniopsis. IDONEARCA, Conrad. I make the same objection to Mr. Meek’s retaining this creta- ceous genus as a subgenus of Cucullea. It is a large group of fossil shells, which can be instantly known by the hinge character, and which disappeared entirely at the close of the cretaceous period. MUTELIDA. HAPLOTHERUS. This extinct genus was the forerunner of Columba, Lea (Leila, Gray), to which it is nearly allied, the typical species having much Y)s y ; ) I g 1876. ] NATURAL SCIENCES OF PHILADELPHIA. 275 resemblance in outline to Columba Blainvilleana, Lea, but wants the cardinal tooth of that genus. The hinge more nearly resem- bles that of Columba (Leila) castelnaudi, Hupé, but the anterior muscular impression is very different from that of C. castelnaudi. Columba, Lea, takes precedence of Leila, Gray, according to date of publication. ANCHURA. In the Geology of North Carolina, by Prof. Kerr, I have inad- vertly referred Anchura pennata, Morton, to his Rostellaria ros- trata, pl. 2, fig. 28. Arene Carolinensis of the same work is erro- neously referred to plate 2, fig. 19. It should be pl. 1, fig. 19. ETEA, Conrad. To this genus must be transferred Crassatella monmouthensis, Gabb; C. transversa, Gabb; C. Delawarensis, Gabb; and C. prora, Con.; all of which were described from casts without knowledge of the hinge characters. 276 PROCEEDINGS OF THE ACADEMY OF [1876. NOTES ON AMERICAN CRETACEOUS FOSSILS, WITH DESCRIPTIONS OF SOME NEW SPECIES. BY W. M. GABB. After fifteen years, during which I have been engaged con- stantly at other geological and paleontological labors, but have not lost sight of my first love—the Cretaceous fossils of the Atlantic region of the United States—I have spent much of the past summer in reinvestigating them. In this work I have been materially assisted by the constantly enriching collection of the Academy, and have received a large suite of fossils from Dr. Little, the State Geologist of Georgia. Besides these, Prof. Cook, of New Jersey, has loaned me all of the specimens from his survey collection that I required, so that I have it in my power, while describing a number of new forms, to correct many of my own juvenile errors, as well as similar ones of others, which must result during the publication of a large number of small, isolated papers. Many of the fossils of New Jersey are only known as internal casts in the marls, and, while very unsatisfactory, require. names, if only provisional ones, to assist the field geologist in the identification of strata. Some of these have from time to time been rediscovered in the gray marl, commonly known as the ‘* Ripley group,” and we may reasonably hope that all will eventually be fully described. This Ripley marl is a deposit now known to extend from New Jersey around through the coast States to Tennessee. It has been found in ail of these States except Delaware, Maryland, Virginia, and South Carolina, that is to say, it seems coextensive with the Atlantic Cretaceous. It is a fine-grained, gray material, in which, unlike most of the rest of the formation, the shell substance is preserved, and, although the shells are often distorted, their specific as well as generic charac- ters are beautifully preserved. It is especially favorable for the study of the bivalves, since, in nearly all cases, the hinges can be exposed. The fossils are extremely fragile, alike from the softness of the inclosing material and from the fact that the animal matter seems to have totally disappeared, without being replaced by any other cementing substance. Still, with care, the greater part of the fossils can be extracted and afterwards hardened with gum, 1876. ] NATURAL SCIENCES OF PHILADELPHIA. 277 so as to fit them for study and preservation. In the following paper I have enumerated all the recognizable species sent me by Dr. Little, since very little is known of the fossils of Georgia, and in that sense this is a geographical list :— Navriuus, Linn. N. Bryani, n. s. Shell discoidal, sides flattened, nearly parallel; dorsum regu- larly rounded; umbilicus small; aperture elongate, emarginate to about a third of its length by the preceding whorl; siphuncle central, small; septa slightly arched forwards, close to the um- bilicus, and very gently backwards on the middle of the side of the whorl. Surface unknown. Greatest diameter 3.5 inches; width of aperture 1.9 inch; height of mouth from umbilical margin 2 inches, from the dorsum of included whorl 1.4 inch. From the yellow Cretaceous limestone of Vincenttown, New Jersey. Two fragments, one comprising half of a volution, well preserved, showing seven septa; the other, a smaller fragment of a larger specimen, useful only as confirming the specific deter- mination. This species is markedly distinct from N. Dekayi, the only other described species in New Jersey. Its flattened sides are entirely unlike the globose form of that species. It seems nearest to NV. Sowerbianus, D’Orb., resembling that species in the size of its umbilicus and in the style of the septa, as well as in being compressed. But our species differs in having the sides more parallel, in the whorls increasing somewhat less rapidly in size, and in the septa being further apart and less sinuated throughout. I take great pleasure in dedicating it to my friend, Colonel T. M. Bryan, who has, by his assiduous collecting, added much to our kuowledge of the New Jersey fossils. N. sp. indet. 1 have also received from Col. Bryan another form from the dark marls of New Jersey, near Vincenttown. This is distinct from either of the known species, having very sinuous septa. It is represented by fragments too imperfect for description. N. Dekayi, Morton. Synopsis Cret. p. 33, pl. 8, f. 4; pl. 13, f. 4. A distorted specimen from Pataula Creek, Georgia, from Dr. Little. 278 PROCEEDINGS OF THE ACADEMY OF [1876. N. elegans, Shy. It is not improbable that the shell referred by me (in the Report of the Palzontology of California, vol. 1, p. 59, pl. 9, fig. 3) to N. Texanus, Shumard, may prove to be Sowerby’s species. It seems to agree quite closely, not only in its outline and pro- portions, but in the shape of the septa and in the ornamentation. The only difference I can detect is that, in the Californian shell, the ribs are a trifle larger and less numerous—a very unreliable character in these shells. Dr. Shumard’s species, only known to us by a description from imperfect specimens, may also have to be put down as a synonym. AMMONITES, Brug. A. placenta, Dekay. Ann. N. York Lyc. vol. 2, pl. 5, f. 2. A large specimen from Pataula Creek, Georgia. A, Trinitensis, Gabb. A. Gibbonianus, Marcou, Geol. N. A. p. 35, pl. 2, fig. 2; not id., Lea, Trans. Amer. Philos. Soc., 2 ser. vol. 7, p. 284, pl. 8, f. 3. In my paper on the fossils of South America, now going through press (Journ. Acad. 1876), I have pointed out the differences be- tween the Texan fossil and that from South America, and I now propose the above name. Marcou found his specimen on one of the tributaries of the Trinity River, Texas. Hamirtes, Park. H,? torquatus, Morton. Syn. p. 45, pl. 15, fig. 4. A straight fragment, with the Ammonites placenta, some three inches long. I have it also in my collection from Uniontown, Ala., showing part of the septum. Fusvus, Lam. Exiuirusus. New subgenus. Shell very long, slender, fusiform, spire high; aperture produced into a long, slender, twisted canal. This group differs from the true genus Fusus, as restricted, by its twisted, slender canal. In this character it approaches some of the Neptunee, but its high spire and strongly costate whorls show that it is more nearly allied to the true Fusus. wxilia of Conrad (Journ. Philada. Acad., 2 ser., vol. 4, p. 291) has a 1876.] NATURAL SCIENCES OF PHILADELPHIA. 279 “beak perfectly straight,” and may be only an extremely slender Fusus. The author does not describe the shape of the outer lip, and gives us no clue as to its family relations, whether it belongs with the Fusine or the Pleurotomide. The lines of growth on my shell are slightly sinuous on the upper part of the body whorl, though not enough to be called the notch or sinus of a Surcula, the genus which it most resembles in that family. I attribute their shape to the generally curved outline of all of the body whorl. The figure of Fusus Diaboli, Pal. Cal. v. 1, pl. 18, fig. 35, is a very accurate reproduction of one specimen before me, the ex- tremity of the canal being broken away. But I have another, nearly of the same size, with the same character of the spire, in which the aperture and canal are larger than the spire, the canal being twisted exactly as in the present described species. In the specimen figured, as above, the lines of growth are slightly sinuous also, so that further research may prove that this is really a member of the Pleurotomide. i (E,)) Kerri, n.s. Pl. 17, f. 1. Shell elongate, slender; spire high ; whorls about six or seven, rounded on the sides and bordered on the upper margin by a rib adjoining the suture. Surface marked by about a dozen oblique heavy ribs, beginning on the top of the whorl adjoining the mar- ginal thickening, most prominent on the upper angle of the whorl, and disappearing a little below the middle. In addition to these characters, their entire surface is covered by numerous closely placed, fine, revolving ribs. Upper part of the aperture sub- elliptical, continued below into the twisted canal, twice as long as the upper portion. Columella thickened and marked by a com- paratively prominent angle, similar to that of Busycon, where the curved canal begins. Length 1.25 inch; width 0.37 inch. A single specimen in the Museum of the Academy, from the Cretaceous of North Carolina (Ripley group). Named in honor of Prof. W. C. Kerr, State Geologist of North Carolina. Surcuna, H. and A. Ad. §. strigosa, n. s. Shell very long and slender; spire and aperture of nearly equal length; whorls broadly rounded, perhaps eight in number (apices 280 PROCEEDINGS OF THE ACADEMY OF [1876. broken), those of the spire marked by a peculiar revolving con- striction just above the suture. Surface cancellated by numerous, small, longitudinal ribs, somewhat smaller than their interspaces, and crossed by still smaller revolving lines. These latter con- tinue over the whole surface to the end of the canal. Length 3 inches ; width 0.6 inch. From a light-colored Cretaceous marl from Holmdale, N. J., from the collection of the N. J. Geological Survey, kindly loaned to me by Prof. Cook. This is the most slender species of the genus with which I am acquainted. The shell substance is entirely destroyed, but the surface characters are preserved, all except the lines of growth. I am consequently unable to describe the shape of the outer lip. The groove above the suture causes an appearance, at first sight, as if the top of the whorls was bordered by a thickening; but the separation of the volutions is still marked by a slight fissure in the suture, which is placed about a tenth of an inch below the groove. This seems to have died out on the body whorl. S. (Surculites) Mathewsonii, Gabb. Fusus, id., G., Pal. Cal. v. 1, p. 88, pl. 18, f. 33. S. (Surculites) io., Gabb. ? Fasciolaria, td., G., Pal. Cal. v. 1, p. 101, pl. 28, f. 214. Both of these species, as seen from better specimens than I had originally, have the broad, shallow sinus on the upper part of the whorl, characteristic of Surcula. The first certainly belongs to Mr. Conrad’s subgenus; the latter, however, with its tuberculated volutions, may have to be separated, though there is no named division into which to remove it. Generically, or subgenerically, they only differ in this character. DriL1iA, Gray. D. Georgiana, n. s. Shell elongate, fusiform; spire elevated, longer than the mouth ; whorls seven or eight, flattened, bordered by a thickened rim adjoining the suture; below this is a groove followed by a series of heavy longitudinal ribs, about 12 or 13 to a volution. These ribs are not well defined beyond the middle of the body whorl. Cross- ing the entire surface are numerous revolving lines, appearing as small ribs on the upper whorls, and as narrow impressed grooves on the last whorl. Notch narrow and shallow (as determined ai at ica a i i, 1876.] NATURAL SCIENCES OF PHILADELPHIA. 281 from lines of growth), and corresponding to the groove below the thickened upper margin of the shell. Canal moderately long ; details of it and of the mouth unknown. Length 1.5 inch; width 0.4 inch. From the Ripley group, Pataula Creek, Clay Co., Georgia; Dr. Little. A pretty species, resembling Turris Ripleyana, Con. (Journ. Acad., 2.s., v. 3, pl. 35, f. 21), in ornament, but more slender, with a higher spire and shorter body whorl. Trironitum, Linck. Subgenus Lagena, H. and A. Ad. T, (L.?) edentatum, n. s. Shell thin, short, broadly subfusiform; spire moderately elevated; whorls seven; spire turriculated; whorls of spire sub- angulated and sloping above, terminated in a thickened, beaded margin adjoining the suture, and constricted below this margin ; body whorl regularly rounded. Upper whorls marked by nume- rous longitudinal ribs, sometimes visible on the upper part of the body whorl, sometimes obsolete. These are crossed by revolving lines, always distinct on the spire and on the anterior part of the body whorl, but sometimes obsolete on the middle. Aperture broad, subelliptical ; canal short, very slightly recurved. Outer lip simple; inner lip lightly encrusted. No tooth on the posterior part of the inner lip. Length 1.4 inch; width 1 inch. A smooth, rounded shell, with ornamented spire, rather plain body volution, and no varices. With the following species, to which it is closely allied, it seems to form a distinct group in the Tritons, nearest, however, to Lagena, to which I have referred it, but differing in the absence of the tooth. Common on Pataula Creek, Georgia; Dr. Little. T, (L.?) interruptum, Con. (sp.). Chemnitzia, id., Con., Journ. Acad., 2 ser., v. 3, p. 3388, pl. 35, f. 15. With the preceding. Mr. Conrad describes the species as havy- ing the “ spire prominent ;” but my specimen, as well as his figure, shows that it is not so long as the mouth. Chemnitzia? gloriosa, Roem. Kried. von Texas, p. 40, pl. 4. f. 3. From the remarkable resemblance in the style of ornament 19 282 PROCEEDINGS OF THE ACADEMY OF [1876. of this shell to the two preceding, I have little doubt that it is sub- generically identical with them. Roemer’s fanciful restoration of the anterior end of the mouth, of course, goes for nothing. Nassa, Lam. N. globosa, n. s. Shell thin, subglobose; spire moderately elevated; whorls six or seven, the upper whorls costate, the ribs not reaching to the suture; above the ends of the ribs is a narrow concave space; suture bordered by a slight thickening of the margin of the suc- ceeding volution; suture not impressed, although well marked— partly obliterated by irregular lines of growth. Body whorl not ribbed, but ornamented by small indistinct and sometimes almost obsolete revolving lines. Aperture oblique; outer lip simple; inner lip rather heavily encrusted by a narrow deposit, and termi- nating in front in a heavy rib, hardly visible externally; anterior notch narrow and deep. Dimensions of a small specimen: length 1.0 inch; width 0.9 inch. Other specimens, too imperfect for measurement, indicate a size nearly twice that given. From the Ripley group of North Carolina, Museum of the Aca- demy, from Prof. Kerr, and from the same deposit on Pataula Creek, Georgia, from Dr. Little. FascioLaria, Lam. F. Slackii, Gabb. Proc. Acad. 1861, p. 322. Described from a single internal cast from New Jersey. The longitudinal ribs are large, showing strongly on the cast. The revolving sculpture, if it existed, is unknown. From the shape and from the cast of the columellar fold it most probably belongs to Meek’s subgenus Piestochilus. Subgenus Cryproruytis, Meek. F. (C.) crassicosta, n. s. Shell small, broadly fusiform; spire moderately elevated, number of volutions unknown, suture well marked and undulated ; body whorl! subangulated, flattened above, convex in the middle, and rapidly constricted in advance. Surface bearing about nine large rounded longitudinal ribs, beginning near the suture, strongly developed on the upper angle and disappearing with 1876.] NATURAL SCIENCES OF PHILADELPHIA. 283 the convexity in advance; the entire surface to the end of the canal, is crossed by small but well-defined revolving elevated lines, showing a slight tendency to alternation in size. Aperture broad above, constricted into a moderately short twisted canal; inner lip encrusted terminating in advance in a single heavy oblique fold. Length about 1.0 inch; width about .65 inch. A single specimen from Pataula Creek, Georgia; Dr. Little. It is somewhat distorted in shape by pressure, and has lost part of its apex ; but its heavy ribs and strongly twisted columella will distinguish it. F. (C.) Kerri, n. s. Shell small, subfusiform, spire shorter than the aperture, whorls five, suture minutely channelled; upper whorls sloping convexly ; body whorl regularly convex and gradually contracted in advance into a moderately long and somewhat curved canal ; surface marked by a few large square revolving ribs, five on the convex part of the body whorl, and numerous smaller ones in ad- vance; these are crossed by faint longitudinal ribs, more closely placed than the first. At the points of crossing, these two sets of ribs develop well-marked little nodes or tubercles. On the spire, the longitudinal ornaments do not appear, but each volu- tion carries three revolving ribs, the upper of which is smallest Aperture gradually narrowed in front; inner lip somewhat en- crusted and bearing a small oblique fold on the angle. Length .75 inch; width .4 inch. From the Ripley of N. Carolina; Prof. Kerr. F, (C.) obliquicostata, n. s. Shell small, fusiform, spire not quite as long as the aperture ; whorls about five or six, upper surface rounded, subtruncated ; body whorl widest above, top sloping, tapering in front. Surface marked by a few large oblique ribs with broad concave inter- spaces ; these ribs begin at the suture, are most prominent on the angle of the whorl and disappear in front. The entire surface is also crossed by numerous fine revolving striz. Aperture gradu- ally narrowing in advance; inner lip sinuous, encrusted ; fold small, very oblique ; canal moderately twisted. Length .9 inch; width .45 inch. Locality ; with the preceding. 284 PROCEEDINGS OF THE ACADEMY OF [1876. From F.(C.) crassicosta, this shell differs in its much more slender form, its higher spire, less twisted canal, and in the longi- tudinal folds being much more compressed laterally and placed obliquely instead of direct. Pyropsis, Con. P, Richardsonii, Tuomey, sp. Pyrula. td., Tuomey, Proc. Acad. 1855, p. 169. Perissolaxz? id., Gabb, Syn. Cret. p. 69.! Tudicla (Pyropsts) perlata, Con., J. Acad. 2:s., v. 4, p. 288, pl. 46, f. 39. This species is found in New Jersey, and is abundant in the white limestone of Prairie Bluff, Ala. Dr. Little has sent me one internal cast from Pataula Creek, showing that it grows to a dia- meter of nearly two inches. P, Bairdi, M. & H. (sp.) Meek. Pyrula Bairdi, M. & H. With the additional information furnished by Mr. Meek’s illus- trations, especially by the wood-cut, p. 371 of his admirable memoir, I am convinced that there is no generic, or even subge- neric difference between his species, and that of Mr. Conrad’s type, lying before me; unless it may be found in the end of the canal of the Eastern species, and which has never yet been found. P. Richardsonii has a slender canal, probably not umbilicated, but this is not ground enough for a separation. The characters of the inner lips of the two species are identical. P, elevata, Gabb. Rapa, id., Gabb, Journ. Acad. 2 s., v. 4, p. 301, pl. 48, f. 12. Tudicla, id., Gabb, Syn. Cret. 1861, p. 85, 7d. Meek, Check List Cret. No. 750. Described from the brown sandy marl of Burlington Co., N. J. But a single internal cast has ever been found and this corre- sponds so nearly in size and shape with P. Bairdi, that I suspect it of being identical. It is certainly not the same as P. Richard- sonti (perlata Con.), as Mr. Conrad intimated in Journ. Conch., 1868, p. 248. ! This arose from an error, I having confounded Tuomey’s two species, and transposed them in their genera. I intended to put this under 7'udiela, and to put trochiformis, which is a round bodied shell, under Perissolax. Even this, however, would have been wrong, since, as will be seen below, on obtaining more material I am obliged to separate it. 1876.] NATURAL SCIENCES OF PHILADELPHIA. 285 ? P. trochiformis, Tuomey (sp.). Pyrula, id., Tuomey, Proc. Acad. Nat. Science, 1855, p. 169. Tudicia, id., Gabb, Syn. Cret., p. 85. Shell moderately large, spire somewhat elevated; body whorl convex on the sides, sloping above, canal long and straight; sur- face marked by prominent acute revolving ribs, about nine on the body whorl and others pretty regularly placed, to the end of the canal; between these are concave interspaces, and those on the body whorl are, in some specimens, crossed by faint longitudinal ribs. The inner lip is encrusted, and, just where the mouth con- tracts into the canal, bears a prominent bend like that in some of the Fasciolarias, but without folds ; or better, resembling somewhat Busycon. Length 3.75 inches; width 2.0 inches. A fossil, common as casts in New Jersey, and in the white lime- stones of Alabama. The above description is from a specimen in the Museum of Yale College, from Uniontown, Ala. It is the only one showing the entire surface, that I have ever seen, and also the only one retaining its entire canal. I have long had doubts as to the generic relations of this shell, and have referred it provisionally to Pyropsis, since that is the nearest clearly defined genus. The columella of my specimen is not perfect enough to warrant me in asserting that the inner lip may not be like that of Pyropsis, though I think, as described above, it is more like that of Busycon. Should this eventually prove to be the case, the species, with probably both the following, must be separated as a distinct genus, for which the name T’ro- chifusus would not be inappropriate. P. septemlirata, Gabb. Cancellaria, id., Gabb, Proc. Acad. 1860, p. 94, pl. 2, f. 10. A shell closely allied to the preceding, and also marked by revolving sculpture, but differing in having a much lower spire, less globose body whorl, tapering into the canal much more regu- larly in front. The species was described from internal casts, from the New Jersey marls, and in no case has the canal been preserved. Enough, however, has been obtained to show the peculiar curve of the columellar margin. P, Alabamensis, Gabb. Cancellaria, id., Gabb, Journ. Acad., 2s., v. 4, p. 301, pl. 48, f. 14. Also described from an internal cast, showing slight traces of longitudinal ribs. Another, smailer specimen, from Mississippi, 286 PROCEEDINGS OF THE ACADEMY OF [1876. also a cast, shows that the surface had both longitudinal and revolving ornaments. There were about 12 or 13 longitudinal ribs, crossed by eight or ten smaller, revolving ribs. This also shows part of a long, straight canal. The longitudinal ribs and the high spire separate this from all other species yet known in the genus. I also have it, but in a very imperfect state, from New Jersey (Vincenttown, Col. Bryan). Votutip#, Fleming. Almost every author who has written on this family has sug- gested a different grouping of the genera, and no two fully agree in regard to the range of the genera themselves. Among the more modern writers, H. and A. Adams proposed three sub- families: Cymbiinex, Zidonine, and Volutine. Under the first, they place the genera Cymbium, Melo, with the subgenus Ausoba, and Aulica. In Zidonine, the genus Zidonia —Volutella; and in the last subfamily, genera Callipara, Cymbiola, Scaphella, with subgenus Alcithw, Voluta, Harpula, Fulgoraria, with sub- genera Aurinia, Lyria, with subgenera Hneta and Volutilithes. In the appendix to their work these authors change the arrange- ment, as follows :— Subfamily VOLUTIN &%. Genera CYMBIUM. MELO. ScAPHA. Subgenera Aurinia (Livonia, Gray). Aulica. Cymbiola. Alcithe. VOLUTA. Chlorosina. Harpula. FULGORARIA. LyYRIA. Harpella. Eneta. VoLUTILITHES. CALLIPARA. ZIDONA. Ausoba (Nobilia, Gray). Fricusa (Scaphella, G., not Sw.). 1876. ] NATURAL SCIENCES OF PHILADELPHIA. 287 Subfamily SCAPHELLIN A. Genus SCAPHELLA (Amoria, Gray). They also adopt Dr. Gray’s subfamily Volulimitrine for the genus Volutimitra. Dr. Gray, in the Guide to Systematic Distribution of Mollusca in the British Museum (1857), proposed a somewhat different arrangement, as follows :— a. VOLU TINA. +YETINA. 1.) Yaarus. 2. CYMBIUM. 3. ScAPHA. 4, FULGORARTIA. Genera 5. CALLIPARBA. 6. VOLUTA. 7. Lyria. Subgenera Lyria. Enexta. 8. VOLUTELLA. +tAMORIANA. 9. AMORIA. b. VOLUTIMITRIN &. 10. VoLUTIMITRA. And finally the subfamily PorceELLANina, made up of Porcel- lana (= Marginella), Closia (—Volutella, Sw.), and Persicula. This latter group must be thrown out. In 1873, Dr. Theodore Gill proposed an arrangement of the Families of Mollusca, in which he separates the family into two groups :— ea alent! ie teneeees Gray. Amoriana, Gray. Ay alnt eee cae. Gray. Yetina, Gray. This division, as I have been personally informed by the author, is based on the dentition; a character not always the most reliable, though in this case it seems to be sustained by the others. 288 PROCEEDINGS OF THE ACADEMY OF [1876. Reversing the position of the groups, as placed by Dr. Gill, it seems to me that the following genera include all of the known species, and are sufficiently clearly circumscribed :— Subfamily VOLUTIN A. CymBiuM, Klein, Auct. Yetus, Adams, Gray. Meo, Humph. Type Voluta melo. Scapua, Gray (not Humph. nor Klein). Subgenus Aurinia, H. and A. Ad. Type S. dubia. AULICA, Gray. Ausoba, H. and A. Ad. Type V. aulica. VoLutTeLia, D’Orb. 1839. Zidona, H. and A. Ad. Type V. angulata. H.and A. Adams have renamed this genus because the name Volutella was preoccupied both by Perry and Swainson. But since neither of their names stand, D’Orbigny’s, being the oldest, must, and Zidona becomes a synonym. CALLIPARA, Gray, 1847. Type C. bullata. CYMBIOLA, Sw. 1853. Type C. ancilla. AtcitHa, H. and A. Ad. 1853. Type V. fulgetrum. VouuTa, Linn. Harpula, Sw. Type V. musica. Although V. vexillum, Swainson’s typical species, looks suffi- ciently unlike V. musica to have warranted a separation, it only requires a study of a large series of specimens, of the few species in this group, to satisfy one that the division has not even a sub- generic value. V. musica alone varies through half a dozen spe- ss eK Oe 1876.] NATURAL SCIENCES OF PHILADELPHIA. 289 cific names, some of the extreme forms almost as round as vexillum. I have fossil specimens from the Pliocene of Costa Rica, almost exactly the shape of V. verillum, without a tubercle on the angle of the whorl, and marked with as many folds on the inner lip as a Cyprea.' FuLGoRARIA, Schum. 1817. Fulguraria, H. and A. Ad. Type F. rupestris, Gm. VoLuroperMA, Gabb. New genus. Shape similar to Fulgoraria, which it also resembles more or less in surface sculpture; apex not papillate; inner lip marked by from three to five well-marked folds, not very oblique, and of pretty uniform size. This is a group of shells characteristic of the cretaceous rocks, and, perhaps, peculiar to them. They are all somewhat slender, and are marked by longitudinal ribs, not always well defined, and by revolving ribs ; the columella is always straight or nearly so, and the folds are as isolated and distinct as those of Turbinella. But the most strongly distinguishing cha- racter is the entire absence of the irregularly rounded mass at the apex of the shell, one of the best characters of Fulgoraria. The species have been referred to Voluta, Volutilithes, Fulgoraria, and even Fasciolaria. V. Navarroensis, Shum., Gabb, Paleontology of California, vol. i., pl. 19, f. 6, may be taken as the type. The genus includes such species as— V. elongata, d’Orb. sp. Voluta, id., d@’Orb., Pal. Fr. Cret., v. 2, p. 323, pl. 220, f. 3. Volutilithes, id., Stol., Sitz. Akad. Wien., lii. p. 74. Fulguraria, td., Stol., Pal. Ind., p. 87, pl. 7, f. 1-9. Voluta Trichinopolitensis, Fbs., Tr. Geol. Soc. Lond. vy. 7, p. 133, pl. 15, f. 5. This shell is very variable in height, and carries three equal columellar folds. Specimens before me, sent to me by Dr. Stoliezka, from Trichinopoly, show that the apex is as acute as in my Cali- fornian shell. Another shell, accompanying this, marked Fasciolaria rigida, Stol., bi. cit., p. 109, pl. 10, f. 10-16 (Voluta rigida, Baily), evi- ' For further remarks on this subject see Crosse, Journal de Conchy- liologie, vol. 19, p. 271. 290 PROCEEDINGS OF THE ACADEMY OF [1876. dently also belongs to this genus, as well as do Fasc. carinata, Stol., and F. assimilis, Stol. AvuriniA, H. and A. Ad. 1853. Type A. dubia. VoOLUTOMORPHA, Gabb. New genus. Shell elongate, fusiform; whorls cancellated by longitudinal and revolving ribs. Columella with one very oblique fold, and sometimes one or more smaller secondary folds. In shape this genus is not unlike the two preceding genera, but it differs from them all in having essentially a single large oblique fold. When more than one occurs, the secondary folds are smaller than the large primary. Type Volutilithes Conradi, Gabb, Journal Acad. Nat. Sciences, 2s., v. 4, pl. 48, f. 10. V. cRETACEA, Con., loc. cit., pl. 47, f. 18, also belongs to this genus, and V. Delawarensis, Gabb, Proc. Acad. 1861, p. 322. RostELLitTEs, Con. 1855. Type &. Texana, Con., Emory’s Report, Mexican Boundary Sur- vey, p. 158, pl. 14, f. 2. A curious genus, the most slender of the Volutes, with numer- ous equal plaits on the columella, and with the outer lip somewhat expanded anteriorly. Vo.utirusus, Con. 1866. Type V. typus, Con., J. Conch., 1866, p. 67, pl. 3, f. 2. Very characteristic of the Miocene. Lyria, Gray, 1847. Type L. Delessertit. Enata, H. and A. Adams, 1853. Types L. Cummingii, harpa, ete. Marked by a tooth in the middle of the outer lip, seems to be but a division of Lyria. VoLuTILitHEs, Swains, 1831. Type V. abyssicola. A genus abundant in the Eocene rocks, perhaps found in the Cretaceous, and represented in the living fauna by but a single species. 1876.] NATURAL SCIENCES OF PHILADELPHIA. 291 ATHLETA, Con., 1853. Types A. rarispina and A. Tuomeyi, Con., J. Acad., 2s. v. 4, pl. 47, f. 35. A form separated by Conrad from Volutilithes on account of a heavy callosity deposited on the spire above the aperture. LEIopERMA, Conrad, 1865, Proc. Acad., 1865, p. 184. Type L. leioderma, Con., J. Acad., 2 s. v. 4, p. 292, pl. 46, f. 32. Includes also Volutilithes cretacea, Con., loc. cit., v.38, p. 333, pl. 35, f. 16. Subfamily SCA PHELLIN &, H. and A. Ad. Volutimitrine, Gill; Volutimitrina and Amoriana, Gray. ScAPHELLA, Swains., 1832. Amoria, Gray. Type S. Junonia. Vo.utTtirusus, Con., 1866. Type V. typus, Gon., Jz Conch:, 1866) pi 67, pl.'3, f. 2: Very characteristic of the Miocene, but does not include /. Junonia, as Mr. Conrad intimates. VoLuTIMITRA, Gray. Types V. Grenlandica. In addition to the above, there are perhaps several other genera among the fossil Volutes. V. rarispina, Lam., with which I am only acquainted by published figures, may be an Ath/eta, or it may be new. It certainly cannot be placed in any other genus. The two shells, Athleta purpuriformis and A. scrobiculata, of Stoliczka, were referred to that genus from a misconception on the part of the author. They have not the characteristic callous, are subglobular, instead of being subfusiform and angulated, and the folds are very oblique, and on the anterior part of the columella. The genus might be called PrycHoris. Ficulopsis Stoliczka, Pal. Indica, p. 84, founded on Pyrula Pondicherriensis, Forbes, is a Ficus, with folds on the columella. I have just received from the Cretaceous of Georgia an allied form, with a flattened columella and with a single fold. I cannot agree with the Doctor in placing it in the Volutide. 292 PROCEEDINGS OF THE ACADEMY OF [1876. Megaptygma, Con., founded on a Miocene species, described by me under the name of Voluta sinuosa, differs only from Volutifusus in having the folds unusually heavy. Together with Mr. Conrad, I have compared it with several species of the latter genus, and find that some of the species, especially V. mutabilis, Con., vary so in this character, that we have agreed that the distinction is not a valid one. V. mutabilis varies not only in the presence and absence of folds, but also in their direction when present, and in the shape of the anterior half of the shell. Some specimens are perfectly straight in advance, while others are as twisted as the typical form of V. Junonia. In fact I am by no means convinced that Volutifusus should be separated from Scaphella. LEIODERMA, Con. L, canalis, Con. sp. Conus, id., Con., J. Acad., 2.8. v. 3, p. 331, pl. 35, f. 22. “olutilithes cretacea, Con., J. Acad., 2s. v. 3, p. 333, pl. 35, f. 16. Common at Pataula Creek, Clay Co., Ga. A long, slender, fusiform shell, with a polished surface, high spire, with the upper whorls faintly ribbed longitudinally. The outer lip is slightly thickened at its junction with the body whorls, and obliquely truncated in advance. The columella bears a single faint very oblique fold. Its surface, although polished, shows strong lines of growth. Mr. Conrad agrees with me in the above synonymy. I have a cast, apparently of the same species, from Crosswicks, New Jersey. VoOLUTODERMA, Gabb. 2 V, biplicata, Gabb. : Volutilithes biplicata, Gabb, Journ. Acad., 2 s. v. 4, p. 300, pl. 48, f. 6. Rostellites biplicatus, Meek, Cret. Check List, No. 690. But a single specimen of this species has ever been found. It shows none of the surface, but its form is so peculiar that it can- not be mistaken. Its two folds are in such a position that I have little hesitation in referring it to this genus. V. sp. indet. Another form occurs in the brown marls of Vincenttown, N. J., of which two internal casts have been found by Col. T. M. Bryan. In size and general shape it approaches Volutomorpha Conradi, but has three strong transverse folds on the middle of the colum- ella, From impressions on the inner face of the cast of the outer —— 1876.] NATURAL SCIENCES OF PHILADELPHIA. 293 whorl its surface is covered by small longitudinal ribs, crossed by numerous revolving lines, the characteristic sculpture of the genus. VoLuToMoRPHA, Gabb. V. Conradi, Gabb. Volutilithes, id., Gabb, Journ. Acad., 2s. v. 4, p. 300, pl. 48, f. 10. Rostellites, id., Meek, Cretaceous Check List, No. 691. The typical species of the genus. A common fossil in New Jersey. I have not seen it yet from other parts of our Cretaceous deposits. It is a long, slender, fusiform shell, a little variable in shape, but always slightly subangulated on the upper part of the whorl; the middle is gently convex, with the sides converging in advance. The canal is straight, and the columella bears one large oblique fold. Sometimes one or two smaller secondary folds occur. The surface is marked by numerous longitudinal ribs crossed by more closely placed revolving ribs. Impressions of this surface in the matrix, and on the inner face of the cast of the body whorl are not rare, but I had never seen even a piece of shell preserved until a few days ago, when Col. Bryan brought me a body volution with a third of its surface covered with well-pre- served shell. V. Abbotti, Gabb. ‘olutilithes id., G., Proc. Acad. Nat. Sci. 1860, p. 94, pl. 2, f. 7. The surface of this shell is as yet unknown. The columella, besides the large typical fold, carries also three smaller and more transverse ones above. V. Saffordi, Gabb. Volutilithes td., Gabb, Journ. Acad., 2s., v. 4, p. 300, pl. 48, f. 8. A strongly cancellated species, approaching the preceding in form. V. bella, Gabb. Volutilithes id., Gabb, Journ. Acad., 2s., v. 4, p. 300, pl. 48, f. 7. Rostellites id., Meek, Check List Cret. No. 689. A remarkably symmetrical fusiform shell, not very rare in New Jersey. Its surface is unknown. V. Kanei, Gabb, Voluta id., Gabb, Proc. Acad. 1861, p. 322. V. mucronata, Gabb. Voluta id., G., loc. cit. p. 322. 294 PROCEEDINGS OF THE ACADEMY OF [1876. ROSTELLITES, Con. R. nasutus, Gabb, sp., Meek, Check List, No. 692. Volutilithes id., G., Journ. Acad., 2s., v. 4, p. 300, pl. 48, f. 9. This shell has normally three folds on the columella, but I have seen specimens with five or six. it is the most slender of all the Volutide of New Jersey, and can be distinguished, even in casts, by the entire absence of longitudinal ribs or plications. Prof. Geo. Cook, State Geologist of New Jersey, who has loaned me all the desirable specimens of the survey collection, has at last obtained this shell, showing the surface. Unlike most of the marl fossils, these specimens, of which there are several, are fossilized, so that, while all shell structure is destroyed, being replaced by marl, the surface characters are perfectly preserved. The species is characterized by about 17 or 18 elevated, thin, revolving ribs, those in advance placed very obliquely ; the interspaces are three or four times as wide as the ribs. All the specimens are more or less distorted, but enough remains to show that the outer lip was broadly expanded, and, perhaps, even very slightly everted in advance. From Pataula Creek, Clay Co., Georgia, Dr. Little has sent me some imperfect internal casts which seem to belong to this species, but which are unusually large. Better material may prove them to belong to a distinct species. Prycuosyca, N. gen. Shell like Ficus in shape; surface smooth (or sculptured ?); inner lip bearing one very oblique fold on the anterior part of the columella. This shell fills in a gap in the series of genera, and connects » Stoliczka’s genus Ficulopsis with the true Ficus. Ficulopsis has the same general style of sculpture as Ficus, but bears several plaits on the columella, so like some of the Volutes that Dr. Stoliczka united it with them in the same family. The present genus has a fold, but it is small and very oblique. The posterior notch, which the author mentions as doubtfully a generic character in his species, seems, from a study of ours, to be so. In Ficus, the outer lip shows a very slight trace of it; in our genus it is more marked, while in the Indian fossil it develops into a regular Pleurotomoid sinus. 1876. ] NATURAL SCIENCES OF PHILADELPHIA. 295 P. inornata, n.s., pl. 17, f. 2, 3, 4. Shell small, regularly convex; spire small; number of whorls unknown (apex destroyed on the only specimen); suture nearly obsolete; surface without other marks than faint lines of growth; body whorl convex above, tapering in advance, slightly constricted by a broad, shallow, revolving groove in advance; canal short, notched in advance; outer lip very slightly notched posteriorly, immediately adjoining the suture; inner lip thinly encrusted and bearing one very oblique fold. Length about 1.5; width about .75. The specimen is com- pressed, so that, with the loss of the tip of the canal, the measure- ments can be only approximate. The lines of growth, which are distinct, enabled me to ascertain the details of the anterior end. A single specimen from the Ripley group, Pataula Creek, Georgia; Dr. Little. GyropEs, Con. G. abyssinis, Morton (sp.). Natica id., Morton, Syn. Cret. p. 49, pl. 18, f. 13. Gyrodes id., Gabb, Syn. Moll. Cret. p. 59. Described originally from Prairie Bluff, Ala. We did not know the surface of this shell, until now I have received from Dr. Little specimens from the Ripley group, from Pataula Creek, Georgia. The surface is perfectly plain, slightly flattened adjoining the suture, and with the umbilical margin rounded. It is marked only by lines of growth, and has none of the crenation of the upper edge, characteristic of Conrad’s species G. crenata. It also occurs, though rare, in New Jersey. G. petrosa, Morton, (sp.). Natica id., Morton, Syn Cret. p. 48, pl. 19, f. 6. Gyrodes id., Conrad, Journ. Acad., 2 s., v. 4, p. 289. G. alveata, Con., loc. cit. p. 289, pl. 46, f. 45. Originally described from internal casts from Prairie Bluff, Ala. Mr. Conrad’s species, from the Ripley group of Mississippi, was described from shells retaining their surface. They are identical, and we have the same species from Glassboro, N. J., from Colonel Bryan, and from Mullica Hill, whence it was brought by Mr. John Ford. 296 PROCEEDINGS OF THE ACADEMY OF [1876. AMAUROPSIS, Morch. A. paludineformis, H. and M. (sp.). Natica id., H. and M., Mem. Am. Acad., Boston, v. 5, p. 389, pl. 3, 1 By A. id., M. and H., Proc. Phil. Acad. 1860, 185. In the Academy’s museum are half a dozen specimens of this species, brought by Mr. Conrad from Haddonfield, N. J. LunatiaA, Lam. L. rectilabrum, Con. There is yet some confusion about this species. Mr. Conrad described it as a Natica in the Journal Phil. Acad. 2 ser. vol. 4, p. 344, pl. 35, f 28. In my synopsis of Cretaceous Mollusca, I placed it as asynonym of Hall and Meek’s concinna. In Hayden’s report, Mr. Meek refers it to H. and M.’s obliquata, and separates concinna and obliquata on the ground that the latter has an oper- cular groove, wanting in the former. This hardly seems to me to be a valid specific difference, and I believe the synonymy should stand as follows :— L, obliquata, H. and M. (sp.), Meek, Cret. Check List, No. 672. Natica, id., H. and M., Mem. Bost. Acad., v. 5, p. 389, pl. 3, f 1. N. concinna, H. and M., loe. cit., p. 889, pl. 3, f. 2. N. moreauensis, M. and H., Proc. Acad., 1856, pp. 64, 282. Lunatia concinna, Meek, Hayden’s Rep., p. 314. N. rectilabrum, Con., J. Acad., 2s. v. 4, p. 344, pl. 35, f. 28. NV. acutispira, Shum., Trans. St. Louis Acad., 1860, p. 597. It is common everywhere in the Ripley Group, and Dr. Little now sends it from Pataula Creek. The altitude of the spire, and the obliquity of the body whorl differ considerably in the eastern shell, as is frequently the case with Naticas, and, consequently, if — there is no difference except the presence or absence of a groove, and a slight one at that, made by the operculum on the pillar lip, the difference is too slight to divide them. N. acutispira of Shu- mard, of which I compared a specimen, some years ago, with the Atlantic form, also comes into this synonymy. Scaua (Klein), Humph. 1797. Scalaria, Lam., 1801. S. (Opalia) Thomasi, n. s. Shell slender, thin, subulate, whorls numerous, increasing gra- dually in size, rounded, and curving abruptly to the suture; surface —ee 1876.] NATURAL SCIENCES.OF PHILADELPHIA. 29% marked by numerous, small, very thin plates, and crossed by well marked though small revolving lines, base bordered by an angular carina. From the white limestone of New Jersey, a single speci- men given me by Prof. W. H. B. Thomas. Its nearest ally, S.(0O.) Sillimani, Morton, from Prairie Bluff, Ala., is a somewhat larger shell, with a wider apical angle, the varices, instead of being numerous thin plates, are fewer and thickened, and the revolving sculpture is much finer. From S. annulata, Morton, found with it in New Jersey, it can be at once distinguished by its much nar- rower apical angle, very much smaller size, and in the ornaments. In that species, in the adult stage, the ribs become rounded on their edges ; in the young shells they are squamose, though not so numerous, and the revolving sculpture is fine and closely placed. From the following species it can be known by the plates being smaller and thinner, by the revolving sculpture, which in this is marked, while in that it is either very fine or wanting. Further, in this species, the carina at the base of the whorls is merely a strongly marked angle, over which the longitudinal markings cross without change; the plates very regularly decreasing in promi- nence from the sides to the base of the whorls, and reaching the lip as mere threads. In that species the carina is a strong rib, and the longitudinal plates continue well elevated and thick to the end. I have not described the mouth, because in the only Specimen it is in great part broken away. From a trace in the umbilical region, it seems to have been bordered by the usual thickened lip. 8. (0.) cyclostoma, n. s. Shell smaller and slightly more slender than the preceding ; whorls seven, cross sections circular; surface marked by numerous prominent recurved ribs, one of which on each whorl is thickened, showing a periodical arrest in growth; between these ribs is very minute revolving sculpture, a little more distinct on the earlier whorls. Aperture circular, bordered by a very thick expanded lip; base of body whorl bordered by a strong rib. Length .55 inch, width .25 inch. In the large varices this is not unlike S. Sillimani, but it is distinguished by its smaller size, narrower whorls, less thickened longitudinal ribs, and by the base. In that species the base is much flatter, the revolving carina is less evident, and each rib, on 20 298 PROCEEDINGS OF THE ACADEMY OF [1876. the angle is reflexed back into a little lip or notch; these ribs also become much less distinct on the base. S. (0.) annulata, Morton. Scalaria, id., Morton, Synopsis, p. 47, pl. 3, f. 10. A character exists in this shell which has never been mentioned. It has a broad open umbilicus, bordered by an angle, as well marked as that of Architectonica, though, of course, not so large. I have yet another species from Georgetown, Georgia, from Dr. Little, nearest to S. annulata in the character of its ribs, but ap- parently more like S. Sillimanz, in the shape of the shell. It consists of only one whorl and a part of another imbedded in a hard rock and too imperfect for description. PUGNELLUS, Con. Dr. Little has sent me from the Ripley marl of Pataula Creek, Clay Co., Georgia, specimens of Conrad’s original Strombus densatus, Journ. Acad., 2 ser. vol. 3, p. 330, pl. 34, f. 6, which have enabled me to discover that it is a very different shell from that which the same author called Pugnellus densatus, in the 4th volume of the same work, p. 284, pl. 46, fig. 31. It is more than twice as large as adults of the latter species, the canal is straight, and the outer lip is not so thickened. The first species, that from the 3d volume, must retain the specific name, and that in the 4th volume must be renamed. I, therefore, name it P. typicus, since that species was the one for which the genus was first founded. More perfect material than I yet possess may even prove that P. den- satus may belong to my subgenus Gymnarus. ANcHURA, Con. A. arenarum, Morton, sp. Rostellaria, id., Morton, Syn. Cret., p. 48, pl. 5, f. 8. R. arcuarium, QW Orb., Prod. Pal., v. 2, p. 227. Chemnitzia distans, Con., Journ. Acad., 2 s. v. 3, p. 333, pl. 35, f. 30. With the preceding, from Dr. Little. A. Texana, Roem., sp. Scalaria, id., Roem., Kreid von Texas, p. 39, pl. 4, f. 11 a-0. Chemnitzia, id., Meek, Check List, No. 658. cs ‘6 Gabb, Pal. Cal., vol. 2, p. 261. Aporrhais, id., Stoliczka, Pal. India, vol. 2, p. 281. Stoliczka says he examined, in the museum in Bonn, the original of Scalaria Texana, “and found that it was based upon an imper- 1876. ] NATURAL SCIENCES OF PHILADELPHIA. 299 fect specimen of an Aporrhais.” On re-examining my own speci- men of the species I see nothing incompatible with its belonging to the genus Anchura, a view which is sustained by Roemer’s figure, and doubtless Dr. Stoliczka found some remains of the expanded lip, or of the terminal ascending suture line. He did not understand the genus Anchura, restricting it to those species in which the outer lip bears two points, one posterior, the other running parallel with the canal. As I have shown elsewhere the genus cannot be so restricted, and there are not even valid grounds for retaining Meek’s Drepanochilus as a subgeneric division. Stoliczka called two species of Anchura by the name of Aporrhais, and, therefore, Iam satisfied that he meant this same group. The long, slender spire of the species in question is very like many species of Anchura, but is wholly incompatible with Aporrhais. Aporruals, Dillw. 2A. bicarinata, n. s. Shell small, spire elevated, number of volutions unknown; upper whorls bearing an angle in the middle, from which the surface slopes inward to the suture; below this angle it slopes very slightly outwards to the sutures below; body whorl bearing two angles on the middle, the upper slightly the largest; outer lip unknown, inner lip lightly encrusted, expanded, and slightly reflected, pro- ducing a groove which runs from the posterior angle of the aper- ture, parallel with the mouth, down to the canal. Width of body whorl, less the expanded lip, about 0.5 inch. This species is described from two fragments from Pataula Creek, Georgia, sent me by Dr. Little. They are so mutilated that I do not know the outer lip, the canal, nor the upper whorls of the spire. In fact, nothing remains except the body volution and the one adjoining it. Both show the very remarkable character of the inner lip, so that I am convinced it is not an accidental result of crushing. The form of the body whorl is very similar to the little shell described by Mr. Meek, from the Yellowstone region, under the name of Aporrhais biangulata. It has the same two earine, and, like that shell, is smooth, unlike it, not showing, under a magnifying glass, any trace of sculpture. The most marked dif- ference exists in size, our species being larger than Meek’s magni- fied figure (Hayden’s Report, pl. 19, fig. 6b). Another difference occurs in the spire. In that all of the upper whorls are rounded, 300 PROCEEDINGS OF THE ACADEMY OF [1876 in this the upper carina of the body whorl is continued on the mid- dle of the upper whorls, the suture following the lower carina. The peculiar character of the inner lip is not mentioned in Mr. Meek’s description, as it certainly would had it been present. As to the generic relations of the present species, it may belong to Apor- rhais, and I have so referred it on account of its close specific relation to the Northwestern species, or it may prove to be an Anchura. In this group the generic determination cannot be certain until we have all of the parts of the perfect adult shell, the classification resting almost entirely on the manner in which the adult forms its mouth. TURBINOPSIS, Con. This genus seems to be not remote from Trichotropis, resem- bling the subgenus [phine in form, but differing in having a thick sheil, and in bearing a rather obscure fold on the inner lip close to the anterior end. This fold is not visible externally, but can be seen if the outer lip is broken away or on casts. T. Hilgardi, Con., Journ. Acad., 2d ser., vol. 4, p. 259, pl. 46, fig. 29. Cancellaria, id., Gabb, Syn. Cret. Moll., p. 42. T. depressus, Gabb, Proc. Acad., 1861, p. 321. Found in New Jersey, Delaware, Alabama, and Mississippi. My name given to casts from New Jersey must stand as asynonym. Gyrotropis. New genus. Shell thin, resembling YTrichotropis in form, spire elevated ; umbilicus open like in Iphine and Turbinopsis; surface biangu- lated like in the typical form of T'richotropis, but covered also with numerous very thin foliated varices like Murex. A peculiar genus, combining a series of characters which ally it closely to Trichotropis, but markedly different in the presence of thin plates covering the surface, and expanded to an unusual degree. G. squamosus, n. s., pl. 17, fig. 5. Shell moderate in size, turbinate; spire about as high as the length of the mouth, whorls eight, apex acute, body whorl bicari- nate, the carina high and very thin; outline sinuous in front to the umbilical margin, concave between the carine and above the upper one to the suture; upper carina carried on the middle of 1876. ] NATURAL SCIENCES OF PHILADELPHIA. 301 all the upper whorls to the apex; suture channelled, the channel formed by the upper surface of the lower carina, the succeeding whorl being soldered to the outer edge of the plate-like ridge; umbilicus open, narrow, deep, bordered by the sharp, acute angle of the base of the volution; surface ornamented by numerous very thin, squamose, murex-like varices, most marked on the an- terior part of the shell, these are all crossed by closely placed revolving lines, somewhat alternated in size. Aperture broad, outer lip thin, inner lip rather heavily encrusted. Length, 1.1 inch; width, 0.9 inch. From Snow Hill, North Carolina, from the Ripley marl. Col- lection of the Academy. TURRITELLA, Lam. T. encrinoides, Morton, Synopsis, p. 47, pl. 3, fig. 7. Pataula Creek, Georgia, Dr. Little. LAXIsPIRA. New genus. Shell spiral, dextral, whorls with a circular cross section, few in number, and so rapidly descending as to form an open spiral; aperture simple, lips thin. A curious genus, the relations of which are not clear to me. I propose it to receive some shells which have been long known as internal casts in the marls of New Jersey, but of which the sur- face was unknown until quite recently. In general form they might be compared toa partially uncoiled Turritella. From that genus they differ, however, in the whorls not being in contact, and from Vermetus and the allied genera in being regular spirals, but not having the apex either turritelloid or attached. Another analogy, though perhaps only one of external resemblance, might be adduced in such shells as Huomphalus circinalis, Goldf., or in some of the Delphinulas. L. iumbricalis, n. s., pl. 17, f. 6, 7. Shell with a circular cross section, whorls about as far apart as the diameter of the whorls, three or four in number; surface marked by numerous small, closely placed revolving ribs. This description is from a small specimen from the Ripley marl from Haddonfield, N. J., presented to the Academy by Mr. Con- rad. Casts over two inches long and about half an inch in diam- 302 PROCEEDINGS OF THE ACADEMY OF [1876. eter of aperture are common in the glauconite marl, and appa- rently belong to the same species. Brvontia, Gray. 7B, cretacea, n s. Shell tubular, irregularly coiled in the young stage; curved, straight, or irregular as it grows older; surface irregularly wrin- kled by lines of growth; aperture circular, substance thick. Average diameter of shell .25 inch to .3 inch. I propose this name for a shell consisting of a contorted tube common in the Ripley marls, and which shows so few characters that it is hard to describe it. I have never seen any signs of at- tachment, and no two specimens are of the same shape. Dr. Little has sent me a good series from Pataula Creek, Georgia. EnpopryaMa. New genus. E. umbilicata, Toumey (sp.), pl. 17, f. 8, 9. Phorus umbilicatus, Toumey, Proc. Acad., 1855, p. 169. This shell was described by Tuomey from internal casts well known in the Cretaceous of Mississippi and Alabama. It differs from the typical Phorus, Montf. (Xenophora, Fisch.) in having a strong revolving plate inside, nearly midway between the umbili- eal and outer margin on the base, leaving a groove on the cast. The irregularly pitted upper surface shows that the shell agglu- tinated foreign bodies to its surface in the same manner as in the genus from which I propose to separate it. Figure 8 shows the position of the internal plate, as represented by a groove on the cast; figure 9, a side view of a smaller specimen. ATAPHRUS, Gabb. Paleontology of California, vol. 2, p. 171. Additional material has enabled me to become better acquainted with this genus, and obliges me to modify a little the generic description. The inner lip is rounded above, on the body whorl, and merges ingensibly into the adjoining surface, covering up the umbilicus; but, instead of being round all of the way down, as described, it ends abruptly just at, or a very little in advance of, the umbilicus, in a little tubercle, on the outer or front face of the pillar, below which the lip is slightly grooved. The position I 1876.] NATURAL SCIENCES OF PHILADELPHIA. 303 assigned it, associated with Oxysfele and Photinula, is correct, it differing from the former in having the tubercle and the anterior groove, instead of being flattened; and in wanting the angular termination of the latter. The figure of A. crassus is incorrect, in that it makes the pillar lip round all of the way down. A. compactus, Gabb. Littorina, id., G., Pal. Cal., v. 1, p. 131, pl. 20, f. 89. This is a member of the genus, but the figure and description are incorrect in the one character of the inner lip. Better speci- mens than the original (which, like that of A. crassus, were slightly weathered) show that the groove should only have been represented as extending half way up the inner lip, the upper half being regularly rounded and terminating in the tubercle mentioned. The anterior end of the mouth also is rounder than the figure. In addition to the above, I have another species from the creta- ceous of North Carolina. This shell, from the character of its fossilization gives us another character, the pearly structure; an additional proof of its family affinities, and one which was not attainable in its Californian congeners. Aekerri,n. 8) Pl: i7; £10: Shell small, turbinate ; spire slightly elevated, whorls five, con- vex above and below, and obscurely angulated in the middle; suture well marked, following the angle in all the upper whorls, but in the adult shell, for the last fourth of a volution, descending at a slightly increased angle. Entire surface covered by small closely placed revolving ribs with acute interspaces. Aperture circular, outer lip retreating very obliquely from the suture and then regularly curving downwards on the middle of the upper half of the whorl; edge acute. Inner lip covering all of the minute umbilicus and then truncated abruptly, a little in advance, as described above. Height 0.15 inch; diameter 0.21 inch. A beautiful little shell, closely allied to A. compactus, but dif- fering in being less elevated, in the subangulated whorls, in the more rapidly descending suture, near the mouth, and in the sculp- ture. In compactus the sculpture is a series of rather strong, though small revolving ribs. In A. Kerri the ribs are so close together, and the interspaces so small that in one case they be- 304 PROCEEDINGS OF THE ACADEMY OF [1876. came nearly obsolete. In another, however, they are stronger, approaching the Californian shell. A. crassus differs from this Species in the entire absence of revolving sculpture and of angu- lation, and in its more sloping top. TuRNus, Gabb. > Subgenus Xylophagella, Meek. T. (X.) contortus, Gabb. Teredo contorta, G., Proc. Acad., 1861, p. 323. A study of the valve of this species shows it to be an allied species to 7. (X.) elegantula, but more oblique, and differing in sculpture. Marresta, Leach. M. cretacea, Gabb. Pholas, id., Gabb, J. Acad., 2s. v. 4, p. 3938, pl. 68, f. 18 (tube). 7., G. Proc. Acad., 1861, p. 324 (shell). Rare in the marls of New Jersey. The tubes are occasionally found perforating wood, but replaced by pyrites. I have before me an excellently preserved shell with both valves in contact, and which shows clearly the generic characters. M. cithara, Mort. sp. Pholas, id., Morton. Syn. Cret., p. 68, pl. 9, f. 2. P. pectorosa, Con., J. Acad., 2s. v. 2, p- 293, pl. 24, f. 9. Equally rare with the preceding. I have never seen but the two respective types. LEPTOSOLEN, Con. L. biplicata, Con., J. Conch., v. 3, p. 15. Siliquaria, id., Con., J. Acad., 2s. v. 3, p. 324, pl. 34, f. 17. Not rare on Pataula Creek, Clay Co., Georgia, Dr. Little. LEGUMEN, Con. L. planulatus, Con. (sp.). Solemya, id., Con., J. Acad., 2s. v. 2, p. 274, pl. 24, f. 11. Legumen, id., Gabb, Syn. Cret., 1861, p. 133. L. elliptica, Con., Journ. Acad., 2s. vy. 3, p. 325, pl. 34, f. 19. L. appressa, Con., loc. cit., p. 325. A fine shell growing three inches long; several specimens from Pataula Creek, Georgia. It is one of the most widely diffused species in the Ripley marl. On comparing the various types of the above names, I find that the names have been given to dif- 1876. ] NATURAL SCIENCES OF PHILADELPHIA. 305 ferent ages of the same shell. The lines of growth at the same age in all the forms have the same direction. PrERIPLOMYA, Con. Leptomya, Con., Nat. Ad. Plicomya, Stol. P, elliptica, Gabb. Anatina, id., Gabb, Proc. Acad., 1861, p. 324. I place this shell under the above generic name, in accordance with the opinion of Mr. Conrad, who has examined seven original specimens, and recognized its generic relations. It isan extremely rare shell. ; SotyMa, Con. Not Solemya (as in index). S. lineolatus, Con., Journ. Conch., vol. 6, p. 75, pl. 3, f. 9. Mr. Conrad has identified for me, under the above name, a little shell out of the Georgia collection of Dr. Little, from Pataula Creek. It is a little more than half as wide as long, the beak is median, the two ends are very nearly equal, and the base is very slightly convex. Although mine is a left valve, 1 am unable to describe this part of the hinge, since, in cleaning away the marl, the teeth were destroyed. These fossils are so fragile that, until after being hardened by gum, a breath will almost destroy them. Mr. Conrad, who cleaned this hinge, saw the teeth just at the moment of their destruction. PHOLADOMYA, Sby. P. Littlei, n. s. Shell very large, gibbous, beaks large, prominent, nearly in contact, placed about a third of the length from the anterior end. Base irregularly convex, most prominent a little behind the mid- dle, from which it slopes up with a broad gentle curve to the anterior end ; posterior end broader than the anterior and gaping. Surface marked by about a dozen large acute ribs, with broad concave interspaces. The anterior end is not costate, or very faintly so; the first well-marked rib descends directly from the front part of the umbone directly to the base, curving slightly forward at its lower end. The strongest ribs are on the middle of the shell, and they are somewhat more widely placed, and become more oblique posteriorly. 306 PROCEEDINGS OF THE ACADEMY OF [1876. Length 6 inches, width from beak to base 4 inches, diameter of both valves 3 inches. This is the finest species of the genus with which I am ac- quainted, and I dedicate it with pleasure to Dr. Little, State Geologist of Georgia, who sent me three well-preserved specimens, one retaining the greater part of its surface, from Pataula Creek, Clay County. It can be at once recognized by its few large ribs, increasing rather than diminishing in size posteriorly, and in being less oblique than P. occidentalis, Morton, the only other large species known in America. It is twice the linear size of that shell. CYMBOPHORA, Gabb. C. lintea, Con. sp. Cardium (Protocardia) linteum, Con., J. Acad., 2s., v. 4, p. 278, pl. 46, f. 17. Veleda, td., Con., Journ. Conch. 1871, p. 74. Veleda, id., Con., Kerr’s Geol. Rep. N. Car., p. 9, pl. 1, fig. 26. Dr. Little sent me a good suite of this species, and on uncover- ing the hinge, I cannot find any valid difference between it and my typical form, on which to base a generic separation, unless it be on a peculiar cross striation of the lateral teeth, which I did not observe in the Californian shells. The species attains a large size. One specimen measures: length 4 inches, width 3 inches, depth of single valve 1 inch. In its young state it is thin, but becomes quite thick as it grows older. I have ventured to asso- ciate these large specimens with Mr. Conrad’s species, although in all of them the hinges are destroyed; but I can find no good grounds either in form or surface markings for separating them. My smaller specimens on which I identified the species are an inch and a half long. ScHIZODESMA, Gray. ? §, appressa, n. s. Shell small, subtriangular, flattened, thin; beaks sub-central, a little in advance of the middle ; anterior end rounded ; posterior end produced, subtruncated, cardinal margins sloping rather rapidly from the beaks ; base broadly convex ; a distinct umbonal ridge runs from the beaks to the posterior basal angle; and one less marked runs nearly parallel with the posterior cardinal mar- gin to the upper angle of the truncated posterior end. Surface marked only by lines of growth. The hinge agrees better with 1876. ] NATURAL SCIENCES OF PHILADELPHIA. 307 the above genus than with any other described ; in the left valve the V-shaped tooth is delicate, though well marked, and encroaches slightly on the deep ligament pit ; the lateral teeth are very small, short, and thin. The species can be at once distinguished from the preceding by its shape. Length 1.2 inch ; width 0.9 inch. A rare species, from Pataula Creek, Georgia ; Dr. Little. TENEA, Con. T. pinguis, Con. (sp.) Lucina, id.,Con., Journ. Acad., 2 ser., vol. 2, p. 275, pl. 24, fig. 18. Diplodonta parilis, Con., loc. cit., vol. 4, p. 278, pl. 46, f. 16 (not 8 as in text). Mysia gibbosa, Gabb, loc. cit., vol. 4, p. 802, pl. 48, f. 17 (not f. 18 as in text). Tenea parilis, Con., Journ. Conch., v. 6, p. 78, pl. 3, f. 12, ¢d., Con., Kerr’s Geol. Rep. N. Car., p. 8, pl. 2, f. 25. Mr. Conrad and I redescribed this species simultaneously in the 4th volume of the Academy’s Journal, both of us overlooking the fact that it had been previously described as a Lucina and with a bad illustration. It does not possess the angular base given to it in vol. 2. TELLINA, Linn. Tellinella, Gray. T. (T.) Georgiana, n. s. Shell moderately large, elongate; beaks central, elevated, ante- rior end produced, rounded ; base very slightly convex ; posterior end subangulated below, arched above; a strong umbonal ridge runs from the beaks to the angle. Surface destroyed on the only specimen I have seen. Length 2.6 inches ; width 1.25 inch. The impression of the hinge is preserved in the matrix, and the shell is so strongly characterized by its form that I have not hesi- tated to describe it. It is from Pataula Creek, Georgia, in a hard calcareous marl. GARI, Schum. G. elliptica, n. s. Shell moderately large, very thin, subelliptical in outline; beaks central, somewhat elevated; anterior end prominent above the middle, retreating below with a gentle curve to the base; 308 PROCEEDINGS OF THE ACADEMY OF [1876. posterior end rounded, broader than the anterior ; base most pro- minent a little in advance of the beaks. Surface marked by irregular lines of growth. Ligamental grove strongly marked ; hinge consisting of two teeth in the right valve and one bifid tooth in the left. Length 2.4 inches; width 1.5 inch. This shell resembles in size and general shape G. texta, Gabb, of the Californian cretaceous, but is not so narrowed anteriorly ; is less obliquely truncated posteriorly, and the beaks are more ele- vated ; it also differs in the surface. From the Ripley marl, Pataula Creek, Georgia. PERONZODERMA, Poli. P. Georgiana, n. s. Shell small, thin, flattened ; elongate, beaks subcentral ; in one case in the middle, in another a little posterior; cardinal margins sloping about equally towards both ends. Anterior end promi- nently and narrowly rounded ; posterior rounded, subtruncate ; base broadly and regularly convex. Surface marked by fine, regular concentric lines. Hinge composed of minute teeth. Length 1.2 inch; width 0.8 inch. Intermediate in form and size between 7. Hoffmani and T’ longa of the Californian cretaceous and differing from both in having the posterior cardinal margin convex, instead of concave. In this character and in the rounded base, it differs also from Gneplana, Conrad, of the N. Carolina Cretaceous. Two specimens from Pataula Creek, Georgia; Dr. Little. CYPRIMERIA, Con. C. depressa, Con., Kerr’s Rep. Geol. N. C., p. 9, Palwontology. Dosinia depressa, Con., J. Acad., 2s., v. 4, p. 278, pl. 46, f. 6. Sanguinolaria cretacea, Con., loc. cit., p. 277, pl. 46, f. 11. C. Cretacensis, Con., J. Conch., 1867, p. 9. C. cretacea, Con., J. Conch., 1869, p. 98, not C. cretacea (Dosinia) Zittel, Con., J. Conch., 1866, p. 102. Dosinia Haddonfieldensis, Lea, Proc. Acad. 1861, p. 149. Georgia specimens, from Doctor Little, differ only from those from Alabama in being nearly twice the size. C. torta, n. s. Shell large, discoidal, inequivalve, the right valve more convex than the left; beaks in advance of the middle; anterior end and 1876.] NATURAL SCIENCES OF PHILADELPHIA. 309 base regularly rounded; posterior narrowed, truncated and strongly deflected to the left side, more so below than above. Surface unknown. An internal cast from Georgetown, Ga., from Dr. Little, measur- ing : length 3.0 inches, width 2.5 inches, internal diameter of valves 1.0 inch. From C. densata, Con., the present species can be at once dis- tinguished by its being shorter and in having the posterior cardi- nal margin nearly straight. From C. excavata, Morton (sp.), by being more quadrate and longer. From C. Texana, Roem. (sp.), in being narrower and more produced behind. I have casts from Texas of another species approaching this, certainly a different species, but too close to describe without more material than mere internal casts. Carpivum, Linn. Subgenus Pachycardium, Con. Stoliczka does not approve of Conrad’s genus Pachycardium, and is inclined to associate it with Pseudocardia. The type P. Spillman, if it does not stand as a separate genus, should rather be placed with ZLevicardium than with Protocardia, since it has no ribs on the posterior face and only half a dozen obsolete radiat- ing lines on the umbonal angle. It is clearly not a Levicardium, from which it is separated by its very thick shell structure, its elongate form, and by the irregular transverse corrugations follow- ing the lines of growth. Most if not all of the Levicardia are thin, delicate shells with polished surfaces. Whether the East Indian bisectum belongs to this genus or not, C. Spzllmanz should, in my opinion, be taken as the type of a separate genus, or sub- genus. Casts are not rare in a sandstone at Georgetown, Georgia. They show that the hinge teeth were enormously developed, especially the laterals; the muscular scars are very deep and, in advance of the posterior muscle, there is a thickening of the shell, broad and rounded and occupying the position of the plate of Cucullza. The posterior portion of the internal margin is crenu- lated, but more closely than the part corresponding to the ribs on the umbonal ridge. The species is also found as casts in the brown and black marls of New Jersey, and associated with them I have a cast, more globose than any of the specimens that can be 310 PROCEEDINGS OF THE ACADEMY OF [ 1876. referred to Conrad’s species. It is of the same size, shows traces of the same surface markings, but is broader, rounder, and has the beaks much nearer and more incurved than the internal moulds of either the other Jersey specimens, or those of Mr. Conrad from Mississippi. Subgenus Vrachycardium, Morch. C. (T.) Carolinense, Con., Kerr’s Rep. Geol. N. C. Palxont., p. 7, pl. 2, f. 1. A larger shell than C. Hufaulense, Con., more circular in outline and less angulated on the umbonal ridge. It is very closely related, however, and requires care and good specimens to distin- guish it. Not rare at Pataula Creek, Georgia; Dr. Little. C. (I.) Eufaulense, Con. Cardium (T.) id., Con., Journ. Acad., 2s. vol. 4, p. 282, pl. 46, f. 12. A single valve from Quitman Co., Georgia; Dr. Little. This shell is common in North Carolina. C. (I.) Alabamense, Gabb. Cardium multiradiatum, Gabb, Journ. Acad., 2s., vol. 4, p. 395, pl. 68, f. 29; not td., Sby., Darwin’s Geol. Obs. 8. A., p. 251, pl. 2, f. 16. All three of these shells differ from the typical form of Trachy- cardium in having smooth ribs, in which character they approach Cerastoderma, with which probably they might better be associated. GRANOCARDIUM, Gabb. C. (G.) Tippanum, Con. Cardium, id., Con., J. Acad., 2.s., vol. 3, p. 326, pl. 34, f. 8 b. Granocardium, td., Gabb, Pal. Cal., vol. 2, p. 266. : Casts of this species are not rare in a hard brownish sandstone at Pataula Creek, Georgia. CRASSATELLA, Lam. C. pteropsis, Con, J. Acad., 2s., vol. 4, p. 279, pl. 46, f. 5. A rare shell at Pataula Creek, Georgia, though very common in North Carolina. C. vadosa, Morton, Syn., p. 66, pl. 18, f. 12. C. Ripleyana, Con., J. Acad., 2s., vol. 3, p. 827, pl. 35, f. 3. C. lintea, Con , loc. cit., vol. 4, p. 279, pl. 46, f. 5. C. Ripleyana of Conrad is the typical form of the species, pre- viously described by Morton; convex on its posterior cardinal margin in the young state and straight or slightly concave below 1876.] NATURAL SCIENCES OF PHILADELPHIA. 311 towards the posterior angle. (C. linfea is a shell of the same species, having attained but half its full diameter. I am not sure but that C. Carolinensis, Con. (Kerr’s N. Carolina Report, Paleontological Appendix, p. 6), should also be put downas a synonym. I only know it from the figure in the report, but the shape is very close to lintea, and the identity of this, I have proven by a critical comparison of the original specimens. C. sp. indet. A cast in brown sandstone, sent by Dr. Little from Pataula Creek, Georgia. The impression of the hinge is perfectly pre- served, as well as most of the outline. It is two and a half inches long by two wide and rather flat. The posterior cardinal line is slightly arched throughout, and the posterior end broadly rounded. Ido not think it belongs to any described species, but refrain from naming it until better material is found. ANTHONYA, Gabb. Scambula, Con. Anthonya, G., Paleontology of Cal. 1864, p. 181, pl. 30, f. 236, a. Scambula, Con., Journ. Conch., 1869, p. 48, pl. 9, f. 7-8. On comparing my types of A. cultriformis, with those of Mr. Conrad’s S. perplana, it proves that they are generically identical, the hinges agreeing perfectly. There is only one difference, and that of minor importance ; my shell, which is very long, is slightly twisted, while Mr. Conrad’s, which is much shorter, is all on one plane. Oris, Dep. ? 0. Conradi, Gabb, Isocardia, id., G., Journ. Acad., 2 ser., vol. 4, p. 393, pl. 68, f. 21. LirHorHaaa, Bolt. Lithodomus, Cuv., Lithophagus, Muhlf. L. Ripleyana, Gabb, Proc. Acad., 1861, p. 326. L. affinis, G., loc. cit., p. 327. Arcoperna Carolinensis, Con., Kerr’s N. C. Rep., Pal., p. 5, pl. 1, f. 6. I named ZL. affinis,a form shorter, more convex, and a little curved, but I do not now believe that even a greater difference in form in a boring shell can be made the basis of a specific distine- tion, unless repeated in a very large suite of specimens. Mr. Con- 312 PROCEEDINGS OF THE ACADEMY OF | 1876. rad’s name must be placed as a synonym; his figure agrees ex- actly with specimens of my species, which is not rare. I have before me a large series, some showing the valves perfectly pre- served, and others bedded partially and entirely in fossil wood. INOCERAMUS, Sby. I. Tippanus, Con. (sp.). Pholadomya Tippana, Con., J. A., 2s8., v. 3, p. 824, pl. 34, f. 9. I. costellatus, Con., loc. ctt., p. 329, pl. 34, f. 12. A rare shell; very thin and marked by both radiating and con- centric sculpture. It is very inequivalve, as will be seen by the figure 12 above quoted. TricontA, Brug. T, Leana, Gabb. Trigonia Gibboniana, G., Pal. Cal., vol. 1, p. 190, pl. 17, f. 178; pl. 31, f. 262, not 7. Gibboniana, Lea, Trans. Amer. P. Soc., 2s., v. 7, p. 255, pl. 9, f. 7, 9. From the rather poor figure and imperfect description of Mr. Lea, quoted above, I made a doubtful identification of the Cali- fornian shell with the South American. Recently, while studying some fossils from Peru, Mr. Lea kindly placed his types at my disposal, and, among other errors I have been enabled to correct, is this one. Our two species are of the same type, but they differ very materially in the ornamentation. I have therefore renamed the Californian species. T. thoracica, Morton, Synopsis, p. 65, pl. 15, f. 13. From the Ripley of Pataula Creek, Georgia; Dr. Little. T. angulicosta, n. s. Shell small, elongate, curved; anterior end regularly convex; . base broadly rounded in the middle, slightly concave posteriorly ; posterior cardinal line concave; posterior end prolonged, truncate. Surface divided by a ridge, separating the corselet from the broader part; corselet crossed by transverse ribs, corresponding in number to those below; towards the end these are directed ob- liquely backwards. Outer surface divided into three parts; nearest the beaks it is marked on the anterior half of the adult shell by about ten or a dozen prominent ribs, most of which, after traversing half the distance from the corselet to the base, suddenly bend forward at a slightly acute angle, and terminate at the anterior 1876.] NATURAL SCIENCES OF PHILADELPHIA. 313. margin of the shell; posterior to these are about ten more ribs, which traverse the entire width, from the corselet to the base. On the anterior half of the basal margin are some short ribs, parallel with those last described, and which arise abutting against the lowest of the antero-posterior ribs, and reach the margin, be- coming oblique forward until the most anterior becomes nearly parallel with the rib against which it originates. Length 1.75 inch; width 1.3 inch. From Pataula Creek, Georgia; Dr. Little. This very peculiar shell has an internal cast not unlike 7’. tho- racica, with which it is found associated ; but its surface sculpture is unlike any other species with which I am acquainted. I have two fragmentary specimens before me, showing part of the surface but none of the antero-basal ribs described above. The details of the description are drawn from the impression of an entire surface in a hard sandstone. VENILIA, Mort. V. Conradi, Morton, Syn. p. 67, pl. 8, f. 1-2. A cast of this species occurs in the same block with one of the casts of the preceding. IponEARCA, Con. A genus represented in the Cretaceous of New Jersey alone by about a dozen species. Some of these are as yet undescribed for want of sufficient material, and most of them are known only from internal moulds. I. vulgaris, Morton (sp.). Cucullea, id., Morton, Syn. Cret., p. 64, pl. 3, f. 8, and pl. 13, f. 5. The commonest species. Casts (pl. 13, f. 5) are abundant in the marls, and are known as “squirrel heads” by the country boys. The cast is recognizable by its oblique form and prominent remote beaks. Dr. Morton described the shell from specimens from Arneytown, N. J. (pl. 3, f. 8). It is variable in its obliquity and convexity, the umbonal ridge being sometimes arched backwards and sometime straight, as seen from the side; the posterior face is nearly flat. The area is large. 21 314 PROCEEDINGS OF THE ACADEMY OF [1876. I, neglecta, Gabb. Cucullea, id., Gabb., Proc. Acad., 1861, p. 326. This species is not rare in the marls of New Jersey, and I have seen casts from the white limestone of Prairie Bluff, Ala., appa- rently belonging to it. Recently I have obtained from Prof. Cook, State Geologist of New Jersey, specimens from the New Jersey white limestone (Timber Creek limestone) in which the shells are in a beautiful state of preservation. The valves are subecompressed; beak small, placed a little in advance of the middle; area narrow, about half as long as the shell, and marked by very few impressed lines; hinge thin, median teeth few and small, lateral teeth long, narrow, and few. Base and anterior end regularly and broadly curved; posterior side convex and sloping, not angulated at the base. No umbonal ridge; surface regularly convex, sloping in a little, more abruptly on the posterior side than elsewhere. Surface smooth, marked only by a few obscure lines of growth. Length 1.75 inch; width 1.4 inch; height of single valve 0.4. inch. I, Carolinensis. Shell subquadrate, convex, hinge line just one-half the length of the shell; beaks small, incurved, umbones prominent and rounded; posterior slope nearly vertical; anterior end regularly rounded, retreating obliquely below; base broadly convex, most prominent in the middle. Surface in the adult marked only by irregular lines of growth ; in the young crossed by very numerous and very fine radiating lines; hinge small. In the adult the mid- dle (transverse) teeth show a tendency to irregularity, and even partial obliteration. Lateral teeth perfectly parallel with the hinge line; area small. Internal plate thin and elevated. | Length 2.0 inches ; width 1.5 inch; depth of single valves .75 inch. This species grows about the size of J. vulgaris, but is less ob- lique, with rounder outlines and a more central beak. The area is smaller, and the whole shell is more quadrate. The markings of the young shell are as minute as those of Trigonarca Saffordt, G., but of a different character, and the present species is propor- tionally shorter, more oblique, and more convex than that. J. “capaa, Conrad, is a heavy shell, remarkably thick, and will, I think, prove to be identical with vulgaris. I referred it to antrosa by 1876. ] NATURAL SCIENCES OF PHILADELPHIA. 315 mistake in the Synopsis of Cret. Mollusca for that species. From I. neglecta this species can be at once distinguished by the more convex valves and by the umbonal angle. From the Ripley Group, Snow Hill, N. Carolina. I, Alabamensis, n. s. Shell convex, oblique; area less than half the length of the shell; very narrow ; beaks small, approximating ; umbones small; anterior end broadly rounded, not retreating below; base convex in front, straight behind; posterior side oblique, uniting with the base by a marked angle; umbonal angle rounded, but narrow and abrupt ; posterior face truncated; hinge narrow. Length 1.5 inch; width 1.25 inch ; depth of single valve 0.6 inch. The nearest ally of this species is the preceding. It can be distinguished by the smaller beaks, much narrower area, the broader anterior end, the base straight behind, instead of being regularly convex, and by the strong umbonal angle and more truncated posterior end. I have not attempted to describe the surface, since although the shell is well represented in all its details, except that, in the spe- cimen before me, the shell substance has been replaced by a bor- ing sponge (? Cliona); the shell itself has disappeared and the sponge has taken exactly its form except a thin outer film. Even two or three strong concentric lines of growth have left their im- pression on the sponge. This unique specimen, which might well serve as the type of two species of widely different organisms, is from the white limestone of Prairie Bluffs, Ala. 2 I, antrosa, Mort. (sp.) Cucullea, id., Morton, Synopsis, p. 68, pl. 13, fig. 6. A very convex form, almost as short as an Axvinea with central beaks and a strong internal plate. The species is only known from casts, although it was described over forty years ago. Its hinge line is so curved that it may prove eventually to be a Trigonarca, and may even belong to Conrad’s subgenus Brevi- arca. I have placed it under the above genus in accordance with the opinion of Mr. Conrad, with whom I have consulted on the subject. I, sp. ? Associated with the casts of antrosa are some of a more elon- gated and angulated form, evidently an undescribed species. 316 PROCEEDINGS OF THE ACADEMY OF [1876. Besides the difference of outline, it has a remarkably thick internal plate running far up into the cavity under the umbones. A mashed shell from Haddonfield, found by Mr. Conrad, and evi- dently of this species, shows the surface to be plain, marked only by lines of growth. The Academy’s collection contains also two other species of this genus from New Jersey, represented by internal casts, but which I refrain from describing, trusting that we may obtain more material in the future. I, Littlei, n. s. Shell very large, oblique, gibbous, beaks large, prominent, remote, incurved ; area broad; anterior end prominent, narrowly rounded, retreating below ; posterior end obliquely sloping ; base nearly straight, most prominent below the beaks ; internal plate very large, prominent and continued up into the cavity under the beaks. Surface marked by coarse lines of growth. Length (of casts) 5 inches ; width 4.8 inches, greatest transverse diameter 4 inches. This enormous species, not surpassed in size even by Arca grandis, is described from a nodular mass showing at the same time the impression of the surface and the mould of the interior. I take pleasure in dedicating this, the largest species of the family,to the State Geologist of Georgia, despite the fact that the name might be punningly suggestive of a specific character, espe- cially inappropriate. Itis from Pataula Creek, Georgia. Nemopon, Con. N, angulatum, Gabb. Leda, id., Gabb, Proc. Acad. 1860, p. 94, pl. 2, fig. 12. A re-examination of this species shows it to belong to Mr. Conrad’s genus. TRIGONARCA, Con. T. cuneata, n. s. Shell small, obligue; beaks slightly in advance of the centre, small, incurved, and approximated; area very small and marked by numerous transverse lines ; anterior end produced, narrowly rounded, most prominent below ; posterior side very sloping, the posterior end of the area being barely visible beyond the umbonal ridge ; below the posterior end is narrow and caudate, almost like some Crassatellas; base slightly convex in advance, nearly 1876.] NATURAL SCIENCES OF PHILADELPHIA. 317 straight, or even a little concave and sloping upwards behind; umbonal ridge strongly marked ; posterior face truncated ; sur- face marked by obsolete radiating lines, and by stronger lines of ‘growth. Hinge broad and with numerous radiately placed teeth. Length 1.1 inch ; width 1.0 inch; depth of valve 0.3 inch. Very closely allied in generic character to 7. Maconensis, Con., the type of the genus, but differs in its small size, the measure- ments being given from the largest of a large series. In shape it differs in being proportionally much larger, less produced in front and more produced behind, and in having a less rounded base. Ofabout the same size as Breviarca Carolinensis, Con., it is a more robust shell, with a stronger umbonal ridge; is caudate behind instead of being convex ; is less prominent in front, and is altogether a much more triangular shell. Abundant at Pataula Creek, Clay Co., Georgia. Axina@a, Poli. A. hamula, Morton, sp. Pectunculus hamulus, Morton, Syn. Cret., p. 64, pl. 15, f. 7. ? A. bellasculpta, Con., J. Acad., 2 s., v. 4, p. 295. The posterior extremity is nof angulated as described by Dr. Morton. His description and figure would be unintelligible with- out his types. His specimens are slightly truncated posteriorly though very faintly, and others are equally round on both margins. There seems to be a considerable difference in the amount of con- vexity in the species, and, although I have not seen so many specimens as I would like, I think fuller series will prove that there is no difference between this and A. subaustralis, d’Orb. (P. australis, Mort., not Quoy). The only character depended on is the convexity, and that certainly varies very much in Georgia specimens sent me by Doctor Little. In fact, in some cases I am in doubt whether to call them by one or the other name, with Dr. Morton’s types beside them. With about the same longitudinal and transverse diameters, the deepness of the yalve of Morton’s original hamula is .5 inch, while that of Australis is .25 inch. All of the casts (there are no shells) from New Jersey, are of this latter form, though Dr. Morton speaks of them as another species. The character on which Mr. Conrad separated A. bellasculpta is visible on some of the Georgia specimens, to a less degree than on his types from Mississippi, and on comparing the whole series, I 318 PROCEEDINGS OF THE ACADEMY OF [1876. can find no valid ground for a specific distinction between them and A. hamula. Nvucuna, Lam. N. percrassa, Con. Journ. Acad., 2s., v. 3, p. 827, pl. 35, f. 4. A fine species, common at Pataula Creek, Ga. N, Slackiana, Gabb. Leda, id., G., Journ. Acad., 2.s., v. 4, p. 397, pl. 68, f. 37. This was described from casts in the marls of New Jersey ; the surface characters have never been obtained, but from its size and shape I have little doubt it will prove identical with percrassa. Nvcovutana, Link. Leda, Schum. It is doubtful if the names of Link should be regarded. To all intents and purposes his book was never published, although printed, until the names were resurrected by Morch. I, however, under protest, follow H. & A. Adams, Stoliczka, Conrad, and Meek in the use of this name, regretting the habit so common of “reducing scientific nomenclature to a branch of archeological research.” N. protexta, Gabb (sp.), Meek, Check List, No. 204. Leda, id., Gabb, Journ. Acad., 2 s., v. 4, p. 308, pl. 48, f. 23. A single specimen from Pataula Creek, Georgia. CAMPTONECTES, Agas. C. Burlingtonensis, Gabb. Pecten, id., Gabb., Journ. Acad., 2s. v. 4, p. 304, pl. 48, f. 25. One of our finest Pectens. It was described from a very per- fect mould in the brown sandy marl of New Jersey. Since then Mr. Conrad has found the shell in the Ripley marl of Haddon- field, New Jersey. The right ear of the lower valve is long and narrow, and has a very deep, narrow sinus. The surface is marked by regularly placed thin subsquamose plates surmount- ing each a small concentric ridge. Between these plates are visible very minute radiating impressed lines. This radiating sculpture is only visible on well-preserved specimens, and, while it takes the directions common in Agassiz’s genus, it differs from all the previously described species in its almost invisible character. 1876. ] NATURAL SCIENCES OF PHILADELPHIA. 319 SrncycLoneMA, Meek. S. simplicius, Con., Meek, Check List Cretaceous, No. 196. Pecten, id., Con., J. Acad., 2s. v. 4, p. 283, pl. 46, f. 44. This little shell grows to a diameter of 0.6 inch, and is an abundant fossil. In the older specimens, many are marked by strong concentric squamose ridges, between which are microscopic radiating lines. NeituHea, Drouet. N. complexicosta, n. s. Shell moderate in size ; lower valve deeply convex, upper valve unknown. Surface marked by six large ribs, regularly distributed at equal distances, between each pair of which are two smaller ones. Each rib, large and small, is divided on its upper surface into three thread like ridges; the interspaces between the ribs are regularly concave, and without longitudinal marking; entire sur- face crossed by minute, regularly placed subsquamose lines. Length one inch. Locality, Uniontown, Ala. A very pretty species, of the typical shape of NV. quinquecostata, ete., but differing from all the described species in the character of its ribs. It is probably nearest to D’Orbigny’s N. striato-costata, but the large and small ribs are more nearly equal in size, and they differ in the manner in which the ribs are ornamented. In our species, the broad concave interspace rounds up to nearly the full height of the rib, and only on the top does it show the two grooves which divide it into three little linear ribs. NV. alpina, D’Orb., has the same number of large and small ribs, but they are rounded and plain on top. AwnomiA, Linn. A. argentaria, Morton, Syn. p. 61, pl. 5, f. 10. A. tellinoides, Mort., loc. cit., p. 61, pl. 5, f. 11. A, selieformis, Con., J. A., 28. v. 3, p. 330, pl. 34, f. 6. I have compared large suites, including Dr. Morton’s original specimens, and conclude that all three of the above names must go together. ‘The differences depended on for the separation were only those of outline, and there is no possible ground for the second specific name given by Dr. Morton. Mr. Conrad’s name was given to a single specimen distorted by growing on an irregu- lar surface. The species is common at Pataula Creek, Georgia, 320 PROCEEDINGS OF THE ACADEMY OF [1876 and grows to more than an inch in diameter. The most regular form, before the shell becomes distorted, is nearly circular, with a well-marked little beak, adjoining to, and sometimes overhang- ing the cardinal margin. The surface is faintly squamose and ornamented by microscopic radiating lines. Accompanying these is another form, represented by no less than fifteen specimens agreeing well with one another. Unlike the typical A. argentaria, they are ornamented by a uniform pattern, clearly not the impression of a surface, to which they were at- tached. In form and size they do not differ from A. argentaria, but the ornament is a series of radiating ribs, one set large, flat- tened on top, and well defined; between these are interpolated from one to three smaller ribs. In most cases this alternation is well defined; though in two or three the large ribs are nearer in size to the small ones. On the typical argentaria this radiation is never observed, even in a rudimentary manner, and on some of my specimens it begins at the very apex; but on several the first half inch in diameter, or less, of the shell does not differ from argentaria, while after that the ribs begin, first on thread-like lines, finally developing to full size. In consequence of this I feel reluctant to separate the form as a distinct species, believing that more material will merge the two. I therefore content myself with proposing the name of A. argentaria, var. ornata. PARANOMIA, Con. P, Saffordi, Con., Journ. Acad., 2s. v. 4, p. 290, pl. 46, f. 21. Several specimens from Pataula Creek, Georgia. OstrEA, Linn. 0. subspatulata, Fbs., Quart. Journ. G. Soe., v. 1, p. 61. Five miles north of Lumpkin, Stewart County, and near Fort Gaines, Georgia; Dr. Little. The species is characterized, even when not two inches long, by a tendency to great thickening of the upper half, the lower half being a thin tongue-like process. O. larva, Lam., A. S. V., v. 6, p. 216. O. falcata, Morton, Syn., p. 50, pl. 3, f. 5. Not common at Georgetown, Quitman Co., Georgia. 0. plumosa, Morton, Syn., p. 51, pl. 3, f. 9. With the preceding. 1876.] NATURAL SCIENCES OF PHILADELPHIA. 321 O. pusilla, Nills., Petr. Suec., p. 32, pl. 11, f. 7, ac. O. tecticosta, Gabb, Journ. Acad., 2s. v. 4, p. 403, pl. 68, f. 47, 48. From Georgetown, Pataula Creek, and five miles north of Lump- kin, Stewart County, Georgia. Some of the specimens are much larger and broader than those from Tennessee and New Jersey, from which I described the species. I am convinced that not only is this shell identical with the Swiss species, but, by looking over Nillson’s work, there are nearly a dozen others that will probably prove synonymous. Among these might be mentioned Grypheza lateralis and Ostrea larva, of which the broad form, called by Nillson O. lunata, also occurs in New Jersey. 0. Bryanii, n. s. Shell moderate in size, subtrigonal, oblique, irregular in out- line, rather thick. Lower valve deep, upper valve flat, or more or less concave towards the basal margin. Shell usually free, sometimes showing signs of attachment near the beak; surface irregularly squamose, more so as it grows older; a few broad but not very prominent radiating lines or ribs are visible usually, though not always, on the most convex part of the lower valve. I have never observed any on the upper valve. Hinge long, tri- angular, deeply grooved in the middle, and strongly deflected to the left side. Inner margin crenulated, though sometimes ob- securely, near the hinge. Muscular scar large. Usual size about 1 inch to 1.5 in length; I have one specimen three inches long. Found abundantly near Vincenttown, New Jersey, in the marl at the top of the Cretaceous, by Col. Bryan. In a few minutes, in company with that gentleman, I collected more than fifty speci- mens on the marl heaps of the West Jersey Marl Co. O. Littlei, n. s. Shell small, irregularly elongate-falcate to subtriangular ; more regular in the young state; thin. Young shell marked, at least on the lower valve, by faint radiations, which become obsolete in the adult; these are crossed by unusually faint lines of growth, not squamose. Hinge elongate, triangular, deflected to the left. Associated with the lower valves are some upper ones of corre- sponding form and size, with the same surface markings except that they are not radiated even towards the beaks. The margins are crenulated, corresponding to the ends of the radii in the lower valve. 322 PROCEEDINGS OF THE ACADEMY OF [1876. Length of largest specimen 2.5 inch ; width 1.0 inch; depth of lower valves 0.5 inch. From Pataula Creek and Georgetown, Georgia. I have also found some valves of this species among the undetermined oysters sent me in 1860 by Prof. Safford from the Ripley Marls of Ten- nessee. Nearly as smooth as O. plumosa, Morton, this shell differs in its more triangular form, elongate, and somewhat bent ; the lower valve is subangular and deep, and the young shell has radiations which point to a resemblance to some of the more triangular forms of O. larva. From that species it differs in being less faleate than the shortest and broadest specimens, and in having a mere trace of the radiations and none of the marginal plications. 0. exogyrella, n. s. Shell subequivalve, nearly equilateral, elongate, more or less quadrate ; sides subparallel, cardinal margins more or less slop- ing; beaks usually nearly median, sometimes a little deflected; base rounded; surface marked by distant subsquamose lines of growth not radiated at any stage; hinge broad, shallow, normally triangular, varying to nearly subquadrate. Length 1 to 2 inches; usual proportion a third longer than wide. From Pataula Creek and Georgetown, Georgia; Dr. Little. I have purposely omitted a very important point in the above diagnosis, to mention it more in detail here. The shell shows an additional character, which I have failed to discover in any other true oyster, and which shows the transitional character from Os- trea to Hxogyra. Fortunately, I have a good series of specimens, and every lower valve possesses a ‘nuclear whorl,” if I may be permitted to use such a phrase in connection with a bivalve. In other words, up to a diameter of nearly a quarter of an inch, every specimen has been a well-characterized Exogyra. After this the direction of growth changed to a right line, and the spiral is par- tially imbedded in the succeeding layers, or projects as a slightly deflected tip or beak on an unusually symmetrical oyster. This spiral is on the normal side of Hxogyra, and under the deflected beak there is a slight emargination, a corresponding convexity existing on the opposite side. This character is of the greater interest, since it is a transition to the generic characters of the species variously known as Ostrea, Gryphexa and Exogyra lateralis, Nillson, Petr., Suec., pl. 7, f. 9- 1876.] NATURAL SCIENCES OF PHILADELPHIA. 323 10. (G. vomer, Morton, Syn. Cret. p. 54, pl. 9, f. 5.) This shell is a well-marked Lxogyra in its young state, but in some cases in the adult the spiral beak is entirely covered up. Mr. Conrad proposed for this group, although I think on insufficient grounds, the subgeneric name of Gryphostrea in the genus Ostrea. This last species survived to the Hocene, where it is known in the Paris Basin as O. eversa, and in Maryland as OQ. sub-eversa. GRYPHAA. G. vesicularis, Lam. (sp.), Bronn, Leth. Geog. pl. 32, f. 1. Ostrea, id., Lam., Am. Mus., v. 8, p. 160, pl. 22, f. 3. Common at Georgetown, Georgia; Dr. Little. G. Thirsz, Gabb, Proc. Acad., 1861, p. 329. This is a rare species, and seems to be confined to the neighbor- hood of Alabama and Georgia. I described it from the former State, and now have it from near Fort Gaines, Georgia, whence it was sent by Dr. Little. It is intermediate between the narrowest forms of G. vesicularis and G. pitcherii. From the former it can be distinguished by the sides being narrowed and sloping nearly straight from the umbone, which is narrower and more prominent than is Lamarck’s species. From G. pitcheri, which it most re- sembles, it can be distinguished by being less distinctly lobed laterally; by the hinge area of the lower valve being broader and flatter, and by the beak being very minute instead of being large and incurved. Exoeyra, Say. E. costata, Say, Journ. Phila. Acad., 1 ser., vol. 2, p. 43. To the already long synonymy of this species must be added E. interrupta, Con., Journ. Acad., 2 s. v. 3, p. 330, pl. 34, f. 15. I have this latter, which is only an attached lower valve of £. costata, of every size and of every degree of attachment from an almost total obliteration of the ribs, to a perfectly free and typi- cal costata. They are marked Georgetown, and five miles north of Lumpkin, Stewart County, Georgia. Discoidea occidentalis, Gabb. This echinoderm was described by me as coming from the Cre- taceous of Oregon. It was given me by a friend, who at the same 324 PROCEEDINGS OF THE ACADEMY OF [1876. time told me that was the locality. Since then an extensive ac- quaintance with the Cretaceous rocks of the west coast of North America, including not a little with the geology of Oregon, renders me doubtful of the accuracy of the information. The specimen is preserved in a light-colored limestone, entirely unlike anything I know of in our Pacific States, but which looks suspiciously like some Cretaceous rocks I have seen from Peru. It may conse- quently prove to be a South American fossil, though this is only a conjecture. Patiurus. New Genus. A free serpuloid tube, usually with a triangular cross section externally ; circular internally; tube straight or slightly twisted or bent. P, triangularis, n. s., pl. 17, f. 11, 12, 13. I propose this name for a common little annelid in the white limestone, found especially abundant at Vincenttown, New Jersey. It is free, and, as above described, has an external triangular cross section; the two ends are open, and the apertures are circular. The carinz are subangular or rounded, the sides more or less deeply grooved, and the entire shell, usually about three-fourths of an inch long, is slightly twisted or irregularly curved, though varying little from a straight line. The diameter is about .06 or OT inch. oo Lo or 1876.] NATURAL SCIENCES OF PHILADELPHIA. DECEMBER 5. Mr. Vaux, Vice-President, in the chair. Forty-two members present. The following papers were presented for publication :— ‘“Our Sidereal System and the Direction and Distance of its Centre.” By Jacos ENNIS. “On some Extinct Reptiles and Batrachia from the Fort Union and Fox Hills Beds of Montana.” By Epw. D. Corr. On Ozocerite.—Prof. LEipy remarked that the fine collection of specimens of Ozocerite, and minerals with which it is found asso- ciated, presented this evening by Mr. Paul Dobel, through Dr. F. Migerka, the Austrian Commissioner, were well worthy the atten- tion of the members. The Ozocerite, Erdwachs or mineral wax of the Germans, is found in association with clay, sand, and salt, at Boryslaw, in the Carpathians, Galicia. The collection consists ofa fine series of the Ozocerite of different varieties: the ordinary brown resin-like kind; a lemon-yellow flaky form; another lemon-yellow but fibrous kind; a black carbonaceous form, etc., with specimens associated with rock salt, and others with clay and sandstone. Besides these there are a number of specimens obtained from the crude material ; a mass of chocolate-brown hue ; another undistin- guishable in appearance from ordinary yellow beeswax, and a third looking like white wax or like paraftine. On Hyraceum.—Prof. Lrtpy remarked that the large, black bituminous-looking mass presented this evening, through Mr. H. C. Coates, Commissioner of the Colony of Cape of Good Hope, is the substance called Hyraceum, and is said to be the inspis- sated urine of the Hyrax capensis. The animal is reputed to inhabit gregariously, rocky places at the Cape of Good Hope. The accumulated urine in hollows of the rocks, gradually evapo- rating, is supposed to give rise to the product in question. It is reported as having been employed in medicine with the same effect as castoreum. Prof. Cope remarked that a material resembling the concretion made by the urine of Hyrax was found in the fissures of the rocks in New Mexico. It was probably the fecal and renal deposit of the wild rat, Neotoma. On Itacolumite.—Prof. W. P. BLAKE remarked that the Mineral Department of the National Museum at the Centennial Exhibition had recently received some specimens of flexible sandstone, re- 326 PROCEEDINGS OF THE ACADEMY OF [1876. ported to be from Mariposa County, California, which are inter- esting and worthy of note by reason of the new locality, and as showing the peculiarities of this kind of sandstone in a marked degree. The specimens are, also, unusually fine, some being over thirty inches in length, and only two square inches in section. The color and the structure appear to be the same as in flexible sandstone from other localities. Thin and small scales of silver mica are abundant. It bends with little resistance up to a certain point, and without elasticity, but is rigid beyond that point. When held up by one end and shaken, the motion is transmitted in wave-like vibrations as in a cord, but the limit of movement is sensibly felt like a blow or shock. A specimen thirty-two inches in length may be bent seven and a half inches to one side or the other of a straight line. The freedom of movement is greatest at right angles to the plane of lamination. The specimens are also capable of being sensibly extended when pulled. In a specimen thirty-two inches long the extension amounted to about half an inch. No examinations under the microscope have been made, as they should have been, to show the structure. The freedom of movement up to a certain point, and the rigidity beyond that point indicate that there is a tolerably uniform distance between the grains of sand and a certain amount of movement possible among them, and that by bending, the grains are brought into contact with each other. The theory of the late Prof. C. M. Weth- erill that the grains of sand are shaped like dumb-bells was referred to with a doubt of its correctness. ‘the part which the scales of mica play can only be shown by the examination under a micro- scope of carefully ground sections of the stone, which might per- haps be prepared for cutting by solutions of soluble glass. Prof. Lerpy’stated that he had examined Itacolumite micro- scopically without being able to detect anything like the dumb- bell structure described by Dr. Wetherill. ‘He supposed that the intermingling of grains, differing in translucency and color, gave rise to the impression of a dumb-bell arrangement. Thus a pair of adherent translucent grains surrounded with smaller colored ones would give rise to such an impression. DECEMBER 12 The President, Dr. RuscHENBERGER, in the chair. Forty-four members present. 1876. ] NATURAL SCIENCES OF PHILADELPHIA. 327 DECEMBER 19. Mr. Vaux, Vice-President, in the chair. Thirty-five members present. Mineralogical Notes.—Myr. JosepH WiILucox said that the two fine crystals of scapolite, which were presented this evening by Mr. Vaux, were found at a new locality for this mineral, in St. Lawrence County, N. Y., and that a specimen from the same locality had recently been received in this city which weighs about 25 pounds, and is probably the largest scapolite crystal ever found. He also referred to a specimen of quartz on the table from the well-known locality of green quartz at Blue Hill, in Delaware County, Pa. This specimen had been exposed to the weather for a few weeks, and had lost nearly all its green color.. This green quartz is found in several veins of chlorite, much decomposed, and each of different intensity in color. The quartz occurring in each vein corresponds in color to the matrix. Impurities in Drinking Water.—Mr. Wi11cox also stated that, during the last eight years, whenever the Schuylkill River has been covered with ice, he observed that the water supplied by the city possessed a disagreeable odor and taste, like chlorine. Large quantities of chloride of lime are daily used at Manayunk and at the Wissahickon for bleaching purposes, and the chlorine gas is liberated from it by the application of alum and sulphuric acid. A large portion of the chlorine gas subsequently escapes from the water before it reaches Fairmount; but when the river is covered with ice, this process of purification is retarded, and the offensive element is practically conveyed, in a covered trough, from the nills to the pumps that supply our city with water. He was not competent to state if chlorine in this condition is prejudicial to health. Being a powerful disinfectant it may be a providential interposition for the prevention of disease that might be caused by the foul material that is carried in such profusion through the sewers into the Schuylkill River, and which, on account of the ice, would otherwise be transported into our water-pipes in its original impurity. On Excrescences and Excentric Wood Growths in the Trunks of Trees.—Mr. THoMAS MEEHAN said that on many trees were pecu- liar excrescences, which, up to a few years ago, had been referred primarily to insect origin. Cutting these through lengthwise there was no appearance of this agency. There were layers of wood of annual growth, just as in the normal parts of the tree. 328 PROCEEDINGS OF THE ACADEMY OF [1876. Examining some oak knots of this character, and finding pulve- rulent fungoid matter abundant on the surface, he said he had introduced some of these to the Academy a few years ago, and suggested this as a substitute for the insect theory, but subse- quently Professor Farlow had kindly examined them critically and found no trace whatever of fungoid matter in their structure. This left us wholly in the dark as to the exact origin of these stuctures. It was worth noting that these excrescences were often of a uniform character in each species of tree. In many cases, no matter how large or how old they were, they would separate from the parent stem easily by a short sudden blow. He had made collections of these and in most cases found great uniformity. In Quercus obtusiloba they were depressed globose, in Fagus sylva- tica (American beech) they were convex and oval, with the narrow ends crosswise with the trunk. In the Acer rubrum (red maple) they were oval but drawn out lengthwise. In the common weeping willow they varied very much in size, sometimes being as large as a bushel measure, but always knocking out easily as in all named before. In the common cherry (Cerasus avium) and the paper mulberry (Broussonnetia papyrifera) the excrescences were also very irregular in form, and seemed to have a stronger attachment to the parent stem than the others. The apple had very small and numerous ones in some species ; and it was from an examination of these, he said, that he had derived the key to the whole subject. On the bark of some kinds of apple trees numerous small pea-like projections would exist on the bark within a space of a few inches. On cutting open, these were found to be not vesicular, but to be filled with hard and perfect wood. A careful examination showed that these woody masses took their rise seemingly from the liber, to which, in the newly formed cases, they would be found still attached by a small thread-like vessel. In order to understand their formation, it was necessary to understand how wood was made. In many trees the annual layer was so regular, and seemed to be placed so nicely, that one not a botanist might be pardoned for believing that the sap was changed to woody matter in the leaves, and the new formed matter sent down, sliding over the old layer like the sections of a telescope; but though the food was prepared by the leaves in a great meas- ure, the actual growth was made by the germination of some of the cells along the whole outside wall of last year’s wood beneath the inner bark. In his own observations of this process he had taken the common cherry for his experiments. The germination of the cells takes place here about the middle of June. He takes a healthy cherry tree and strips it entirely of its bark to any length desired. At that season a viscid liquid will be found covering the woody surface in abundance. The stripped part is 1876.] NATURAL SCIENCES OF PHILADELPHIA. 329 covered with a cloth to prevent evaporation, and in a few days numerous dots, like needle points, will be seen about the sixteenth of an inch apart all over the surface. These are the young cells which have germinated from those of last year. They continue germinating, one from the other, until they meet, when they unite and form a complete surface. In the fall a layer of wood will be found just as thick as in the part of the tree not disbarked, and a single layer of liber, with its outer coat of cellular matter— perfect bark—will have been formed over the whole. The entire formation of wood and bark can thus be seen by the ordinary observer, without the necessity of any uice microscopical work. Other people have tried the experiment with other trees. He has seen large apple trees that have had their bark peeled wholly off from their trunks, at the season named, make an entire new layer of bark and woed, not only with no injury to the tree, but to its manifest enjoyment ; but his own experiments were confined ex- clusively to the cherry? By this experiment we learn that there is no difference pri- marily in any part of the annual covering. The same cell may become permanent tissue or generating tissue—and from the generative tissue may come before the season of growth closes every form of structure known to anatomists, from pure wood to the outermost cuticle of the bark. How these cells become differ- entiated may be passed over here. We know that cell-growth is not always uniform in its operations. The law that changes the outermost series of newly made cells into liber need not neces- sarily operate so exactly as to make them perfect to this end—a few may be thrown off into the liber as generative tissue—and, granting this possibility, we see how the woody granules in the apple bark are formed. How cells usually of one character may be made to assume others is shown in the formation of adventitious buds. Sachs (‘Text Book, Eng. ed., p. 563) thinks that few dicotyledons produce adventitious buds. The shoots that often spring from the bark of the older stems of trees, he says, are probably from dormant buds which have retained vitality, though buried from the first growth of the stem. This sort of erowth is true. In Gymno- cladus the buds formed the first year in the axil of the leaves are in a linear series of three or more, of which but one is generally seen above the surface ; but after many years, if the bark be gently shaved, these will be found just beneath the surface as they were the first year, having kept along their hidden growth all that time. In some magnolias (M. acuminata, M. tripetela), besides the axil- lary bud one forms exactly horizontal to it, on the side opposite to the direction of the spiral growth. This bud is rarely seen above the surface, and has not been before made known to botanists as I believe, but may always be found beneath the surface of the stronger shoots when the bark is gently shaved, no matter how 22 330 PROCEEDINGS OF THE ACADEMY OF [1876. great may be the age, unless, as sometimes happens, some acci- dent should favor its development to a perfect branch. These are the sort of buds referred to by Prof. Sachs, and of course make up their share of new branches when time comes to favor them. He knew of no dicotyledonous tree that could not be made to throw out numerous adventitious buds from any part of its sur- face by sawing off. In our common street maples this was every- day experience. A few inches below the cut generally died back from evaporation of the juices; but when the shoots pushed out they came by the dozens in the space of a few inches. Now in the original shoot—the first year’s growth—there would be found in a vigorous specimen seldom more than six buds in a length of six inches; but in a strong six year old branch of maple (Acer dasy- carpum) cut back he had seen as many as fifty shoots in that space. He exhibited a one year shoot of Catalpa, where the nor- mal buds were ten inches from each other. In old branches cut back in early winter, so that the surfacé may harden a little before spring, and thus the tree lose little of its juices by evapo- ration, shoots will come out numerously from any part of the foot space between these original buds. It was interesting, however, to note that in no case that he knew of would adventitious buds be produced between the nodes from a one year old branch. Such a branch cut beneath the node invariably died to the next. It would seem as if the demand on the nutritive powers of the plants for the axial elongation had left the generative tissue with less power than in subsequent years they may possess. How cells which under some circumstances become permanent tissue, or at best generative tissue, may become the parents of adventitious buds and shoots was well shown in cutting down horse chestnuts, some poplars, and some birches. As_ before said, during the season following the first year, no adventitious buds will form between the nodes, when the branch is shortened ; but in the older trees, the new cells from the generative tissue all along the exposed part or surface of the stump form adventitious buds and branches. The whole circle between last year’s wood. and the bark produces a forest of branches. He had seen this also, he said, in Cotyledons and other succulents under green- house culture. From these considerations there was no reason why cells, pre- destined, under ordinary circumstances, to be merely bark cells in their change from wood cells, should not occasionally retain enough of growth force to carry on a feeble wood constructing system of their own. We thus come naturally to the origin of these woody excres- cences. Imperfectly formed liber cells, still retaining their genera- tive power, would make a growth the next season, forming a layer of wood and making its own cortical layer, simultaneous with the normal wood growth of the tree, assimilating from the same 1876.] NATURAL SCIENCES OF PHILADELPHIA. 331 store of reserve material that the normal growth does. The proof of all this lies in the cutting through longitudinally of one of these excrescences when it will be found to have made one more annual layer from the point of its origin than the tree itself, showing that the origin dated from a double set of germinating cells in that one year. Where, as in the weeping willow and cherry, the excrescences are protruded much beyond the normal diameter of the tree, the annual layers of wood are on the average thicker, through having assimilated a greater share of food; as is generally the case with cells situated above an obstruction, for instance, as when a wire is fastened around a branch, a ring of bark taken off, or other means employed to interfere with the connection between root and foliage. Mr. Meehan further said that explanation of growth in connec- tion with these excrescences, explained also much that was usually inexplicable in the various excentricities of growth. He exhibited a specimen of a trunk of a Bauhinia, presented to the Academy by the Brazilian Centennial Commission, in which the wood seemed a mere fasciculus of many separate stems, forming a sort of ligneous mosaic work. The trunk was about six inches in one direction, and two in the other. The first year’s growth, round the small pith, was circular; the subsequent ones irregular through the varying powers of growth in the germinating tissue. Very often, but a very small section of the previous year’s circle of wood would germinate, in which case the whole growth would be made from that point pressing round and over, with great luxuriance, and enveloping the bark as well as wood of the pre- vious year. Mr. Meehan thought it quite likely that the cases of Wistaria with bark between some of the annual layers of wood, might be explained in a similar way.’ The subject of the excen- tricity of the annual layers of wood in trees could also be under- stood, keeping in mind the generating tissue, and its varying powers of life and transformation. Anything which favored nutrition in one part of the mass of cells more than in another, would increase their power of growth, and induce thicker layers at that point than in others. A very hot sun on one side, or in one season on one side, or on particular spots on one side, indue- ing an inordinate evaporation from those parts, would weaken the vital power of the cells just there. The germination would be weak, and the woody layer thin. Cold winds on one side in very ' Since making the above remarks I have had brought to my attention that in 1873, M. Licopoli, of Naples, in some publication not known at this writing, has suggested that the appearance of bark mixed with the wood of Wistaria is due to the formation of woody matter by the bark, whicb wood then continues to grow, and leaves the bark, as it were, behind the wood, instead of being pushed steadily before, as in normal wood growth. Although sure that my facts were as I detailed them, it is pleas- ant to have the confirmation of my views of these abnormal wood growths in this independent way. 332 PROCEEDINGS OF THE ACADEMY OF [1876. cold weather would have the same effect in some cases. The con- tinunal blowing of trees always in one direction might favor assimilation by the cells on one side more than on the other, or even the closer proximity of some cells to healthy foliage or vigor- ous roots, would give them a great advantage over others, and the layer would thicken. In some plants there was pretty equally divided power. The whole mass of tissue seemed equally and regularly vitalized, and the generative tissue formed a new layer of wood of about equal thickness all round. But in other trees some masses of cells seemed to easily draw from the others more than their share, and the latter were correspondingly weakened. This was beautifully illustrated in the Hornbeam (Carpinus Americana). Here the irregularities in the thickness of the annual layers defied all system. They might be very thick at one point, and yet at an inch or two above or below the same layer, be very thin. The red cedar (Juniperus Virginiana) exhibited similar characters, except that the loss of generative power in some of the cells was more uniformly in a direction lengthwise with the stem. In a section he had recently examined the annual layers were tolerably regular for fifteen years. A young tree of the same species had then grown up close to it on one side, and the annual layers became thinner, finally ceasing there. The other sides grew on as before, the layers tapering, with the weakened vitality, to where the tissue was wholly at rest. So in various parts of the outline could be noted the time when various parts of the gene- rative tissue lost vital power. In one part of the section, in a direct line from the centre, there was a continuous and nearly regular annual layer for over fifty years; but in many directions, by counting the rings or layers, the time could be traced when the tissue ceased to be generative or almost so, fifteen, eighteen, twenty-eight, and so on. All the cases of peculiar excentricities, Hedera, Toxicodendron, Ampelopsis, and the peculiar cases of ordinary timber trees, could be explained by this, so far as to note that the immediate law was a loss of generative power in the cells of the annual layer. Of course, the indirect causes leading to this would be very numerous, and left room for much more investi-. gation. The remarks were made as much as possible in lan- guage divested of botanical technicalities for the benefit of those interested in the many other branches of science present; but those who would pursue the subject of wood-growth, as described here and applied to the explanation of excrescences and eccentri- cities, are referred to Sach’s Text Book of Botany. Mr. Martindale inquired if Mr. Meehan had noted the square growth of a coniferous trunk from the Pacific coast, on exhibition at the recent Centennial, and if that growth could be accounted for on his explanations ? Mr. Meehan replied that he had examined that trunk. It was square only at the lower end. It was of Picea amabilis. At the four corners tlie annual layers were thicker than at the sides. He 1876.] NATURAL SCIENCES OF PHILADELPHIA. 333 had no doubt that in that case, and in similar ones if they were repeated, four strong roots had grown out at nearly equal dis- tances, and the mass of cells nearest to these roots had an advan- tage in nutrition. We saw this in the trees of our own forests. Just in proportion to the vigor of the roots below was the thick- ness and irregularity of the trunk for a considerable distance above. If these trees had but four main roots of equal strength at equal distances, a portion of the trunk would be about square. Mr. J. H. Redfield inquired whether Mr. Meehan would class cypress knees among the excrescences he had described ? Mr. Meehan replied not, as they were an outgrowth from the normal woody system of the roots of the tree, while the excres- cences or iginated in the liber, or the tissue very closely allied thereto. Pickeringite , from Colorado.—Myr. E. GoupsMirH stated that he has observed, in the Mineralogical Collection of the Academy, a white mineral which had not been determined. His examination, which was principally a chemical analysis, proved it to be the above-named species. As Peru and Nova Scotia are localities where this mineral has been found previously (see Dana’s Descrip- tive Min., p. 653), this seems to be the first observation of Picker- ingite in the U.S. Dr. John LeConte collected it. The particu- lar note on his label is, near Monument, near Colorado City, Col. Terr. The mineral is crystallized in very thin needles, which can only be seen when it is broken; these crystals keep within the mass well. Externally it is apt to become powdery. Its taste is as- tringent. Hardness about = 1. Specific gravity in oil of turpentine = 2.0105 Gs ‘* water == 1.7290 In the flame reaction he noticed the presence of sodium and potassium. ‘The last element has been noticed by How in the Pickeringite from Nova Scotia. Sodium seems not to exist in the compound found in Nova Scotia or Peru. The blowpipe reaction indicated water, alumina, and sulphuric aci(. The qualitative analysis proved also the occurrence of a minute quantity of proto and sesquioxide of iron, and magnesia was re- cogznized to be in the solution. The quantitative analysis gave this result :— S = 38.69 per cent. a 10.98 eeu (Ka) Na = 0.68 ‘* Sand= 1.90 ‘* By difference H = 41.94 *¢ EOCL00 «5 334 PROCEEDINGS OF THE ACADEMY OF [1876. He was inclined to believe that the average sample had lost some water of crystallization. An attempt was made to separate the potassa from the soda, which were both in combination with chlorine, but the reagent applied failed to affect it. The chloride of potassium could have heen but a trace. Having also observed that the quantity of iron in the mineral was small, it was considered useless to measure it. Epsomite on Brick-walls.—Mr. Goldsmith remarked, with the beginning of the cold season the brick-walls of Philadelphia often become coated with a whitish incrustation. The supposition was current, to some extent, that the incrustation was a mixture of chloride and nitrate of sodium. Mr. W. H. Dougherty, of this city, collected, in the beginning of December, a suflicient quantity of it, and examined it chemi- cally ; to his surprise he found that it reacted strongly on mag- nesia and sulphuric acid. The gentleman handed to Mr. G. some of the substance, which the latter redetermined. The result was the same. The epsomite contained besides, as an impurity, a small quantity of sodium, potassium, and chlorine. Mr. Dougherty endeavored to trace out the origin of the ep- somite, and analyzed some mortar which he collected from a wall that had on its surface this soluble salt. The reactions obtained proved that it was present. When fresh mortar was treated in the same way the presence of magnesia was recognized, but sul- phurie acid was not found in it. The idea that sulphuric acid, in a free state, could be present in bricks is improbable; hence, a plausible hypothesis is offered to explain its presence: The coal and gas used in the city contain small quantities of sulphur, which, when burnt, is oxidized into sulphuric acid, and this, being precipitated on the wall, will event- ually also touch part of the mortar, out of which it will extract the magnesia, and thus form epsomite. From this explanation it may be inferred that the lime in the mortar cannot be any longer caustic, for caustic lime will not permit the sulphuric acid to com- bine with magnesia, as long as it is present in the mixture. The lime in mortar is converted into silicate of lime, but whether the magnesia is also changed into a silicate is, | presume, not known at present. DECEMBER 26. The President, Dr. RUSCHENBERGER, in the chair. Seventy-four members present. The following papers were ordered to be printed :— 1876.] NATURAL SCIENCES OF PHILADELPHIA. 33 NOTES ON FISHES FROM THE ISTHMUS OF PANAMA, COLLECTED BY DR. J. F. BRANSFORD, U.S. N. BY THEODORE GILL. The present article is devoted to an enumeration of fishes col- lected by Dr. Bransford during a recent survey of the Isthmus. Although small in numbers, the collection is of considerable in- terest, inasmuch as there are in it several new species, and among them representatives of two genera which have not before been known to be represented in that country. These, for the Isth- mus, new generic types, are Plalypecilus, hitherto exemplified by a single Mexican species, and Piabucina, previously known only from two species found in Guiana and Venezuela. I have adopted the formulas employed by Dr. Gunther, to enable comparisons readily to be made with the descriptions of the new species. GOBIUS SOPORATOR. Synonymy. Gobius soporator, Cuv. and Val., Hist. Nat. des Poiss.,vol. xii. p. 56; Guich., Hist. Cub. por de la Sagra, Poissons, p. 127; Giunther, Cat. Fishes B. M., vol. iii. p. 26; 7b. Trans. Zool. Soc. London, vol. vi. p. 388 (** Atl. and Pac. Panama.’’) One specimen was obtained at Washington Station. CICHLASOMA C@HRULEOPUNCTATA. Synonymy. Acara ceruleopunctata, Kner and Steindacher, Sitzurgsber, d. bayer. Akad. dl. W., 1863, p. 222; 7b., Abhandlungen d. bayer Akad. der W., II. Cl., b. x., p. 16, tab. 2, fig. 3. 1864; Ginther, Trans. Zool. Soc. London, vol. vi. p. 449, 1868. A number of specimens were obtained from different localities, viz, Empire Station, February, 1875; Rio Frijoli, March, 1875; and Bahia Soldado, March, 1875. PLATYPECILUS MENTALIS. PaO: A/S OV 85, Sa late So. i. tre: Body regularly compressed backwards, and moderately ele- vated ; its greatest depth being in advance of the dorsal fin, and contained three and a half times in the total length, without the 336 PROCEEDINGS OF THE ACADEMY OF [L876. caudal; head less compressed than the body; the width of the interorbital space is less than one-half the entire length of the head; the length is contained three times and a half in the entire length without the caudal; the diameter of the eye considerably exceeds the length of the snout, and equals one-third the length of the head; the dorsal fin is moderate, higher than long, and its origin is about midway between the snout and the middle of the caudal fin; anal fin small; its origin is opposite the middle of the dorsal fin; caudal fin round, equal to the length of the head ; its depth at base equals three-fourths the length of the head; the pectoral fin extends considerably beyond the root of the ventral ; the ventral does not reach the origin of the anal. The color is a uniform brownish-olive, with no caudal spot; a linear band crosses the chin parallel with the lip; the dorsal has a deep, black, band- like spot near the base crossing the anterior half. A single female specimen, 65 millimetres long, was obtained from a stream on the Atlantic side of the Isthmus. Inasmuch as this species agrees with Platypacilus maculatus generically in the position of the ventral fins under the dorsal, and thus differs from all related forms, it appears to be conge- neric with it. It, however, differs much in the comparatively elongated body and less number of rows of scales between the dorsal and anal, as well as in other respects. ASTYNAX ENEUS. Synonymy. Tetragonopterus sneus, Gunther, Proc. Zool. Soc. London, 1860, p. 319; tb., Cat. Fishes B. M., vol. v. p. 326; Kner and Steindachner, Ab- handl. k. bayer. Akad. W., II. Cl., b. x. p. 46; Giinther, Trans. Zool. Soc. London, vol. vi. pp. 394, 478. Numerous small specimens, which would at least have been referred by Mess. Kner and Steindacher to this species, were ob- tained from Empire Station, Bahia Soldado, and the Rio Frijoli. PIABUCINA PANAMENSIS. D120, Ayi2@; Ws lat. 80> sls trans8: The height of the body equals one-fourth of the length, exclud- ing, and one-fifth of the total, including the caudal; the head enters a little less than three and a half times in the length, ex- clusive of the caudal; the lower jaw projects slightly beyond the 1876.] NATURAL SCIENCES OF PHILADELPHIA. 337 upper; the supramaxillary extends below the anterior half of the eye; the diameter of the eye equals about three-fourths of the interorbital space, is somewhat greater than the length of the snout, and about one-fourth the length of the head; the middle postorbital about as high as long; the dorsal fin commences nearer the snout than the sinus of the caudal fin, and behind the vertical from the ventrals ; caudal emarginated, scaly at its base ; the pectoral fin equals about one-fourth the length of the head, and its point is about intermediate between its upper axil and the ventral; ventrals decidedly shorter than the pectorals. The color is yellowish-brown, with a dark lateral band extending from the post-humeral spot to a dark area at the base of the caudal; the dorsal fin has a black spot near the base, which crosses the ante- rior rays. Three specimens—an old and young—were collected in the Rio Frijoli, and an adult in another stream emptying into the Atlan- tic. The two adults were 82 millimetres long. This species is interesting on account of its western and north- ern habitat, Piabucina erythrinoides having been discovered in Lake Maracaibo, and Piabucina uniteniata in British Guiana. The present species is most nearly related to the former, but dif- fers in the smaller scales and otherwise. RHAMDIA BRANSFORDII. DeiG.4, At. The head is covered with soft skin above; the adipose fin is long, and enters two and two-thirds times in the total length without caudal; its distance from the dorsal is only equal to half the length of the dorsal; the maxillary barbels extend behind the anus, or the origin of the adipose dorsal, and the outer ones of the mandible beyond the inner axil of the pectorals ; the height of the body below the dorsal equals nearly one-fifth of the total length without the caudal; the head forms less than one-fourth of the length without the caudal; the lower jaw is considerably the shorter; the band of intermaxillary teeth is about six times as wide as deep; the eyes are nearly midway between the snout and subopercular margin; and the diameter is contained two and a half times in the width of the interocular space; the dorsal fin is scarcely higher than long; its first spine is quite slender, and equal to about three-fourths of the head’s length; the pectoral 338 PROCEEDINGS OF THE ACADEMY OF [1876. spine is half as long as the head ; a minute porus axillaris is de- veloped; the posterior rays of the anal fin, when depressed, fall some distance short of the end of the adipose fin; the free por- tion of the tail is somewhat higher than long; caudal fin forked, with both lobes rounded; the length of the lower is contained five and a half times in the total; the color is a uniform purplish- brown; the dorsal fin lightened by the usual basal cross-band. A single specimen was obtained at Camp Marie Caretta, January, 1875. The specimen is distinguished from those of R. Wagneri de- scribed, by the proportions, although it is possible that it may be conspecific with them. LORICARIA URACANTHA. Loricaria uracantha, Kner and Steindachner, Abhandl. bayer. Akad. Wiss., II. Cl., b. x., p. 56, taf. 6, fig. 3; Giinther, Trans. Zool. Soc. London, vol. vi. pp. 893, 478. Hight specimens were obtained at Empire Station. LORICARIA BRANSFORDI. Dl ile GAG aids 8: Snout (probably broad ?—broken off); eye small, its vertical diameter being about equal to half of the width of the interor- bital space; the space itself is flat, and the orbits are surmounted by slight crests; the posterior portion of each orbit has a slight notch tending upwards; (teeth probably small, and numerous in both jaws?); lower side of the head naked; opercula and the marginal scutes of the head with a broad, dense band of nearly equal erectile bristles; scutes of the neck with two obsolete carine ; L. lat. 28; there are six lateral scutes between the pec- toral and ventral fins; the scutes of the thorax are polygonal and in irregular rows; those of the belly scale-like—z. e., with convex margins—and arranged in transverse rows, somewhat arched forwards; the two lateral ridges coalesce on the eighteenth lateral shield; the origin of the dorsal fin is nearly above the middle of the base of the ventral fin; the caudal fin is slightly emarginated, with its upper lobe somewhat produced, and with the upper spine somewhat swollen at its basal half, the lower lobe obliquely truncated. The color is yellowish-brown; the fins with their rays only banded or spotted. _ 1876.] NATURAL SCIENCES OF PHILADELPHIA. 339 A single specimen, somewhat over 130 millimetres long, was obtained at Empire Station. The snout and jaws have been lost, and consequently some important characters require to be as- certained. The species is, however, evidently nearly related to the Loricaria lima of Kner, but is distinguished by differences in proportions. I take pleasure in connecting with it the name of the discoverer, Dr. Bransford. CHETOSTOMUS CIRRHOSUS. Synonymy. Hypostomus cirrhosus, Val., Voyage Amér. Mérid. par d’Orbigny, Poiss., pl. 7, fig. 3; Cuv. and Val., Hist. Nat. Poiss., t. xv. p. 511. Ancistrus cirrhosus, Aner and Steindachner, Abhandl. bayer. Akad. Wiss., ECE beexe pe Ol. Cheetostomus cirrhosus, Gunther, Cat. Fishes B. M., vol. v. p. 247; 7b., Trans. Zool. Soe. London, vol. vi. pp. 3938, 478. Two specimens were obtained, one at Camp Marie Caretta, March 27, 1875, and the other at Empire Station. 340 PROCEEDINGS OF THE ACADEMY OF [1876. ON SOME EXTINCT REPTILES AND BATRACHIA FROM THE JUDITH RIVER AND FOX HILLS BEDS OF MONTANA. BY E. D. COPE. LELAPS, Cope. Proceed. Acad., Phila., 1866, p. 275. Extinct Batr. Rept. N. Amer., 1869, p. 100. Two species of this genus were described in the latter memoir above cited, the LZ. aguilunguis, Cope, and L. macropus, Cope, both from the greensand or Fox Hills group of the cretaceous of New Jersey. A considerable portion of the skeleton of the former was described, including the peculiarities of the ankle-joint, which led me to the conclusion, previously unsuspected by naturalists, that the Dinosauria present affinities to the cursorial birds. The teeth of this species were described and figured, but in the Z. ma- cropus they were, and still remain, unknown. In a preliminary report on the extinct vertebrata obtained by the writer on the Upper Missouri the present year, three addi- titional species were referred to this genus, viz.: the Lelaps incrassatus; L. explanatus, and L. falculus. Their characters were ascertained from teeth alone, so that their pertinence to the genus Lelaps is not fully assured. transverse BED I i ie Lelaps explanatus, Cope, Proceedings Academy, October, 1876. Lelaps faleulus, Cope, loc. cit. Lelaps cristatus, Cope, sp. nov. 4 Another small species well distinguished by the form and coarse denticulation of the teeth, approaching the genus Troddon. The crowns of the teeth are short, stout, compressed, and curved. Both sides are convex, and neither is facetted. The denticles are large, those of the posterior cutting edge the largest, and measuring M. .0005. A characteristic feature is the full devel- opment of the denticulate anterior cutting edge of the crown. This extends to the base, becoming more prominent as it descends. Surface smooth. Measurements. M. Elevation of crown . - : : : 2 5 g O11 . O48 antero-posterior : . : . 006 Diameter of crown | transverse , : : : : .003 ZAPSALIS, Cope. The teeth of this genus are intermediate in form between those of Lelaps and Paronychodon. They have one flat and one con- 1876.] NATURAL SCIENCES OF PHILADELPHIA. 345 vex side, whose junctions form the anterior and posterior edges of the crown, as in the latter genus; and like the latter, there is no anterior cutting edge, but instead, a solid angle. But the pos- terior edge is denticulate as in Lelaps, and the plice or keels of Paronychodon are here only recognizable in low angles. Some light may be cast on the affinities of the latter genus by the dis- covery of Zapsalis. Zapsalis abradens, sp. nov. This reptile was apparently about the size of the Lelaps levifrons. The best preserved tooth is that of a probably adult animal, as it displays considerable attrition, especially on the flat side. Here three worn lines indicate the former existence of as many low longitudinal angles of the surface, of which the median is basal and short. The convex side exhibits four low angles of nearly equal length, all stopping short of the apex. The facets between them, excepting the anterior two, are slightly concave. The denticles are of moderate coarseness, measuring M. .00033. Measurements. M. Elevation of crown . 3 . ; : : 5 ; -0120 : antero-posterior. : : : .0065 cows ' transyerse : ‘ : : : .0030 URONAUTES, Cope. Genus novum Sauropterygiarum. Cervical vertebrae, like the dorsals and caudals, short and transverse, and distinct from each other. Neural arches and transverse processes coossified at ma- turity. Transverse processes of the cervicals simple and depressed. Extremities plesiosauroid. This genus might be referred to Polycotylus, Cope, were it not for the distinctness and greater abbreviation of the cervical ver- tebre. From Cimoliasaurus, Leidy, it differs in the codssifica- tion of the caudal diapophyses and the much greater abbreviation of the cervical vertebree. The centra are amphiplatyan in Cimo- liasaurus, biconcave in Uronautes. From Pliosawrus, Owen, which resembles the present form in the shortness of the cervical vertebrae, the codssified transverse processes of the cervicals sepa- rate it. The present is pre-eminently a short-necked genus of the order. The remains on which it reposes are the cervical, dorsal, and caudal vertebrae, with portions of limb and rib bones. 23 346 PROCEEDINGS OF THE ACADEMY OF [1876. Uronautes cetiformis, sp. nov. The cervical vertebra of this species is of unusual form, being short and transverse, and not wider than deep. In Polycotylus latipinnis this vertebra is much wider than deep, and as long as wide. The neuropophyses are compressed so as to be antero- posterior, and they inclose a rather wide neural canal. ‘The para- pophyses are directed equally downwards and outwards, oceupy- ing the position of the angle of a subquadrate outline, since the sides are nearly vertical. The articular faces are slightly concave, and the centrum is perforated vertically by the usual two fora- mina. A dorsal vertebra found in immediate proximity to the cervical just described is much like that of the Polycotylus latipinnis. That is, it is exceedingly short antero-posteriorly, and has con- cave articular faces, the concavity with flat fundus, and marked with a few obscure concentric grooves. The sides are also slightly concave, and are pierced with a foramen at the superior portion. The vertical foramina are also present. The neural arch is in this specimen separated from the centrum, not having become coéssified. This circumstance might lead to a doubt as to the proper reference of the specimen to this animal, but such doubt has little foundation. In one of the caudal vertebre one of the diapophyses is codssified, and the other is not. The suture of the surface thus exposed is of a very fine texture, and evidently not like that seen in the genera where it is to act as a permanent articulation. In the case of the dorsal vertebra, the suture for the neuropophysis has the same character. This vertebra is much larger than the cervical, but does not much exceed the proximal caudal in size; preserving the relations seen in the Polycotylus latipinnis. Adjoining the border of the fossa of the neuropophysis is a small parapophysial tuberosity. A proximal caudal vertebra has a very small fore and aft diame- ter, and the vertical exceeds the transverse diameter. The dia- pophyses spring from the middle of the sides of the centrum, while the inferior face is separated from the inferior lateral faces by an obtuse longitudinal angle. In general, the form is that of a transverse hexagon. The chevron facets are very slightly de- veloped. Another probably distal caudal vertebra considerably resembles that in the corresponding part of the skeleton of a cetacean. It is without neural arch, transverse, flat below, and a 9 1876.] NATURAL SCIENCES OF PHILADELPHIA. 347 with the two lateral faces of unequal length, the superior being the longer. The vertical perforating foramina join at the neural canal, and there is a short subquadrate plane on each side of the latter. There are no indications of chevron facets. These verte- bre are different from any of those yet known in Polycotylus. Measurements. M. antero-posterior ; EUG Diameter ofa cervical centrum J vertical . : ; . 026 transverse ; : . .029 ata eae : : : : 5 ULL Diameter of a dorsal 2 vertical : : : : : » = .055 Kirsstarérac : : F 5 ‘ a .056 antero-posterior : 5 022 Diameter of a proximal caudal } verte : : : . .040 transverse . : C 062 antero-posterior : : AULD Diameter of a distal caudal j verte ; : c : ars transverse a, 2 , . 038 Diameter of neural canal of the proximal caudal above mea- sured . F : é ; : ‘ 3 - 5 sn Ole Do. of diapophysis of do. at base : : : : +, 018 The distal end of a proximal limb bone is much like the corre- sponding part of Polycotylus latipinnis. It is relatively of large size, flat, and strongly convex at the extremity, which is not transversely truncate. A portion of another limb bone, perhaps belonging to the distal segment, is symmetrical. The shaft is broken off,and displays a large medullary cavity, with thin walls, which soon terminates towards the articular end, in a fundus with a fissure in the bottom. The proximal portion of a rib has a truncate head of an oval outline. The inferior border presents a low tuberosity, which may represent the capitulum. Measurements. ~ M. Width of distal end of proximal limb bone : ; | phue Thickness of the same . : ‘ : 3 2 . . 082 f ‘ ., (longer . : : Bee, Diameter of proximal end of a rib ' shiner } j 028 The bones above described were found together by the writer, on a slope of the cream-colored soft sandstone, which lies above the black shales of Cretaceous No. 4, near Amell’s Creek, Mon- tana. I suppose the formation to be the No. 5, or Fox Hills group of Meek and Hayden. Near them were found shark’s teeth 348 PROCEEDINGS OF THE ACADEMY OF [1876. of the genera Ofodus and Lamna, and a species of Hnchodus. Above them I found lying loose a fragment of a Baculites. CHAMPSOSAURUS, Cope. Genus novum. Vertebre of more than a hundred individuals referable to several species, which I obtained from the Judith River beds of the Upper Missouri region, present characters which de- mand the establishment of a new genus for their reception. The characters presented by the vertebral column are the fol- lowing: The ribs have a single head, which articulates with a prominent tuberculum, excepting those of the cervical vertebre. On these there is a small capitular tubercle below the diapophysis. It commences very small, and inferior in position, being removed, in fact, but a short distance from the inferior middle line in the first vertebra in which it appears. It rises rapidly in the suc- ceeding centra until it is merged in the tuberculum of the diapo- physis. The latter projects from the neural arch, which is free from the centrum, but in none does the base of the diapophysis rise from a point above the floor of the neural canal. On the dor- sals it is vertically compressed. One of the anterior cervicals, probably the axis, is obliquely truncated below its anterior articu- lar face, for a free hypopophysis or os odontoideum. This vertebra has no parapophysis, and the articular faces for the neuropophysis are superior. The few vertebree in each of several series, probably from the sacral region, are more depressed than the others, and the facets for the diapophyses present a greater antero-posterior extent, but none are coossified. The caudal vertebre are distally quite compressed. In all, except the anterior ones, the neural arch is coossified with the centrum, and in such there are no dia- | pophyses. In those with free neural arch, the facets for the neuropophyses turn down on the sides of the centrum. The articular extremities of the centra are plane, those of the caudal series slightly concave. There are no hypapophyses be- hind the axis, excepting a longitudinal carina, which ceases to exist on the dorsal vertebrae. The zygapophyses are simple. The chevron bones are free. The relations of the atlas and axis, though not fully elucidated by my specimens, are peculiar. The former has separate neura- pophyses, which have nearly the shape of those of the Strepto- stylieate Reptilia, resembling much those of the Pythonomorpha. 1876.] NATURAL SCIENCES OF PHILADELPHIA. 349 Although I procured numerous cervical vertebra, there are but few which exhibit the antero-inferior favet for supposed hypapo- physis, already described. The position of this vertebra was in front of the first cervical which displays a parapophysis, and is, on this account, likely to be the axis or the third cervical vertebra. It is the more probably the axis, as there is no other among the large number of vertebra in my collection which can be referred to that position. Its anterior articular face is smooth and like the posterior, showing that the odontoid bone was not coossified with it. Now in the Crocodilia the odontoid bone is united with the anterior extremity of the axis by suture, which may become coéssified with age, while the free hypapophysis is wanting. In the streptostylicate orders the hypapophysis is present, and the odontoid is above it, but united to the axis by suture. On the other hand, in the Rhynchocephalia, the axis is codssified with both odontoid and hypapophysis, and a few succeeding vertebree possess free hypapophyses. ‘Thus it is possible that I am yet unacquainted with the axis of Champsosaurus. One entire rib and the heads of several others are all that were obtained. The former is from the anterior part of the dorsal series, and is stout and short. The head is truncate and com- pressed, its articular face is contracted, forming a narrow figure eight. The shaft is obliquely flattened. The extremities are sepa- rated from the lateral surfaces by a narrow angle, as though capped with cartilage in life, as in the Pythonomorpha. Bones of the extremities are very rare. One fragment resem- bles the proximal end of a crocodilian tibia, and another is like the distal half or more of the tibia of the same type. There is considerable resemblance between the vertebre of this genus and those of Hyposaurus, Ow., from Cretaceous No. 5, of New Jersey, but the relations of the axis and atlas in that genus are as in other Crocodilia, and not like those seen in Champso- saurus. The absence of sacrum precludes the possibility of regard- ing this form as dinosaurian. It rather seems to share some rhynchocephalian characters with general amphiplatyan crocodi- lian resemblances. The shortness and robustness of the thoracic ribs is a feature quite unique, and reminds one of the Batrachia. The teeth are unknown in their true relations, but there are several types in the collections which may be found to belong here. These are of the rhizodont character. 390 PROCEEDINGS OF THE ACADEMY OF [1876. Asa summary of the preceding, I propose to refer the genus Champsosaurus to the order Rhynchocephalia, provisionally. It differs very much from the typical genus of that order, Sphenodon, in the non-coéssification of the sacral vertebrze, and non-union of the neural arches of the vertebree with their centra, and the absence of the chordal perforation of the latter. It differs from the ex- tinct genera Clepsydrops and Cricotus, Cope, in the last men- tioned two characters. On these grounds it may constitute a dis- tinct suborder, under the name of Choristodera. It is possible that the tooth, which I referred to a new genus and species, under the name of Paronychodon lacustris (Proceedings Academy, 1876, October), may belong to one of those of the pre- sent genus. In that case the older generic name takes precedence of the later. I may add that some vertebre of this genus have been figured and described by Dr. Leidy in the Transactions of the American Philos. Society, 1860, without name. I recognize four species among the vertebree, chiefly by charac- ters observed in the cervical region. There is a great discrepancy of size among them, and the small ones may be immature. Champsosaurus profundus, sp. nov. This species is chiefly known from a series of vertebrae found together, and having every appearance of pertaining to the same animal. It consists of a cervical, three dorsal, and a sacral ver- tebree. Other isolated vertebra of several individuals present similar characters. The primary feature is the great vertical diameter of the dorsal vertebra as compared with the transverse measurement. This is occasioned by the great development of the inferior keel, to which the sides of the centrum converge, without concavity. In corre- sponding centra of the C. annectens the inferior face is merely angulate. Another character is the obliquity of the articular faces to a vertical plane drawn at right angles to the long axis of the centrum. This is most strongly marked on posterior dorsals, where the inferior keel is less prominent. The sacral vertebra has a depressed form. An anterior caudal vertebra may belong to this or an undescribed species. It has rudiments only of the chevron-facets, and having a large neural arch, is doubtless from the anterior part of the series. It is more compressed than the corresponding one in C. 1876. ] NATURAL SCIENCES OF PHILADELPHIA. 351 annectens, and has an acute inferior angle, which is wanting in the latter. Measurements. Noveté M. longitudinal . : ‘ - .020 Diameter of cervicai centrum 4 vertical ‘ . F . 020 transverse . : : ue Alle: j antero-posterior . -020 Diameter of anterior dorsal centrum 4 vertical . é =) 30ee ] transverse a 261019 No. 2. ( antero-posterior . 023 Diameter of posterior dorsal centrum 4 vertical. , . 019 a transverse . Seo Champsosaurus annectens, Cope, sp. nov. The greater number of vertebrae obtained belong to this saurian, which may therefore be looked upon as the type of the genus. The cervical which bears the hypapophysial facet presents a carina below, which is only prominent between the articular faces, One such cervical in the collection is rounded below, and may be anterior in the series, or may belong to another species. The ins ferior keel is strong on the other cervicals, but soon disappears on the anterior dorsals. The remaining centra are rounded be- low. The parapophyses where present are knob-like, and the corresponding part of the transverse process is, similar in the anterior dorsal vertebre. The base of the neural arch is nearer the anterior than the posterior articular face. These faces are nearly round in the anterior caudal centra, but soon become ver- tical ovals, with the compressed form. There is a fossa below and in front of the parapophysis, which continues to beyond the anterior dorsals. The dense layer of the surface of the centrum is smooth, except some delicate striations near the articular borders. These are most marked along the meclian inferior face of the caudal vertebrae, which is flat, grooved, and distally acute. I cannot certainly connect the vertebre of a series as those of a single individual. Measurements. No. 1. M. ¢ Bitero-postenias .023 Diameter of a cervical with hypapophysis 2 vertical . eilen transverse - 020 302 PROCEEDINGS OF THE ACADEMY OF [1876. No. 2. M. antero-posterior OLY, Diameter do. without hypapophysis vertical . : . .0165 transverse : ame akis No. 3. antero-posterior f+ Ot Diameter do. without hypapophiyss vertical : 4 . .0105 transverse 3 Jf O1t No. 4. antero-posterior ; . 023 Diameter of an anterior dorsal vertical. : : . 023 transverse. ; 5 - 023 No. 5. antero-posterior 2 . .008 Diameter of an anterior dors} vet i F - -. wOOze transverse : : . 0075 No. 6. antero-posterior . : = OLG Diameter of a sacral centrum vertical : 2 : 009 transverse . 7 3 ») 2009 No. 7. antero-posterior : . .083 Diameter of an anterior caudal j Yee ; F ‘ . 058 transverse : : . .058 No. 8. antero-posterior . 2 OG Diameter of a median caudal jee : : P 3. ge let transverse . ; : 7) Oleh INO: 9: antero-posterior . . 014 Diameter of a posterior caudal ; vertical . 4 . . 0086 transverse . ; : = 2007 A vertebra not distinguishable from the corresponding one of this species was found near Amell’s Creek, on a bank of deposit of the Fox Hills group (No. 5), with the bones of the Uronautes cetiformis, supra. I cannot account for this circumstance, as it is the most abundant fossil of the Judith River beds (No. 6). Champsosaurus brevicollis, sp. nov. On one occasion the writer discovered a number of vertebra of this genus close together, and in such relation as to induce the belief that some of them belonged to the same individual. Parts of several were obtained, however, adding another evidence of the 1876. ] NATURAL SCIENCES OF PHILADELPHIA. 353 manner in which the fossils of this formation have been dislo- cated and scattered. The evidence for the existence of this species must be allowed to rest at present on a cervical vertebra, with free hypapophysis. This body differs from the corresponding one in the C. annectens in its greater brevity as compared with its length. The vertical and transverse diameters exceed the longitudinal in the C. brevicollis, while in the C. annectens the length exceeds both. The inferior aspect of this centrum is broadly rounded, not carinate as in C. annectens. The value of this character is uncertain, but a centrum similarly rounded be- low (above alluded to) has the more elongate form of the C. an- nectens. Measurements. M. antero-posterior ‘ : ‘ 3 SOL8 Diameter of centrum } vertical . ‘ F ; : ee! transverse . 5 Fi é : 7 OLS Champsosaurus vaccinsulensis, sp. nov. This reptile is indicated by a posterior dorsal vertebra in which the common base of the neural arch and diapophysis is decurved to below the middle of the side of the centrum. This surface has somewhat the outline of the section of a T-rail, the inner portion being on the superior face of the centrum. The centrum is shorter than the corresponding ones of the C. annectens and C. profundus, so that the basis of the neural arch approaches near the borders of the articular faces above. The centrum is perforated by two ver- tical foramina as in most Sawropterygia. The osseous tissue of the bone is quite dense, and the surface is smooth. Measurements. M. antero-posterior A : : . 026 Diameter of centrum feta : ; 4 : ; + ,..029 transverse s c ‘ : . 045 Besides the much larger size, this species differs from those previously referred to this genus in almost all details of propor- tion, ete. SCAPHERPETON, Cope. Genus novum Batrachiarum. Vertebre deeply biconcave, | with opposed, but not continuous, foramina for the chorda dor- salis. Neural arch with zygapophyses, and well-developed neural spine. Centrum with vertically compressed, short diapophysis 354 PROCEEDINGS OF THE ACADEMY OF [1876. near the posterior extremity, a prominent hypapophysial keel, and prolonged neural spine. Supposed proximal limb bone with a branch-like trochanter. Supposed teeth in several rows, at- tached in shallow alveoli, those of the marginal series larger; the crowns obtusely conic and simple. In the above diagnosis are expressed the general characters of a genus of probably tailed Batrachia which has left remains of seve- ral species in the Judith River beds of the Upper Missouri region. Although the vertebra resemble no little those of clepsydrops, Cope, a rhynchocephalian lizard from supposed triassic or permian formations, the atlas is that of a batrachian. The limb bone pro- bably belonging to it, is unlike that of any genus of the Proteida or Trachystomata, differing also from that of Menopoma, but approaching nearly that of the typical salamanders. The diapo- physes are different in form from those of the Trachystomata Proteida and Amphiumidx, but resemble in their vertical com- pression those of Menopoma. They are generally broken in the specimens, but where preserved, are much shorter than in that genus, being even less produced than in most of the recent sala- manders. The prominent keel of the median line below is not found in salamanders, and it has no posterior prolongation resem- bling the structure seen in Amphiuma and Ceciliide. The produced neural spine is a character not found among tailed Batrachia, and the posterior direction which it takes reminds one of the Dinosauria more than anything else, and is not like the form seen in Lacertilia. It is a prolongation of the roof-like extension of the neural arch seen in some of the tertiary sala- manders of France. The structure of the proximal limb bone, and the form of the diapophyses of the vertebrae refer this genus with much proba- bility to the Urodela. The produced neural arch, and the pro- bably complex disposition of the teeth, indicate a family different from any of those now living. The biconcave centra place it nearest to the Amblystomide. The teeth above mentioned are attached to a fragment of a jaw- bone. The crowns are all imperfect, and mostly broken off. There are three series of smaller teeth and a marginal series of teeth of one half greater diameter. They exhibit a moderate pulp cavity, and the superficial investment of the crowns is not inflected. It has a minute granular rugosity, and the bases of the teeth are rugose 1876. ] NATURAL SCIENCES OF PHILADELPHIA. 300 with impressed puncte. The teeth are described here because it is not known to which species they belong. It is, indeed, not certain, but only probable, that they belong to this genus. Four atlases preserved indicate two species; one being more depressed than the other three, and the anterior cotyli therefore more transverse. The vertebre indicate four species. It is probable that they present some pecularities at different points in the same column, the caudals at least differing insome degree from the others. The characters of the species are quite well marked. Scapherpeton tectum, sp. nov. Represented by a vertebra which is one of the best preserved in the collection. The most prominent specific character is seen in the entire roofing over of the neural canal between the anterior zygapophyses, and in the downward production of the inferior median line of the centrum, and accompanying downward pro- longation of the articular cups. The chordal perforation is at the superior fourth of the vertical diameter of the cups. The neural spine is produced backwards and curved upwards, and is narrowed between the posterior zygapophyses, and is striate grooved on the under surface. About half of the posterior zygapophysis projects beyond the edge of the cup of the centrum. Immediately below the anterior edge of the posterior zygapophysis, the diapophysis begins. It is vertical, of an irregular figure 8 in section, and is directed outwards and backwards. A foramen passes under its middle, emerging a little before the middle of the same horizontal diameter of the centrum. It is joined by another which strikes it from below at right angles. There is a deep notch embraced be- tween the superior part of the diapophysis and the posterior zygapophysis. The neural canal is wider than deep. A fragment accompanied this vertebra when found, which resem- bles the articular portion of the mandible. There is no angle projecting behind the quadrate facet, which is oblique, truncating the extremity of the ramus. The lower edge is acute, behind roughened, and a thickening extends along the middle of the inner side of the ramus so far as preserved. The character is that of a Urodele Batrachian. 356 PROCEEDINGS OF THE ACADEMY OF [1876. Measurements. M. ( antero-posterior ss + “ . .0875 Diameter of centrum 4 vertical . : ; : : . .0750 transverse 4 ¢ é : . 0500 Vertical diameter of diapophyses . - 4 . .0500 Transverse diameter of neural spine between posterior zy ga- pophyses . . . .0500 Depth mandibular ramus at ican of dices eounine . .0800 Scapherpeton laticolle, sp. nov. Vertebre of several individuals of smaller size than those referred to the S. tectum differ in the less extensive development of the roof connecting the anterior zygapophyses, and the greater compression of the centrum, in consequence of the downward pro- duction of the inferior keel. The neural arch is openly notched between the anterior zygapophyses, but the notch is bounded by a recurved lamina distinct from the zygapophyses. The dia- pophyses are much as in S. fectum; the ridge from the inferior portion of it is quite prominent, and includes with the base of the neural arch a deep fossa. Accompanying a dorsal vertebra like those of this species, and probably belonging to the same skeleton, is an atlas of a more depressed form than those presumably belonging to the other species. The median tuberosity is well developed, constricted at the base, and much flattened. The condyloid facets are narrow and transverse. Measurements. M. antero-posterior . : SSV0N) Diameter of dorsal centrum | verte : ‘ : : . 2050 transverse : : : - 030 Width of the neural canal. d ‘ . . 2 . .020 Vertical diameter of base of diapophysis. ‘ : . 030 If it should appear that the dorsal vertebree do not represent a species distinct from the §S. dectum, the S. laticolle may rest on the atlas described. The limb bone above mentioned is associated with the neural arch of a vertebra of the character ascribed to this species. Both extremities are eroded so as not to display the forms of the con- dyles, though almost the entire length is preserved. The tro- chanter is imperfect, but its base is that of a subeylindric process. The head of the bone is subtriangular, and the section of the 1876. ] NATURAL SCIENCES OF PHILADELPHIA. 357 distal end an oval with a flat side. The diameter contracts gradually to the middle. Measurements. M. Length of bone . : : : ‘ : : : . .0150 proximally . 2 : ; ; : : . .00386 Diameter ; medially . i : : ; : : . .0019 distally : : : : 5 ; F . 0037 This bone is plainly that of a urodele saiamander. Scapherpeton excisum, sp. nov. This salamander is represented in the collection of the expedi- tion by vertebree of three individuals of different sizes. They all agree in having the anterior zygapophyses separated by the con- cave excavation of the roof of the neural canal usual in ordinary salamanders, and in the moderate development of the hypapophy- sial keel. As a result, the articular extremities of the centra are not produced so far inferiorly as in §S. laticolle. The longitudinal ridge from the inferior part of the diapophysis is pronounced, and separates a deep fossa above it from another below it. The longi- tudinal perforation of the base of the diapophysis issues in the superior fossa, while in the two smaller specimens a vertical per- foration joins it from the inferior fossa. As in the preceding two species, one articular face is a little deeper than the other. Measurements. M. longitudinal , ‘ : - °.009 Diameter centrum No. 1 } verte : 3 ‘ 4 £2006 transverse . p : ; . 005 Width of neural canal do. . : j : é i . 008 Depth = ae A ¢ ¢ ‘ : ‘ a eOOLS longitudinal : : : . 0060 Diameter centrum No. 2 vertical : ? , . . 300388 transverse . z ' 4 . .00380 Specimen No. 1 is as large as the corresponding portion of an Amphiuma means. Scapherpeton favosum, sp. nov. The vertebra which I select as typical of this species is more distinct in character from those of the three species above described, than they are from each other. Although the centrum presents a strong inferior keel, its border is not horizontal or con- vex, but concave, and the articular cups are proportionally little elongated downwards. The diapophyses have at their bases a 358 PROCEEDINGS OF THE ACADEMY OF [1876. relatively small vertical diameter, and the longitudinal perforation enters below and before the base and not behind it. The longitu- dinal ridge from the inferior part of the latter is very prominent and horizontal, bridging over the vertical perforation, which enters the superior lateral fossa. It is separated below from the posterior perforation by a short oblique bridge. The neural arch is lost from this specimen. There are other vertebree which display a slightly developed in- ferior keel, and articular cups little produced downwards, but the fosse are less developed than in the one described. Measurements. M. antero-posterior : : c . .006 Diameter of centrum vertical B ; : < F . 004 transverse. : j 4 ‘ . .008 The typical individual was about as large as the Menopoma. HEMITRYPUS, Cope. Represented by a vertebra of the general character of those of the genus Scapherpeton, but which lacks the foramen chord dorsalis of the posterior half of the centrum, and is not carinate on the inferior surface. The diapophysis is directed backwards just below the posterior zygapophysis, inclosing with it a notch into which the anterior zygapophysis is received. Anterior zyga- pophyses connected by a prolongation of the neural arch. I had suspected that this vertebra might be one of those of tie cervical region of a species of Scapherpeton, but the position of the foramen chorde dorsalis renders this highly improbable. The only position to which it could be assigned in the column of this genus would be that of the axis. But the foramen is present in the posterior half of the atlas and thus probably in the axis in Scapherpeton, as in vertebree from all other regions of the column, so that such an exception as is presented by the present centrum is not to be looked for. The absence of the carina, and the cylin- dric form of the centrum, add to the belief that the species does not belong to Scapherpeton. Hemitrypus jordanianus, Cope, sp. nov. No emargination between the anterior zygapophyses; neural spine directed upwards and backwards. The diapophyses verti- cally compressed, directed downwards, inwards, and backwards, 1876.] NATURAL SCIENCES OF PHILADELPHIA. 359 and not giving origin to a strong ridge on the side of the cen- trum, as is seen in the species of Scapherpeton. Neither is there any fossa on the side of the centrum as in that genus. There is a small longitudinal foramen which enters the inner base of the in- ferior half of the diapophysis. There is a low ridge on each side of the neural arch, which extends backwards and inwards. The anterior articular face is a wide oval somewhat contracted below, and is pierced by a foramen at a point within the superior third of the vertical diameter. It is not so deeply excavated as in the species of Scapherpeton. The posterior articular face is a regular vertical oval, is concave, but not excavated, as is seen in the centra of the genus just mentioned. The inferior face of the centrum is rounded, with some feeble lateral ridges. Measurements. M. longitudinal . c : : 5 HOA Diameter of centrum 4 vertical . F ; c ‘ . 0050 transverse ; ‘ ; é . 0040 Total elevation at middle . : ; : : : . .0090 Expanse of posterior zygapophyses . : : ; . 0070 es 2 r diapophyses : A 5 3 . 0095 About the size of the Menopoma allegheniense. This batrachian is dedicated to Prof. D. 8. Jordan, of the North- western Christian University, author of the Manual of the Ver- tebrata of the Eastern United States. 360 PROCEEDINGS OF THE ACADEMY OF [1876. OUR SIDEREAL SYSTEM, AND THE DIRECTION AND DISTANCE TO ITS CENTRE. BY JACOB ENNIS. I. Tue Form oF our SIDEREAL SystTEM.—Before we can find the centre of an object, we must have a knowledge of its form. The form of our system is determined by the ring of the galaxy ; because it is computed to contain eighteen millions of stars, while all the other stars situated around and within that ring are sup- posed to number only about two millions. The best observers declare that they can look fairly through the galaxy, and see be- yond only the black ground of empty space. Its ring form is fur- ther proved by the fact that the great mass of its stars are of the same small magnitudes, from the 9th to the 12th. If it were merely the appearance of a stratum of stars extending outward from our own vicinity, it would contain many more stars of large mag- nitudes, and these magnitudes would regularly and gradually de- crease in size from their increasing distances. But no such ap- pearance is presented. Therefore, as Sir John Herschel announces, * it is not a stratum, but an annulus.” In the general direction of the galaxy, though situated far be- yond, there are very many easily resolvable nebulw, which are unique among all nebule, from their very irregular forms and aspects. From their appearances and positions, and resolya- bility, they must be members of our own sideral system, and they occupy the same relative position to the galaxy, as the systems of Jupiter, Saturn, and Uranus hold to the ring of the asteroids. In some places observers cannot apparently see through the galaxy; stars, or rather nebule, appear beyond one another in- definitely. These appearances are explained by the resolvable nebule just mentioned, which are the extremely distant members of our system, and by the irresolvable nebule in the same direc- tion, though far beyond, which are independent sidereal systems. The two seem to make a continuity of stars. Mere vision in such cases fails to distinguish these distant sidereal systems from the outlying members of our own system; the same as Saturn and Sirius when side by side, seen by mere vision, seem to be equally distant. Irresolvability is at present a decisive test between the 1876. ] NATURAL SCIENCES OF PHILADELPHIA. 361 outlyers of our own system, and other independent sidereal systems. That our sidereal system has definite bounds, we may believe from the definite boundaries of other distant sidereal systems. Often they are regularly round or elliptical; and even those with irregular contours may have their stars to revolve in nearly cir- cular orbits; the same as our solar system must appear to distant observers to be extremely irregular in contour, although its revo- lutions are nearly circular. Neither is our opinion of the definite boundary of our system disturbed by the appearance of new stars with every new power added to the telescope. These newly-discovered stars may be its smaller members, and comparatively near, and visible only by high powers. Nor is it an argument against the ring form of the galaxy, be- cause it is broken by a slight transverse rift in the southern hem- isphere. My recollections are distinct that this rift is exceedingly narrow, hardly observable, and smaller by far than the longitu- dinal rifts in both hemispheres. Therefore all objections are easily answered, and we have solid grounds to conclude that our sidereal system is round, and in the main, disk-like in form, with the vast majority of its stars in or near the plane of the galaxy. The ring form of the chief mass of our system, is confirmed by the existence of other rings of stars, as the annular nebule, the ring of the asteroids, and the rings of Saturn, composed, there is good reason to believe, of very little stars, the majority not larger than meteorites. IJ. Tue Postrion oF THE CENTRE OF GRAVITY.— From the form of our sidereal system the conclusion is clear and irresistible that the centre of gravity of the system must lie in the plane of the galaxy. It is also equally clear that this centre must be situated in the centre of that plane. Because the stars in general are equally numerous, and equally large and bright in all extended regions of that ring. They appear a little brighter towards the southern pole; but this seems an indication that our own position is a little nearer that side of the galactic ring. III. Att THE Srars oF ouR S1IDEREAL SysTEM REVOLVE WITH HIGH VELOCITIES AROUND ITS CENTRE OF GRAVITY.—It was for- merly supposed that the vast distances between the stars cut off this intergravitating force. Newton, in his Principia, uses this 24 362 PROCEEDINGS OF THE ACADEMY OF [1876. language: ‘*The fixed stars, therefore, being at such vast dis- tances from one another, can neither attract each other sensibly, nor be attracted by our sun.” This opinion was generally held among his followers, one of whom has remarked: ‘So remote are the nearest of the fixed stars, that it may be doubted whether the sun has any sensible influence on them.” It is remarkable that the thought occurred to no astronomer to calculate the force of gravity from our sun on the fixed stars, until more than a quarter of a century after the distances of some of these stars had been approximately discovered. Then this was first done by myself, and the amount of this foree was found to be surprisingly large. To present an impressive and graphic view of that amount, I brought it out in terms of the velocity around our sun required for gaining a centrifugal force so great as to prevent a revolving body from falling in the sun. I employed two methods of de- monstration quite independent of each other, and by both the same results were obtained. As these methods have already been stated in the “ Origin of the Stars,” they need not be repeated here. By them it was proved that our sun acts so powerfully on Alpha Centauri that, if there were no other influence, Alpha Cen- tauri would have to revolve around our sun at the rate of 145 miles an hour to gain a counterbalancing centrifugal force. That star, judging from its distance, and its amount of light, must be two and a third times greater than our sun. Therefore its power of gravity alone on our sun is such that, without any other influ- ence, our sun must revolve around it at the rate of 222 miles an hour to gain a counterbalancing centrifugal force. Judging from its distance and its light, Sirius is at least sixty times greater than our sun. Therefore our sun would have to revolve around Sirius at the rate of 580 miles an hour to avoid falling into its flames. In all these instances, the gravity of a single star has alone been calculated, and not the combined force of the two. These velocities impress strongly on our minds the greatness of the force of gravity between the stars of our sidereal system. How inconceivably mighty must be the united force between the twenty millions of stars. How strongly must they all be im- pelled toward this common centre of gravity. And how swift must be their velocities around that centre to gain a centrifugal equal to the centripetal force. Now, first, we understand the ne- cessity of such high velocities as those of 61 Cygni, and of 1876.] NATURAL SCIENCES OF PHILADELPHIA. 363 Arcturus, and of other stars ; that is, velocities from nearly 2000 to nearly 3000 miles per minute, velocities about double any of those seen among the planets of our solar system. It is evident that the stars of the galaxy must all move in the same direction around in the plane of the galactic ring, otherwise they wound fiy off, and soon there would remain no ring. It is also evident that such rings of stars revolving with high velocities, both in our own and in other sidereal systems—annular nebulee—coincide perfectly with the nebular theory which teaches the absolute necessity of ring formations abandoned by centrifu- gal force in high velocities of revolution. IV. Tue D1rEcTION FROM OUR OWN POSITION TO THE GALACTIC CENTRE or to the CENTRE OF GRAVITY OF OUR SIDEREAL SYSTEM. —Our own position is certainly on the north side of the galactic plane; that is, on the same side with Ursa Major, and not on the side on which Orion appears. The median line of the galaxy, or its plane, does not coincide with a parallel great circle. Between the two, as projected on the heavens, there is a distance of about 2°, the precise distance being not yet determined within half a degree, more or less. This appears as follows: The median line of the galaxy is distant about 32° from the north pole; but on the op- posite side of the heavens it is distant from the south pole only about 27°. Other measurements in other regions, not polar, cor- respond. This difference of five degrees must be equally divided, and there remains about 24° as the distance in are between the median line of the galaxy and a parallel great circle. Our own position therefore is situated, as measured by our great circle, about 24° away from the galactic plane, and on its north side. We are further confirmed in this conclusion because it explains the fact that more stars are seen in the southern galactic hemis- phere than in the northern. Many of these southern stars are really on the north side of the galactic plane, but being ourselves so much further north, they are projected on the southern galactic hemisphere. At first view this seems unlikely, but forthcoming proofs are convincing. Now, being on the north side of the galactic plane, and if we were equally distant all around from the galactic ring, then the conclusion would be certain that the direction of the centre of the galactic plane, or the centre of gravity of our system, would be precisely toward the south galactic pole, that is, at about 1199 364 PROCEEDINGS OF THE ACADEMY OF [1876. N, P, D, and a little east of the equinoctial colure. In such case there could be no other decision. But because the galactic ring appears a little brighter in the southern regions, it seems probable that we are situated a little nearer towards the southern side of that ring; consequently the galactic centre must be projected on the heavens a little to the north—the geographic north—of the south galactic pole, say in the tail of the constellation Cetus. This northern projection of the galactic centre may be illustrated as follows: Let N be a point in N the geographic northern side of the galaxy, S the opposite point in the southern side, A the B south galactic pole, and the dot at ¢ the centre Conte of the galactic plane or centre of our system. D-*~ A Then our position at D being a little nearer the southern side of the ring at S, the centre ec would be projected on the heavens at JB, that is, S geographically north from the south galactic pole A. In the figure there is an exaggeration in the position of B to render the principle plain. Therefore we may affirm, without pretending to absolute preci- sion, that the DIRECTION of the centre of our sidereal system, and consequently its centre of gravity, must lie a little east of the equinoctial colure, and a few degrees north geographically of the south galactic pole; that is, in the tail of the constellation Cetus. It remains now to demonstrate— V. Tue DIsTANCE FROM OUR OWN POSITION TO THE GALACTIC CENTRE, OR CENTRE OF GRAVITY OF OUR SIDERAL SystTEM.—To find this we have the following data: First, that the median line, or plane of the galaxy, is distant from a parallel great circle 25° ; second, that the distance of the galactic ring from our own posi- tion is such as to require 2000 years for its light to reach us. This latter is Sir John Herschel’s estimate of its nearest stars of the 9th magnitude. Strave computes that light requires 3400 years to reach us from the galactic stars of the 12th magnitude. In this demonstration the 9th magnitude galactic stars, with the distance for light travel of 2000 years, will be taken. In the figure S represents the position of our sun or our own position. The dotted circles are the distances of the stars of the several numbered magnitudes. A B is the plane of the galaxy, and C its centre. D # is the plane of a parallel great circle. S C is the 1876.] distance from ourselves to the galactic centre, or the centre of our sidereal system. S F isa line perpendicular to the galac- tic plane. Our position S is made a little nearer to the geographi- eal southern side of the galaxy at B, for the reason already stated. D A is the are, and D S A the angle between the ga- lactic plane and a parallel great circle, at present assumed at 23°. peak = DVS: Aw light: re- quires 2000 years to travel from A to S, or from A to F nearly. Here we have a right-angled tri- angle with three known ele- ments, namely, A # = 2000; ps A r=—21°. S F A= 90°. From these elements it follows from the most simple of all trig- onometrical processes that S Ff equals 87. Therefore it re- quires light 87 years to pass between ourselves and the plane of the galaxy, or about the same to reach the galactic centre at C. But according to the esti- mates of astronomers, light re- quires 85 years to reach us from the stars of the 5th magnitude; therefore the centre of our side- real system is distant from our own position about as far as the stars of the 5th magnitude. But the amount of the are D A or the angle S A Fis not yet precisely determined. If it be only 2°, then the distance from the plane of the galaxy is such NATURAL SCIENCES OF PHILADELPHIA. 365 > 366 PROCEEDINGS OF THE ACADEMY OF [1876. that light from there requires 70 years to reach us, and it must lie beyond the stars of the 4th magnitude, as it is drawn in the ac- companying figure. If the angle S A F equals 14°, then the light from the region of the galactic plane requires 52 years to reach us, and that plane must lie beyond the stars of the 3d magnitude. And so on, after the following table, where the third column ex- presses the number of years required for light to reach us from the stars of the several magnitudes, according to Struve, aud also from the galactic plane, when the first column expresses the dif- ferent values of the are )) A or the angle S A F. AngleS AF. Star magnitudes. Distances in years. 1 5 > ; - 15 ON ee ES I EOE aie amas Peeirio 2 5 ; : 28 HCY Tee : ; 3 - = By) 3 : : : 43 130 . 4 : : - : 5 52 4 2 “ . 5 61 20 : F : : 70 5 5 ¢ 85 BRON S00 lp LAE Pe phere a deel Se Spears < 2 3 : . . . 104 6 : 5 6 Sono A iOne 4 s - c : = ld We have now discovered approximately both the DIRECTION and the DISTANCE to the centre of our sidereal system. I need not at this early day be precise in my statements of either of these ele- ments: these will require the careful observations and measure- ments of many years. When Copernicus had announced the centre of our solar system, his discovery was not vitiated nor rendered the less valuable because he made such an enormous error about the distance of that centre. Even yet, after the studies of 10 generations, that is, of 333 years, astronomers are still endeavoring to find more nearly the distance to the centre of our solar system. These round numbers just named measure the long flight of time which has intervened between the discoveries of these two centres, the centre of our solar and the centre of our sidereal system. In attaining precision in the distance to the centre of our sidereal system, the first element to be determined is the are D A, or the angle S A F. Its nearest value seems to me at present to be 2°, 1876. ] NATURAL SCIENCES OF PHILADELPHIA. 367 and the figure is drawn on that supposition, locating the sidereal centre between the stars of the 4th and 5th magnitudes. In addition to the data contained in the five sections already given, our present determination of the direction and distance is confirmed by the observed movements of the stars. Hitherto, the proper motions of the stars, amounting to nearly 2000, have pre- sented the most wild and disorderly confusion. Nothing can be more hopeless and forbidding than an attempt to find our sidereal centre from the study of these motions. But our present deter- mination of that centre shows the causes of this apparent confu- sion. It is because we are situated on one side of our system, far outwardly and away from the centre, with some stars interior and other exterior to us; precisely the same reason why the mo- tions of the planets seemed so tangled before the discovery of the centre of our solar system. I will here point out the opera- tions of this cause in detail, along with other causes of this apparent disorder. 1. In our figure the two stars within the dotted circles, marked with arrows at 2 and 7, move in the direction of the arrows. On the face of the heavens, or on a celestial globe, they seem to move around in contrary directions, the same as they seem to move in our figure in contrary directions around our position at S. But in reality they both move in the same direction around our side- real centre at C. 2. The stars at 7 and 8, marked with arrows, seem, from our position at S, to move in contrary directions, but in truth they both move in the same direction around the sidereal centre at C. 3. Our sun’s motion must give apparent motions to many stars, and some of these may be eontrary to their real motions, the same as our earth gives retrograde motions to the planets. To separate these apparent from their real motions will be a task of many years, even after we learn the true direction of the sun’s motion. 4. As our sun is on the north side of the galactic plane, and nearly equidistant from the galactic ring all around, it follows that the plane of his orbit is nearly, perhaps quite, at right angles to the galactic plane. It is evident also that thousands of other stars move in planes either at right angles, or highly inclined, to the galactic plane. Hitherto all this has been a source of per- plexity, but now we may begin to lay down the lines of their nodes 368 PROCEEDINGS OF THE ACADEMY OF [1876. on the galactic plane, and make real progress in sidereal astro- nomy, evolving beautiful order out of this apparent confusion. 5. In a system like our solar system, with a large central orb, and all the stars nearly in the same plane, it is generally conceded that the revolutions of these stars must be around in the same direction; contrary motions being incompatible with stability. But this cannot be affirmed of our sidereal system, which has no large central and controlling orb, where the stars are very far apart, and where their orbits are highly inclined in opposite di- rections, nearly or quite at right angles to the galactic plane, and so have come to move in opposite directions around the sidereal centre. This has occurred to thousands of stars in our sidereal system. It has occurred also in other far distant sidereal systems, for they are globular in shape. If only a few appeared round we might suppose them discoid, with the planes of their disks per- pendicular to their lines of sight. But such large numbers of round systems argue globularity of form. 6. My discovery of the intergravitation among the members of our sidereal system, as stated in Section III. of this paper, aids to prove that collisions must be impossible, or very rare between the members of our system, even when they move in opposite directions. When two stars are meeting from opposite directions, they are under the influence through gravity of all the neighbor- ing stars, drawing them from the line toward each other’s centres of gravity, and therefore the chances are infinite against their moving towards each other’s centres of gravity. They must ap- proach each other, not directly, but obliquely ; they may pass so near to each other as to remain forever under the power of their mutual gravitation, revolving around their common centre of gravity, and becoming adouble star. Hence, the wonderful spec- tacle in the heavens of ten thousand double and multiple stars, with many more still to be discovered. . ‘ : : . E. T. Cresson. Conservator . . : : . James Ridings. Publication Committee . : . KE. T. Cresson, J. L. LeConte, M.D., Chas. A. Blake, Geo. H. Horn, M.D., Chas. Wilt. JAMES Ripines, Conservator. REPORT OF THE CONSERVATOR OF THE BOTANICAL SECTION. The Conservator presents this first report since the organiza- tion of the Botanical Section, upon the condition of, the additions to, and the needs of the Academy’s Herbarium. The Section has been so recently established, that such a report may be expected to be but imperfect, and to be regarded rather as preliminary than otherwise. But as much work has been done during the year by the Committee on Botany, appointed under the old by- laws of the Academy, aided by the volunteer efforts of other members, who will, it is hoped, continue to co-operate with the Section, it will be proper to embrace a retrospect of what has been done during the whole year. And first, the Conservator would congratulate the members of the Section and of the Academy, as well as the scientific public, that the botanical treasures of the Academy have been exhumed from the dusty and dingy den in which they were entombed in the former building, and that they are now made really accessible to students. The removal was accomplished at the beginning of the year. Before attempting to re-arrange the collection, the leading Herbaria of the country were visited, and the details of their 1876. ] NATURAL SCIENCES OF PHILADELPHIA. 395 arrangements examined. For very valuable suggestions in this regard we are indebted to Prof. Gray, of Cambridge; and also to Prof. Eaton, of New Haven; and to P. V. Leroy, the Curator of the Torrey Herbarium, at Columbia College, New York. Our own Curators, availing themselves of these and other suggestions, have spared no pains or expense in fitting up for our department a series of shelves and cases which fully meet our present wants, and which are in every way suitable to the careful preservation of the plants, and for facility of comparison and study. It is due to Mr. Tryon to say that, fully appreciating our needs in this respect, he entered heartily into the plans, and, as Curator, gave them his careful supervision. These cases were completed about the Ist of May, and the labor of transferring the plants from the old unwieldy portfolios to the new shelves was carried on and completed during the summer mainly by the aid of Messrs. Meehan, Burke, and Parker. Among the packages removed from the old building were enormous piles of duplicate specimens which had been accumulating for years, some of which had lain buried, suffering from the ravages of in- sects, and few of which had been carefully examined. These, by the labors of Messrs. Burke, Meehan, Schimmel, Leffman, and others, have been examined, the ruined plants thrown out, and the remainder brought into some kind of partial arrangement, which, when completed, will enable us to select from these stores such specimens as may be desirable for the Herbarium, and to render the remainder useful for purposes of exchanges. This labor our Committee on Duplicates will doubtless continue and complete. The Committee on the Herbarium, at its last meeting, decided on the general arrangement of the collection on a plan similar to that adopted at the Kew Gardens, and at Dr. Gray’s Herbarium at Cambridge. The Conservator is now preparing the necessary tablets for displaying the names of the Natural Orders, and the lists of the Genera in each order. When this work is completed, the ease of consulting the Herbarium will be vastly increased, and any one of the 9000 known genera may be turned to, as readily as to a word in the dictionary. During the past year the following donations have been re- ceived for the Academy’s Herbarium :— 185 lots of cones of Coniferze, and acorns of Oaks. Presented by Josiah Hoopes. 396 PROCEEDINGS OF THE ACADEMY OF [1876. 31 species of Plants, collected near Peking, China, by Rev. 8. Wells Williams, 1868-9. Presented by John H. Redfield. 171 species of Plants, from Norwegian Mountains, collected by Prof. Willhelm Bork. Presented by Dr. H. C. Wood. Leaves of Argyroxriphium Sandwicence, from the volcanoes of Kileau, Hawaii, Sandwich Islands. Presented by J. A. Ryder. Branch of Pinus pungens, bearing cones. Presented by Dr. Isaac Lea. Specimen of Gaylussacia brachycera, Gray, from Millsborough, Sussex County, Delaware. Collected and presented by W. M. Canby. Specimen of Rice Grass, Paspalum, from prairies, Sedgwick County, Kansas. Presented by Atchinson, Topeka, and Sante Fé Railroad Company. Sample Alfalfa, raised by W. H. Egan, Sedgwick County, Kansas. Presented by Atchinson, Topeka, and Sante Fé Rail- road Company. Specimen of Habenaria rotundifolia, from N. Vermont, a new locality. Presented by Dr. A. Gray. Several specimens of Salix longifolia, with abnormally devel- oped buds, produced by the sting of an insect. From the banks of the Pecos River, Texas. Presented by Lieut. A. C. Markley. Specimen of Onoclea sensibilis, L., Var. obtusifolia, Torr., from near Germantown. Presented by Isaac C. Martindale. Bark from which Tapa cloth is made. From Samoan or Navigators’ Islands. Presented by Dr. Ruschenberger. Specimens of Leonurus glaucus, collected near the mouth of Wissahickon Creek. Presented by I. C. Martindale. Hydnum ? Presented by Mr. Whelen. Cone of Pinus coulteri, Cupressus, n.sp., and Pinus sabriniana. From California. Presented by Mr. Begg. A collection of Woods, Coffee, Cotton, Fibres, Bark, Seeds, Resins, India-rubbers, Leaf Tobacco, Sarsaparilla, Cone of Awro- caria, etc. From Brazil. Presented by Dr. Jose de Saldanha da Gama, of the Brazilian Commission. Cypress Knee, from Arkansas. Presented by Dr. Lawrence. Specimens of Cotton, Millet, ete., from Arkansas. Presented by Dr. Geo. W. Lawrence. Four species of Ferns: Asplenium pinnatifidum, A. tricho- manes, A. montanum, and Trichomanes radicans. Collected at 1876.] NATURAL SCIENCES OF PHILADELPHIA. 397 Rock Castle Springs, Kentucky. Presented by Miss G. H. Rule, through J. C. Martindale. Cone of Pinus Torreyana, Parry, from Southern San Diego County, California (Pallner Collection, No. 368). Presented by John H. Redfield. As regards the future needs of our Herbarium, both as to ar- rangement and as to perfecting the collection, the Conservator has but too recently entered upon his duties to speak fully. It is sufficient now to say that there is already apparent the need of an enormous amount of labor, both scientific and mechanical, and of considerable expenditure, to make our collection what it ought to be. The completion of the Order tablets, and the ar- ranging of the plants in the new genus covers, will absorb much labor, but will require little expenditure beyond what has already been incurred. But we must look forward to the day when the whole of our large collection shall be properly mounted upon paper, as the only way to preserve the specimens from injury in handling, and from a still greater danger, that of confusion arising from misplacing of labels. There is great reason to believe that we have suffered very greatly from such misplacement in times past, and that many type specimens of Nuttall and others have become subjected to doubt, and thus deprived of value. But before this consummation can be properly reached, there is a vast amount of careful, conscientious, and critical scientific work to be done, especially in the general Herbarium, in the re-elaboration of the determinations, culling out of rubbish, and replacement of inferior specimens by better,and in cataloguing with reference to the supply of our deficiencies. In all these departments there is plentiful room for the labor of all the young botanists of the Academy, and for all the knowledge of the older ones. JoHn H. REDFIELD, Conservator. The election of Officers for 1877 was held in accordance with the by-laws with the following result :— President . . . W.S. W. Ruschenberger, M.D. Vice-Presidents due y WE His: De. V AX, J. L. LeConte, M.D. 398 PROCEEDINGS OF THE ACADEMY OF [1876. Recording Secretary . Edw. J. Nolan, M.D. Corresponding Secretary Geo. H. Horn, M.D. Treasurer ; - - Wm. C. Henszey. Librarian : ; . Edw. J. Nolan, M.D. Curators : 4 ., 008. Leidy, M.D., Wm. 8S. Vaux, Chas. F. Parker, H. C. Chapman, M.D. Councillors to serve three J.S. Haines, years Geo. Vaux, Wn. H. Dougherty, Aubrey H. Smith. Councillors to serve anun- Jos. Wharton, expired termoftwo years Chas. P. Perot. Finance Committee . « Wm.S. Vaux, Aubrey H. Smith, Edw. 8. Whelen. ELECTIONS DURING 1876. MEMBERS. January 25.—Rev. W. Q. Scott, Dr. Henry M. Fisher, Dr. Alfred Whelen, Dr. W. F. Waugh, U. 8. N., Edwin H. Fitler, Charles L. Sharpless, Charles H. Rogers, Dr. Wm. R. Cruice. ~ March 7.—Wwm. Harris Kneass, James H. Windrim, Crozer Griffith, Jesse W. Starr, Wm. L. Abbott, Robert Wood, Thomas S. Root, Howard Spencer, James Ridings, Jas. W. McAllister, Charles Wilt, Wm. 8. Pine, John Meichel, Charles A. Blake, James H. Ridings, Geo. B. Dixon, Geo. Biddle, Horace F. Jayne, J. Sergeant Price. March 28.—John Akhurst, Theo. L. Mead, Stuart Wood, Dr. John Eckfeldt, Edward Tatnall, Jr., Benj. H. Smith, James M. Rhodes, John T. Lewis, Jr., John S. Martin, Henry Pemberton, Charles W. Trotter, Charles Roberts, Edward K. Tryon, Edward Potts, Pierre Munzinger, Dr. Washington Hopkins Baker, Rath- mell Wilson. 1876. ] NATURAL SCIENCES OF PHILADELPHIA. 399 May 2.—William Nelson, Rev. Charles A. Dickey, Dr. Robert Hess, George A. Piersol, John Wister, Oliver Bradin, Dr. Wm. B. Brewster, Dr. J. Henry C. Simes, Pliny E. Chase. June 6.—Dr. Chas. E. Slocum, Edward Taylor, Maxwell Som- merville, Henry M. Laing, William Wharton, Jr., C. H. Cramp, Charles H. Rogers, A. R. Justice, Mrs. Gertrude A. Quimby, J. 8S. Helfenstein, Thomas J. Audenreid, Edward P. Borden. June 247.—John Russell, Isaac C. Martindale, Arthur Erwin Brown, Dr. A. C. Lambdin, Geo. A. Wright, Harvey Fisher. July 25.—E. O. Thompson, Dr. Albert E. Foote. September 26.—Dr. Isaac T. Coates. October 31.—H. F. Whitman, Edwin A. Barber, Dr. W. H. For- wood, U.S. A. November 28.—Walter H. Ashmead, Louis F. Benson. CORRESPONDENTS. March '.—M. Alphonse Pinart, Paris; Edward T. Stevens, Salisbury, England. March 28.—Baron Ferdinand von Mueller, of Melbourne, Aus- tralia; Prof. Austin Flint, M.D., of New York. June 6.—Prof. Wentzel Gruber, of St. Petersburg, Russia. July 25.—José de Saldanha da Gama, of Rio Janeiro; Dom Pedro Iil., Emperor of Brazil; Capt. Luiz de Saldanha da Gama, of the Imperial Brazilian Navy. August 29.—Dr. 8. H. Linn, of St. Petersburg, Russia; Prof. Paul Groth, of Strassburg; Dr. James Hector, of New Zealand. September 26.—Don Alvaro de la Gandara, of Madrid, Spain; Col. Juan J. Marin, of Madrid, Spain; Signor Alessandro Castel- lani, of Rome. October 31.—Col. W. L. Ludlow, Eng. Corps, U.S. A. November 28.—Dr. A. S. Packard, Salem, Massachusetts; W. H. Holmes, U.S. Geol. Sury.; Prof. Laurengo Malheiro, of Lisbon, Portugal. 400 CORRESPONDENCE. CORRESPONDENCE OF THE ACADEMY. 1876. January.—H. M. Hull, in reference to donations from the Tasmanian Commission. Societa Toscana di Scienza Naturali, Pisa, requesting exchanges and transmitting publications. American Association for the Advancement of Science ; Astronomischen Gesellschaft, Leipzig ; Natural. History Society of Northumberland, Durham, and Newcastle- upon-T'yne; severally acknowledging receipt of publications. Senckenbergische Naturforschende Gesellschaft, Frankfurt a. M.; Royal Academy of Amsterdam ; severally acknowledging receipt of, and transmitting publications. Belfast Museum; Observatory of Madrid; Naturforschende Gesellschaft zu Emden; L’ Academie Royale des Sciences Suedoise de Stockholm; Geological Survey of India, Calcutta ; Kaiserliche Akademie der Wissenschaften in Wien; Royal Meteorological Institute, Utrecht ; Naturwissenschaftliche Gesellschaft zu Chemnitz; Aertzlichen Verein, Frankfurt ; Université Catholique de Louvain; severally transmitting publications. February.—Naturhistorisches Verein in Augsburg ; Senckenbergische Naturforschende Gesellschaft ; severally acknowledging . receipt of, and transmitting publications. Royal Society of Edinburgh, acknowledging receipt of publications. Naturhistorisches Verein in Passau ; New York State Library ; : Konigliche Norwegische Universitiit zu Christiania; severally transmit- ting publications. Smithsonian Institution, thanking the Academy for the privilege of stor- ing its plates. University Observatory, Oxford, inviting contributions to the library. Commission Geologique de |’Empire du Brésil. University of Norway, notice of the death of Dr. Wm. Boeck. CORRESPONDENCE. 401 March.—Société Hollandaise des Sciences, 4 Harlem; Geological Survey of India, Calcutta ; Gesellschaft Naturforschende Freunde; severally transmitting publica- tions. Naturforschende Gesellschaft zu Freiberg, acknowledging receipt of pub- lications. Dr. Alfred Giinther, acknowledging receipt of diploma. Jas. P. Holmes, Minneapolis, Min., requesting names of members collect- ing plants with a view to exchange. April.—Dr. A. Flint, Jr. ; I. T. Stevens, Esq., Salisbury, Eng.; severally acknowledging election as correspondents. Gesellschaft zur Beférderung der gesammten Naturwissenschaften, Mar- burg; acknowledging receipt of, and transmitting publications. A. J. Phillips, in reference to Mr. Jno. S. Phillips’ bequest to the Academy. Société Impériale des Naturalistes de Moscou, acknowledging receipt of publications. Naturforschende Gesellschaft in Danzig. Naturwissenschaftliche Verein fiir das Fiirstenthum Liineburg. Mannheimer Verein fiir Naturkunde ; severally transmitting publications, May.—Archeological Society of Ohio, inviting the Academy to partici- pate in the International Convention of Archeologists. Smithsonian Institution ; Buffalo Society of Natural History ; Bergen Museum; severally acknowledging receipt of publications. Sammlung fiir Kunst und Wissenschaft, Dresden, transmitting publica- tions through the German Embassy at Washington. Musée Teyler; 4 Harlem; K. k. zoologisch-botanische Gesellschaft Vienna; severally acknowledg- ing receipt of, and transmitting publications. F. W. Hutton, acknowledging receipt of exchanges for Moa skeleton from Otago Museum. Robt. J. Stevens, Clerk of the House of Representatives, in reference to a memorial to Congress by the Academy. A. Bohatta, Vienna, in reference to a proposed device in telegraphy. Jesse W. Starr, acknowledging election as a member. June.—Kaiserliche Mineralogische Gesellschaft zu St. Petersburg ; Kénigliche Sachsische Gesellschaft, Leipzig; severally transmitting pub- lications. Canadian Institute; New York Academy of Sciences ; Yale College Library; severally acknowledging receipt of publications. Baron F. von Mueller, Melbourne, Australia, acknowledging election as correspondent. 402 CORRESPONDENCE. Museum of Comparative Zoology, presenting a collection of fishes. Lyceum of Natural History of New York, announcing change of name to New York Academy of Sciences. Chas. E. Slocum, in reference to election as member. J. T. Audenried, acknowledging election as a member. July.—Joseph Menges, Frankfurt a. M., in reference to being sent on an expedition. Boston Society of Natural History, acknowledging receipt of publications. A. E. Brown, acknowledging election as a member. Chas. H. Stubbs, M.D., in reference to models of stones marking Mason and Dixon’s line. August.—EK. T. Stevens, Esq., presenting work on Stonehenge. M. C. Cooke, in reference to publication of a paper in journal. Zoological Society of Philadelphia, acknowledging the receipt of two green snakes, Akademie Royale de Lisbonne ; University Library, Cambridge, Eng. ; Belfast Natural History and Philosophical Society ; Edinburgh Geological Society ; severally acknowledging receipt of publi- cations. Belfast Naturalists’ Field Club ; Verein zur Verbreitung Naturwissenschaftliche Kentniss in Wien; seve- rally transmitting publications. September.—Leyden Astronomical Observatory ; Academie Royale des Sciences des Lettres et des Beaux-Arts ; French Minister of Public Works at the Exposition ; Naturforschende Gesellschaft zu Emden; severally transmitting publica- tions. Royal Geological Society of Ireland; K. Hof und Staatsbibliothek, Munich ; Naturforschende Gesellschaft zu Bamberg ; Statistical Society, London; severally acknowledging receipt of publica- tions. Mexican Commission at the Exposition, in reference to publications. Jno. Hitz, Consul-General, Switzerland, in reference to donations from the Swiss Commission. October.—La Société des Sciences de Finlande ; L’ Academie Royale Suedoise des Sciences de Stockholm ; Schweizerische Gesellschaft fiir d. gasammten Naturwissenschaften, Bern ; Société Zoologique de France ; Die Naturforschende Gesellschaft in Berlin; severally transmitting publi- cations. Canadian Institute ; CORRESPONDENCE. 403 Yale College Library; Musée Teyler, 4 Harlem; severally acknowledging receipt of publications. Société Nationale des Sciences Naturelles de Cherbourg, in regard to exchanges. Dr. Isaac Lea, giving duplicate copies of his works on conchology to the Academy. Dr. Isaac Lea, accompanying specimens. Dr. Isaac Lea, in reference to depositing a meteorite, with analysis of the same. Prof. Wentzel Gruber ; Prof. Alphonse Pinart; severally acknowledging election as correspondents. C. B. Dyer, in reference to the disposal of his collections. November.—Societa Toscana di Scienza Naturali, Pisa, in regard to ex- change of publications. Prof. W. G. Farlow, Boston, asking for the loan of a specimen of A%cidium pyratum. Leeds Philosophical and Literary Society, stating inability to supply deficiencies. Museum of Comparative Zoology, Cambridge, transmitting photograph of Professor Agassiz. E. A. Barber, acknowledging election as a member. A. A. Outerbridge, in behalf of Mr. Gilbert, of Demarara, in regard to a collection of reptiles. Dr. R. M. Bertolet, in reference to depositing a collection of stone imple- ments. December.—Seiior Carvalho de Borges, Brazilian Minister, acknowledging receipt of letter announcing the election of Dom Pedro II. as a corre- spondent. 404 ADDITIONS TO LIBRARY. ADDITIONS TO THE LIBRARY 876. Adams, A. Leith. Ona Fossil Saurian Vertebra (Arctosaurus Osborni), from the Arctic Regions. Dublin, 1875. The Author. Adamson’s Histoire Naturelle du Sénégal, 1757. J.S. Phillips. Agardh, Jacobo Georgio. Species genera et ordinis Algarum. Vol. III. Wilson Fund. Agassiz, L., large Photograph of. Alex. Agassiz. Aguas Potable de Mexico. Prof. Alfonso Herrera. Altum, Dr. Bernhard. Forstzoologie. I., I1., and III. 1872-73. I. V. Williamson Fund. Annual Report of the Librarian of Congress for the year 1875. The Author. An Outline of Japanese Education, prepared for the Philadelphia Interna- tional Exhibition 1876, by the Japanese Department of Education. 1876. The Japanese Commission. Bailey, L. W. and Edw. Jack. The Woods and Minerals of New Bruns- wick. J. Laidlow. Bancroft, H. H. The Native Races of the Pacific States of North America. Vol. V. New York, 1876. I. V. Williamson Fund. Barcena, Mariano. Noticia Geologica de una parte del Estado del Aquas- calientes. Mexico, 1876. ‘The Author. Baxter, J. H. Statistics, Medical and Anthropological, of the Provost- Marshal-General’s Bureau. 2 Vols. Washington, 1875. The Author. Belleville, E. La Rage au Point de Vue Physiologique. The Author. Bentham, Geo. et J. D. Hooker. Genera Plantarum. Vol. Il. Pars II. Londini, 1876. I. V. Williamson Fund. Bernardino de Souza, C. F. Par& e Amazonas pelo encarregado dos Tra- balhos ethnographicos. 3a Parte. The Brazilian Centennial Com- mission. Lembrancas e Curiosidades do Valle do Amazonas. The Brizilian Cen- tennial Commission. Bernstein, Julius. The Five Senses of Man. New York, 1876. I. V. Williamson Fund. Berzelius, lithographic portrait of. Dr. J. Lindahl. Bianconi, G. La Theorie Darwinienne et la Creation dite Indépendante. Review. The Author. Billings, E. Paleozoic Fossils. Vol. I. and II. Part I. Geological Sur- vey of Canada. Binkerd, A. D. Mammoth Cave, Kentucky. Cincinnati, 1869. John A. Ryder. Pinneyia lerrosteal Mollusca. 3 vols. 4to. J.S. Phillips. Binney, W. G. Notes on American Land Shells. Vol. 1]. Part 1V. The Author. Blainville’s Manuel de Malacologie. 2 vols. 1825. J.S. Phillips. Blanchard, E. Les Insectes. Nos. 1-4. Paris, 1876. I. V. Williamson Fund. Blanford, W. T. Eastern Persia. Vol. I. The Geography and Narra- tives by Majors St. John Lovett, and Kuan Smith, and an Introdue- tion by Major-General Sir Frederic John Goldsmid. Vol. 11. Zo- ology and Geology. By W.'T. Blandford. I. V. Williamson Fund. ADDITIONS TO LIBRARY. 405 Bleeker, P. Atlas Ichthyologique des Indes Orientales Néerlandaises. Livr. 28, 29, and 30. Wilson Fund. Blytt’s Norges Flora. Christiania, 1861-74. I. V. Williamson Fund. Bock, H. H. Kreiiter Buch. Strazburg, 1551. J. H. Redfield. Bois-Reymond, Emil du. Gesammelte Abhandlungen zur allgemeinen Mus- kel- und Nervenphysik. ler Band. I. V. Williamson Fund. Bolton, H. Carrington. Index to the Literature of Manganese, 1596 to 1874. The Author. Borre, A. Preudhomme de. La Possibilité de la Naturalisation de la Lep- tinotarsa decemlineata. The Author. Bosanquet, R. H. M. Ona new form of Polariscope. The Author. Botelho de Magalhes, B. C. Theoria das Quantidades Negativas. The Brazilian Centennial Commission. Botella y de Hornos, D. F. de. Descripcion Geologica-Minera de las Pro- vincias de Murcia y Albacete. Madrid, 1860. The Geological Sur- vey of Spain. Boucard, Adolphe. Monographie List of the Coleoptera of the Genus Plu- siotis of America, North of Panama. Notes sur quelques Trochilidés. Notes sur les Trochilidés du Mexique. Catalogus» Avium hucusque descriptorum. Londini, 1876. The Author. Bouvier, A. Afrique Occidentale. Catalogue Geographique des Oiseaux. Paris, 1875. The Author. Bowerbank, J.S. A Monograph of the British Spongiade. Vols. I., IL, and III. I. V. Williamson Fund. Bradley, F. H. Geological Chart of the United States. The Author. Brandegee, IT. S. The Flora of Southwestern Colorado. The Author. Brauns, Dr. D. Der mittlere Jura in nordwestlichen Deutschland. Cassel, 1869. I. V. Williamson Fund. Brazil. The Empire of Brazil at the Universal Exhibition of 1876, in Philadelphia. The Brazilian Commission. Breve Noticia sobre a Provincia do Maranhao. The Brazilian Centennial Commission. Brewer, W. H., Senero Watson, and Asa Gray. Geol. Surv. Cal. Botany. Vol. I. Polypetale and Gamopetale. Cambridge, 1876. I. V. Williamson Fund. Brewster, Wm. Some Additional Light on the so-called Sterna Portlan- dica, Ridgway. The Author. Briosi, Prof. Giovanni. Sulla Phytoptosi della Vita. Palermo, 1876. The Author. Bronn, H. G. Klassen und Ordnungen des Thier-Reichs, 6er Band I. Abth. 1 Lief. II. Abth. 8, 9, 12, and 13 Lief. V. Abth. 11 and 12 Lief. Ter Band V. Abtheil 9 and 10 Lief. Wilson Fund. Brown, Robert. The Races of Mankind. Four vols. in two. I. V. Wil- liamson Fund. Briihl, C. B. Zootomie aller Thierklassen. Atlas, Lief. 4 and 5. Wien. I. V. Williamson Fund. Brusina, Spiridione. Secondo Saggio dalla Malacologia Adriatica. Fossile Binnen-Mollusken aus Dalmatien, Kroatien und Slavonien. Contribuzione pella Fauna dei Molluschi Dalmati. Contribution a la Malacologie de la Croatie. The Author. Bruylants, Gustave. Recherches sur les Hydrocarbures. Catholic Univer- sity of Louvain. Biichner, Dr. L. A. Uber die Beziehungen der Chemie zur Rechtspflege, 1875. The Author. 406 ADDITIONS TO LIBRARY. Buckley, S. B. Second Annual Report of the Geological and Agricultural Survey of Texas. The Author. Buonanni, Recreatione dell’ Occhio, 1681. J.S. Phillips. Bursian, Dr. Conrad. Uber den religiosen Charakter des griechischen My- thos, 1875. The Author. Button, F. T. List of the California Land and Marine Shells for exchange. Oakland, Cal. The Author. Canimhoa, L. Relatorio sobre Zootechnia. The Brazilian Centennial Commission. Capron, Horace. Reports and Official Letters to the Kaitakushi, by Horace Capron and his Foreign Assistants. Tokei, 1875. K. Kuroda. Carpenter, Horace F. A Catalogue of the Shell Bearing Mollusca of Rhode Island. The Author. Carpenter, Wm. B. Introduction to the Study of the Foraminifera. By Wn. B. Carpenter, assisted by Wm. K. Parker and T. Rupert Jones, I. V. Williamson Fund. Castro, Don Manuel Fernandez de. Aitobatis Poeyii. Madrid, 1873. The Author. Catalogue delle Conchiglie componenti la Collezione Pigacci. Parte prima della Conchiglie vicenti. Roma, 1866. T. A. Conrad. Catalogue of H. C. Roeters van Lennep’s Collection of Shells, 1876. The Publishers. Catalogue of the West Virginia State Exhibit. W. Virginia Centennial Jommission. Catalogue of the Chinese Imperial Maritime Customs Collection. Chinese Centennial Commission. Catalogue of the Austrian Department, Philadelphia Centennial Exhibition of 1876. The Commission. Catalogue of recently added books, Library of Congress, 1873-75. The Librarian. Catlow’s Conchologist Nomenclator. Interleaved. 1845. J.S. Phillips. Census of the Town of Madras, 1871. Madras, 1873. The Indian Govern- ment. Centennial Exhibition, Philadelphia, 1876. Dominion of Canada, Province of Ontario. Catalogue of Exhibits in Education Department, 1876. J. Laidlaw. Educational Institutions. Province of Ontario. J. Laidlaw. Chemins de Fer de la Province de St. Paul. Brézil, 1875. Brazilian Cen- tennial Commission. Clark, S. F. The. Hydroids of the Pacific Coast of the United States, south of Vancouver Island. The Author. Clark, W. B. Mines and Mineral Statistics of New South Wales. N.S. Wales Centennial Commission. Cole, Jas. E. The Mechanical Construction of Water. New York, 1876. The Author. Conrad’s New Fresh Water Shells. John S. Phillips. Conrad’s Unionide. Vol. I. J. 8. Phillips. Conrad’s American Marine Conchology, 1831. J. 8. Phillips. Conrad’s Tertiary Fossils. J.S. Phillips. Cooke, M. C. Mycographia seu Icones Fungorum. Part I. Wilson Fund. Cope, Edw. D. Article on Osteology. Descriptions of some vertebrate Remains from the Fort Union Beds of Montana. The Author. On the supposed Carnivora of the Eocene of the Rocky Mountains. The Author. ADDITIONS TO LIBRARY. 407 Cortazar, Daniel de. Memorias de la Comision del Mapa Geologico de Es- pata. Descripcion de la Provincia de Cuenca. Madrid, 1875. The Author. Descripcion fisica, geolégica y Agrolégica de la Provincia de Cuenga. The Geol. Survey of Spain. Cotton Manufacture in the United States. J. 8S. Phillips. Coutinho, J. M. da Silva. O Caco na Exposicao universal de 1867. The Brazilian Centennial Commission. Cox, E. T. Seventh Annual Report of the Geological Survey of Indiana, made during the year 1875. Indianapolis, 1876. G. M. Levette. Cozzen’s Geology of New York, 1843. J. S. Phillips. Crépin, Francois. Materiaux pour servir a l’Histoire des Roses. Troisi¢me Fasc. Gand, 1874-75. The Author. Croft, Thomas. The Self-Propagating Nature of Centrifugal Force. Papeete, 1875. The Author. Crosby, W. O. Report on the Geological Map of Massachusetts. Boston, 1876. The Author. Cuences Carbonifer de Asturias. Geol. Surv. of Spain. Curioser Botanicus, oder Sonderbahres Kriiuterbuch. Dresden and Lipzig, 1745. Louis Godey through C. F. Parker. Cuvier’s Regne Animal. Twelve Numbers of Fishes and Mollusks. 3 Vols. Mollusks and 2 Vols. Zoophytes. J. S. Phillips. Cuvier’s Legons d’Anatomie Comparée. 2d Ed. 1837. J.S. Phillips. Cyon, E. Methodik der Physiologischen Experimente und Vivisectionen. 1 Vol. and atlas. I. V. Williamson Fund. DaCosta’s Elements of Conchology. 1776. J.S. Phillips. Dale, T. Nelson. A Study of the Rhaetic Strata of the Val di Ledro in the Southern Tyrol. 1876. The Author. Dana, Jas. D. Cephalization. Part V. The Author. Davila’s Catalogue. Vol. I. J.S. Phillips. Dawson, Geo. M. Keport on the Geology and Resources of the Region in the vicinity of the 49th Parallel. Montreal, 1875. Geol. Surv. of Canada. Dawson, J. W. The Fossil Plants of the Devonian and Upper Silurian Formations of Canada. 1871. Geol. Survey of Canada. Report on the Fossil Plants of the Lower Carboniferous and Millstone Grit Formations of Canada. Figures and Descriptions of Canadian Organic Remains. Decades 2 to 4. Geol. Survey of Canada. Descriptive Notices of the Models, Maps, and Drawings collected under the Auspices of the Ministry of Public Works. M. Lavoinne. Descriptive Catalogue of a collection of the Economic Minerals of Canada. J. Laidlow. Detailed Census Returns of the Bombay Presidency. Part III. Bombay, 1874. Indian Government. Die Industrie des Kénigreichs Wiirtemberg. Prag, 1873. The Author. Dillwyn’s Catalogue of Shells. Vols. 1 and 2. J.S. Phillips. Donayre, D. Felipe Martin. Bosquejo de una Descripcion fisica y geologica de la Provincia de Zaragoza. The Geological Survey of Spain. Douglass, J. W. and John Scott. The British Hemiptera. Vol. 1. Hem- iptera-Heteroptera. I. V. Williamson Fund. Drechsler, A. Der Arabische Himmels—Globus. Katalog der Sammlung des K. mathem-phys. Salons zu Dresden. Royal Museum at Dresden. 408 ADDITIONS TO LIBRARY. Dunker und Zittel, Drs. Paleontographica; 2ler Band, 7e and 8e Lief.; 22er Band, Te Lief.; 23er Band, 8e and 9e Lief.; 24er Band. 2e and 3e Lief. and General Register, les Heft. Cassel, 1876. Wil- son Fund. Kcole des Ponts et Chaussées. Cours Preparatoires ; Eléves Externes ; Catalogue des Livres composant la Bibliotheque ; Catalogue des Modelles, Instruments, &c. ; Collection de Dessins ; Programmes de l’enseignement interieur. From M. Lavoinne. Edwards, A. Mead. ‘The Microscope in Gynecology. Newark, 1875. The Author, through Biol. and Micr. Section. Emerson, Geo. B. A Report on the Trees and Shrubs growing naturally in the Forests of Massachusetts. Vols. 1 and 2. Second Edition. Boston, 1875. I. V. Williamson Fund. Encyclopedia Methodique. Mollusca. Wols. land 2. J.S. Phillips. Encyclopedia Britannica. Vols. I1].and ITV. I. V. Williamson Fund. Engelmann, Geo. Notes on Agave. The Oaks of the United States. The Author. Erlenmeyer, Dr. E. Ueber den Einfluss des Freihern Justus von Liebig auf die Entwicklung der reinen Chemie. ‘The Author. Esper’s Pflanzenthiere. 1791. J.S. Phillips. Faber, Carl. Der Bau der Iris. Leipzig, 1876. I. V. Williamson Fund. Falkenberg, Dr. P. Vergleichende Untersuchungen iiber den Bau der Vegetationsorgane der Monocotyledonen. Stuttgart, 1876. I. V. Williamson Fund. Featherstonhaugh, G. W. Geological Report of an examination made in 1834 of the elevated Country between the Missouri and Red Rivers. 8vo. Washington, 1835. I. V. Williamson Fund. Ferussac’s Histoire Naturelle des Mollusques. 5 Vols. Folio. J. S. Phillips. Fialho, Anfriso. Don Pedro II. Empéreur du Brésil. Notice Biograph- ique. Bruxelles, 1876. The Brazilian Centennial Commission. Figuier, Louis. The Human Race. New York, 1872. Geo. W. Tyron, Jr. Fischer, M.,et H. Crosse. Mission Scientifique au Mexique et dans |’ Amé- rique Centrale. Recherches Zoologique, 7me Partie. Etudes sur les Mollusques terrestres et fluviatiles. Paris, 1875. The Authors. Fitzinger, L. J. Der Hund und seine Racen. le, 2e, and 3e Lief. Tiibin- gen, 1876. I. V. Williamson Fund. Fleming’s History of British Animals. 1842. J. 8. Phillips. Foote, A. E. The Naturalist’s Agency Catalogue. Part First. Minerals. - The Author. Freiesleben, J. C. Geognostischer Beytrag. 4 Volumes in Three. Frey- berg, 1807. I. V. Williamson Fund. Fries, KE. Icones Selecte Hymenomycetum-Hungarie. II. and III. Hun- garian Academy of Sciences. Fromentel, E. Etudes sur les Microzoaires. 3me Fasc. Paris. I. V. Williamson Fund. Galvani, L. Collezione delle Opere. 2 Vols. 4to. From Acad. of Sciences of the Inst. of Bologna. Gastinet, Mr. Memoria sobre a cultura do Cafezeiro no Yemen. The Bra- zilian Centennial Commission. Geinitz, H. B. Die Urnenfelder von Strehlen und Grossenhain. “Royal Museum at Dresden. Geinitz und Marck, Drs. Zur Geologie von Sumatra. Royal Museum at Dresden. ADDITIONS TO LIBRARY. 409 Geol. Surv. of Canada. Report of Progress 1866 to 1875. 6 vols. Gentry, T. G. Life-Histoiries of the Birds of Eastern Pennsylvania. Vol. I. Phila. 1876. The Author. Gervais, Paul. Zoologie et Paléontologie Générales. 2me Série. Livr’s 14,15 and16. Paris, 1876. Wilson Fund. Giebel, C. G. Thesaurus Ornithologie. Ser Halbband. Leipzig, 1876. I. V. Williamson Fund. Gill, Theo. Arrangements of the Families of Mammals, Fishes, and Mol- lusks. 3 copies of each. Smithsonian Institution. Gillmore, Parker. Prairie and Forest: a description of the Game of North America. London, 1874. I. V. Williamson Fund. Giudice, F. del. Dell Instituzione de Pompieri. Universalita dei Mezzi di Previdenza, difesa e salvezza per la Calamita deg!’ Incendi. Academy of Bologna. Goode, G. Brown. Classification of the Collection to illustrate the Animal Resources of the United States. Washington, 1876. The Author. Gould’s Report on the Invertebrata of Massachusetts. J.S. Phillips. Gould, John. A Monograph of the Trogonide. Parts III. and IV. Lon- don, 1875. Wilson Fund. The Birds of Asia. Parts 26 and 27. London, 1875. Wilson Fund. The Birds of New Guinea and the adjacent Papuan Islands, including any new species that may be discovered in Australia. Parts | and 2. London, 1875-76. Wilson Fund. Gray’s Conchology of the Voyage of the Blossom. J. 58. Phillips. Greenhow’s Oregon and California. 2d Ed. 1845. J.S. Phillips. Grote, A. R. Check List of the Noctuide of America, North of Mexico. I. Bombycize and Noctuelite (Nonfasciate). Buffalo, 1875. The Author. Gruber, Dr. Wenzel. Monographie iiber das Corpusculum triticeum. St. Petersburg, 1876. The Author. Gumaelius, Otto. Om Malmgrens Aldersféljd och deras Anviindande siisom ledlager. Geol. Surv. of Sweden. Gunther, Albert. Description of the Living and Extinct Races of Gigantic Land Tortoises. Parts I. and II. Contribution to the Anatomy of Hatteria (Rhynchocephalus, Owen). Description of Ceratodus. The Author. Gurney, J. H. Rambles of a Naturalist in Egypt and other Countries. London. Mrs. E. P. Gurney. Guthrie’s Universal Geography. London, 1795. J.S. Phillips. Haeckel, Ernst. Die Perigenesis der Plastidule. Berlin, 1876. I. V. Williamson Fund. History of Creation. Vols. 1 and 2. I. V. Williamson Fund. Ziele und Wege der heutigen KEntwickelungsgeschichte. Jena, 1875. I. V. Williamson Fund. Arabische Korallen. Berlin, 1876. I. V. Williamson Fund. Haldeman’s Fresh Water Univalve Mollusca. 2 Vols. 1842. J. S. Phillips. . ‘ Half Hours nith Modern Scientists. Second Series. New Haven, 1873. John A. Ryder. Hall, Chas. E. On Glacial Deposits in West Philadelphia. The Author. Hanley, Sylvanus and Wm. Theobald. Conchologia Indica, Part 8. Lon- don. Wilson Fund. Hanley’s Young Conchologist. 1840. J.S. Phillips. Harcus, Wm. South Australia: its history, resources, and productions. London, 1876. Samuel Davenport. Same. Lorin Davenport. 27 410 ADDITIONS TO LIBRARY. Hartley, Walter Noel. Air in its relations to Life. I. V. Williamson Fund. Hartmann, Dr. Robt. Die Nigritier. ler Theil. Berlin, 1876. I. V. Williamson Fund. Haughton, Rev. Samuel. On the Tides of the Arctic Seas. The Author. Hayden, F. V. Report of the United States Geological Survey of the Territories. Vols. 1X. and X. Department of Interior. Another Copy of Vol. IX. F. V. Hayden. Annual Report of the United States Geological and Geographical Survey of the Territories for 1874-1876. Department of the Interior. Hector, Jas. Geological Sketch. Map of New Zealand. The Author. Heer, Oswald. Flora Fessilis Helvetie. Je Lief. Die Steinkohlenflora. Zurich, 1876. I. V. Williamson Fund. Hemsley, U. B. Handbook of Hardy Trees, Shrubs, and Herbaceous Plants. 1873. I. V. Williamson Fund. Hess. W. Bilder aus dem Aquarium. I. V. Williamson Fund. Heude, R. P. Conchyliologie Fluviatile de la Province de Nanking. Fase. 1. I. V. Williamson Fund. Hewitson, Wm. C. IJllustrations of Diurnal Lepidoptera. Parts IV. and VI. Lycenide. Wilson Fund. 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Philadelphia, 1876. The Author.. Hoysradt, Lyman H. Catalogue of the Phznogamous and Acrogenous Plants, growing without cultivation within five miles of. Pine Plains, Duchess Co., N. Y. Torrey Botanical Club. Hugo, M. le Comte Leopold. Extraits de deux lettres addressées a D. B. Boncompagni. ‘The Author. Hugo, Leopold. 1874 and 1875. The Society. Annales de la Société d’Agriculture, Histoire Naturelle et Arts Utiles. 4me Série, Tome 6me and 7me, 1873-74. The Society. Mémoires de |’ Academie Impériale des Sciences, Belles-Lettres et Arts. Classe des Lettres. Tomes 8 and 16. Paris, 1859-74. The Society. Nancy. Bulletin de la Société des Sciences de Nancy. Série II., ome L., 6e Année, 1873, Fasc. III.; Tome II., Fasc. IV. Paris, 1876. The Society. Orleans. Mémoires de la Société d’Agriculture, Sciences, Belles-Lettres et Arts d’Orleans. 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INDEX :-TO GENERA. PANISLCS Steet cicichale’s cc clase ais aiere eter arts 173 ALOT a 5 CE SE CO e GOD OOOO EC DEES 828 PMU INES TIOV EL OTe Ye yerouatel’s ove aval escfalercishe 65 AM CIDE INTE NCR Cer OCEe CRIS ICI benifits 185 PCCM AULIMLO MD 10, x s'oi0.0.6/'s: aie sicle's alo 185 PMH TIED SGM: ctepeie slclelatots/< oicle sie. s stalls 52 MOISE arrest oleic jorsiers's 6s 239, 246, 247 PNMULO CMS yle cys: vays oie stacia's cied elaats 258 OWT s 3 o6gloe DEO COnorIn’ Gee ta 148 PAB GUS isa) oi aiclciatsio avs si steecars leo 308 PAE eAy Mites se) «oles 0) 5 caghere, erekeieuetspale 189 PATA OPH EMU) 6). 1a%s\v/oin-'s 01s sccelstelere 251 JANE OEE doe OOCe ONC OOD EO eD Opie c 142 PATE TIS cfs: sheig cs ais ai) avo, a sielaverare telat 194 OSS) a eee 286, 289 PAMNVOTISTHA ois: «5 ) 3ys121 5,51 3) sv siekereil ete dl PAMPIA NSS UT iat asicye) cy v/s crak siers'nc)ofeters) SoC Galligan peice ccttsteie see 286, 287, Callocystites CMib VCO EWS Rec eosscudcsa04 210, GRinTaH GR Anos acoso sopcodonods Cam panulaznmereie cece recer Campanularia @Wamptonectes=e sisi 2 Dw (Jt) ee @ wo = © Eboroziphius Eleolite Cr eee eee ee ee ee eee _ Emery _ i=) co | Endoptygma..;.....0:00seuees | Epeira Bphestta . sccccs . ee ROMO MSccs sis ceoas css et eee s UCT a eee ig ce PETAL AM ian, w'anse Bh ereperel ete. a orev eae ERA UUTOSATEGUS 5) <)5)< ests oss sual ieatts 953 | Liriodendron..............:... RM UMD 20 orc Ss Fw asc ss .0 oases 210, 217 Tees rh svnislnia' a accials eet wen leke ¥alloysite® <<... ... ESO are « 140 | PIVONTA. 0 eee eee ee eee ee eee eee MMBUEVONV ELGG: ses cs sc aoeds otter 235 | Lophophyllum................ EIRONTUINES! Ss, casei sae joner0': owns S cieverstore 278 | Loricaria eee e eee ee eee eee PAOMNPCUS ooo ae ss as eticnare 274 | Lottia..................... 246, Haploscapha Vee enake Aa cc ck tne Sate 273 } Tunatia eee ennecceccceeneecenece Harpella..... AggobotnUOOdS sone 986 | Luzula ....................20. Harpula........ eaoerete cerreLere 286, 288 | Lyria................. 286, 287, MNS ao, sna 0 ,w,aicin' .22seeeee ATION. we meee ceccce see Seteersewes VEG CAONILE: « ss oo ciao aavs oreo HIGIOPATAMCCUS.. «. oo:e0<.0' = eerie Obelians sees cares wee ie wise eras 210; 212 | Poebrotheriumi.. --1..100 sere (OBIE Sa SsonnooongodocoUeG. 158 | Boly cotylus.4.\.42%.5 eee 266, OUNPNE goenoeocanouaanboosCOad TOR | “Poly pryita a--etai.evoterele as ereleranee Om@nmGEy on cododocscousamonas 184 | Polyodon'. «2.30... ssh cen ome Ono Aan onseodoseacsde domcusc JAS: Poly thonaxaeicteetsicle oitiel ckereete (OMS. GodsdadaongpododosHodess 166: | Pomoxysi:¢ tc ccleitee teeter Oniki Gag ancoseapeunorode counor oll) Porcellanay ste cecesetse eee COMUNE SebooceobeConaocas 19s UGLs PPontulacapncr et letslectceie setae OMG soovnestueoguaveccooode 112) Procamelusisc.s = sam otoconia OSiCOOTOSSUTI er eriieiceree cle aioke ele 66 || ProCy Oise va tric s.natae tes cornet OStrede nes ats tiersiats cyeraisic.ctaketoutane ts 520") Prorg7 PHVUSss\-\sralearle ee ee 87, OMMOGHE NS oc6 bs SSOD SB RDO GU QdOnOSS $48 | Prosopis: so..0 cc0ew vole eee Say BUGLE ciated a letetaiel sto lalstelaieiele lors ere 303) Protgeardiay 0. )n.\tecikie etree Protolabis’s -acteet< ee eee a Clun olitehmrertevers(eteretereiereioreietevers 42° Protopterlis .23 +2 3.522655 ooo BrGhiyGarduameres ciieciclclesfeveloiee 309) | "Psocus i. isc bowser ALCP UZ OMS ato: oie citaleretb tenets 11S) | Pteromvaltas: cs sie css circ oc aireteetees IPE eMAKEN Go bGgoocos bb oDODNOCE Gp | Ptiloriss 22 /e. 1h. eee ere PAlPOSCIMEUS Ne o1n\os axnileie alee ee NE) Pty CHOSY GA sic ite. uialeteleies siete eet IehnibaOR\Waliskoaaoonsecacadncosuboc Gp: | daupnellus!<: hi. taenee eee eee leone. gue dabecoodarouc spac Se | UE UPD Sie, c t= sc leiats ctenelelaiete tet tenenene LEMON ceoecocoooodeocechuos E50!) PrrvOpsissit os ckie tic secretes IHOWALIS Cocca sorchccdaguooc Dl |MEAV TOKEN) nichole ctercte rare eterna PPATAMONITUL, (ata) atisl eee’ aiciafviel oamerers ORO AE VEULAN YS \c! octets stele siete eee PATASRSy <1: fcrecclataicisteroene nla erates 1538 ATOM CHOMOM ste tei-ye:ejetaucteletere DOG; 0) Ova crUlar.ye) teleters