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Bulletin 21 evn
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Fossil Mammalia of the”

Huertano Formation, Eocene,

of Colorado

by

Peter Robinson

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FOSSIL MAMMALIA OF THE HUERFANO
FORMATION, EOCENE, OF COLORADO

Bulletins published by the Peabody Museum of Natural History at Yale University
embody research carried out under the auspices of the Museum. ‘The issues are numbered
consecutively as independent monographs and appear at irregular intervals. Shorter papers
are published at frequent intervals in the Peabody Museum Postilla Series.

EpiroriAL Boarp: Elwyn L. Simons, Chairman
Willard Hartman
A. Lee McAlester
N. Philip Ashmole

Eprtror: Ellen T. Drake

MUS. COMP, ZOOL.
LIBRARY

JUN 2 4 1966

HAr VAI
UNIVERSITy

Communications concerning purchase or exchange of publications should be addressed

to the Editor, Peabody Museum of Natural History, Yale University, New Haven, Con-
necticut 06520, U.S.A.

Issued May 10, 1966

PEABODY MUSEUM OF NATURAL HISTORY
YALE UNIVERSITY
BULLETIN 21

Fossil Mammalia of the Huerfano Formation,

Eocene, of Colorado

BY
PETER ROBINSON

University of Colorado Museum
Boulder, Colorado

NEW HAVEN, CONNECTICUT
1966

Printed in the United States of America

CONTENTS

List OF ILLUSTRATIONS vi
ABSTRACT 1
PART I: GEOLOGY 2
INTRODUCTION 2
ACKNOWLEDGMENTS 3
GEOGRAPHY 4
STRATIGRAPHY 5
Cenozoic System 5
Paleocene Series 5

Eocene Series 6

?Pliocene Series 16
STRUCTURAL GEOLOGY 17
GEOMORPHOLOGY 19
GEoLocic HisTory 20
PART II: PALEONTOLOGY 22
FosstL LocALitTIEs 22
‘TAXONOMY |
MARSUPIALIA 29
INSECTIVORA 29
PRIMATES 31
TILLODONTIA 43
‘TAENIODONTA 44
EDENTATA 44
RODENTIA 45
CARNIVORA 46
CoONDYLARTHRA 53
DINOCERATA 60
PANTODONTA 60
PERISSODACTYLA 61
ARTIODACTYLA 68
APPENDIX: STRATIGRAPHIC SECTIONS 72
BIBLIOGRAPHY 79
INDEX 84
Prates I-X 86-95

ILLUSTRATIONS

‘TEXT FIGURES

r
2.
3. Chart showing the inferred stratigraphic and age relationships of the Huerfano

Index map of Colorado showing the location of Huerfano Park and the appro-
priate area (stippled) occupied by the Huerfano and Farisita formations, p. 4.
Tectonic map of the Raton Basin, p. 5.

and Farisita formations in Huerfano Park and the Spanish Peaks regions, Huer-
fano County, Colorado, p. 8.

. Sketch map of the Gardner area, Huerfano County, Colorado, showing the

location of the major fossil localities and geographic features, p. 17.

. Scatter diagram comparison of widths of trigonids and talonids of lower molars

of Absarokius from the Lysite, Lost Cabin and Huerfano beds, p. 33.

. Scatter diagram comparison of trigonid width and length of M; of Absarokius,

pee:

. Scatter diagram comparison of widths of trigonid and talonid of M, of

Cynodontomys from several localities in the Huerfano formation, p. 38.

. Scatter diagram comparison of widths of trigonid and talonid of M, of Cyno-

dontomys from the Lysite, Lost Cabin and Huerfano beds, p. 41.

9. Scatter diagram comparison of widths of trigonid and talonid of My, of Micro-
syops from the Huerfano and Bridger formations, p. 42.
PLATES
ee bes ol. Talpavus sp. cf. T. nitidus

Fig. 2. Palaeictops bicuspis
Fig. 3. Scenopagus priscus
Fig, 4,5. rMetacheiromys sp.
Fig. 6. Bathyopsis fissidens
Big 7. Peratherium sp.
Fig. 8. Coryphodon sp.
Fig. 9. Palaeosyops fontinalis

HW. “Fie. 1. A bsarohius noctivagus nocerai, new subspecies
Figs 2. Loveina zephyri
Fro. 3. Nyctitherium sp. cf. N. velox

ne: Fie. We FHuerfanius rutherfurdi, new genus, new species
Kio, 2. Phenacolemur jepseni simpsoni, new subspecies
Ris. 3. Shoshonius cooperi
Fig. 4,5. Scenopagus edenensis

PV 5 Bigs. Cynodontomys scottianus
Big.» 2: Cynodontomys knightensis
Fig. 3: Hyracotherium craspedotum
Fig. 4. Hyracotherium vasacciense ?venticolum
Fig. 5,7. Hyracotherium vasacciense vasacciense
Bis. 6. Microsyops lundeliusi

Vy Kien: Stylinodon sp.
Bigs 2: Vulpavus asius
Fig. 3. Viverravus gracilis
Fig. 4. Uintacyon sp. cf. U. asodes
Bis (9: ?Muacis sp.

vi

VA.

Vil.

VIIl.

IX.

Fig,

Se are

ILLUSTRATIONS Vii

Oxyaena sp. cf. O. Lupina
Esthonyx acutidens

?Oddectes sp.

Muacis parvivorus

Oddectes herpestoides

Viverravus sicarius

Sinopa sp. cf. S. strenua
Patriofelis ulta

Mesonyx obtusidens

Sinopa sp. cf. S. strenua
Didymictis ?protenus

Didymictis vancleveae, new species
Didymictis altidens

Didymictis vancleveae, new species
Palaeosyops fontinalis

Trogosus grangert

Notharctus nunienus

Palaeosyops fontinalis

Eotitanops borealis
Lambdotherium popoagicum
Helaletes nanus

Hyrachyus modestus

Eotitanops minimus

Helaletes sp. cf. H. nanus
Antiacodon pygmaeus huerfanensis, new subspecies
Diacodexis sp. cf. D. secans
Diacodexts sp. cf. D. chacensis
Hyopsodus wortmant

Phenacodus vortmani

Hyopsodus walcottianus
Bunophorus macropternus
Hyopsodus paulus

Bunophorus sp. cf. B. macropternus

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YALE UNIVERSITY PEABODY MUSEUM OF NATURAL HISTORY BULLETIN
No. 21, 95 p., 10 PLs., 9 TEXT-FIGS., 1966

FOSSIL MAMMALIA OF THE HUERFANO FORMATION, EOCENE,
OF COLORADO

By PETER ROBINSON

ABSTRACT

Huerfano Basin is a Laramide structure developed between the Sangre de Cristo Mountains
(also Laramide) and the Wet Mountains (a rejuvenated Paleozoic structure).

Huerfano beds accumulated during a period of relative inactivity in the Laramide Orogeny;
fine grained sedimentary rocks derived from mountain areas outside present Huerfano park make
up most of the formation. Huerfano sedimentation was brought to a close by a pulse of the
Laramide Orogeny within Huerfano Park.

Huerfano beds, and their lateral equivalent, the Farisita formation, contain two fossil mammal
faunas; one, the Garcia Canyon local fauna, is of Lostcabinian (late early Eocene) age; the younger
fauna, the Gardner Butte local fauna, represents a substage older than Blacksforkian (early middle
Eocene) and younger than Lostcabinian. The Gardnerbuttean is proposed as a substage of the
Wasatchian (early Eocene) stage; characterized by the presence of the following genera: Hyra-
cotherium, Coryphodon, Absarokius, Cynodontomys, Didymictis, Eotitanops, Diacodexis and
Bunophorus of early Eocene affinity, and Metacheiromys, Mesonyx, Patriofelis, Oddectes, Palaeo-
syops, Helaletes and Antiacodon of middle Eocene affinity.

FOSSIL MAMMALIA OF THE HUERFANO FORMATION,
EOCENE, OF COLORADO*

PETER ROBINSON

leo eae Ba
GEOLOGY

INTRODUCTION

The study of the Huerfano mammals presented here is the result of a project
initiated in 1952 by Dr. George Gaylord Simpson, then Curator of Fossil Mammals
and Birds at the American Museum of Natural History and now Alexander
Agassiz Professor at Harvard. I started working on the project as one of his field
assistants; later Dr. Simpson allowed me to study the fossil mammals.

The recent interest of the American Museum of Natural History in Huerfano
Park dates from 1952, and the major concern of the museum was collection of fossil
mammals from the Huerfano formation. In the same year field parties of the
United States Geological Survey (R. B. Johnson and co-workers) started to map
Huerfano Park as part of a larger mapping program in the Raton Basin. The
U.S.G.S. interests were mainly in coal resources and secondly in oil and gas
potentialities. ‘The next year, several parties from the University of Michigan
(L. I. Briggs, E. N. Goddard and students) began a long range mapping project
of the entire Huerfano Park area. The University of Michigan and the American
Museum of Natural History agreed to work on different aspects of the area—the
museum collecting fossil mammals from the Huerfano formation and mapping
the Eocene rocks and the university concentrating on other geological problems.

The occurrence of “Bridger” fossils in Huerfano beds was first noted by Hills
(1889). Since the first work of Osborn (1897), faunal levels have been recognized
in the Huerfano formation, a lower “Wind River” and upper “Bridger.” In 1916
and 1918 Walter Granger supervised further collection of fossil vertebrates from
Huerfano Park and the results of his work were discussed briefly (Granger, 1918).
Small segments of the Huerfano formation’s fauna have been described by
specialists working on particular groups: Osborn (1919, 1929); Gilmore (1927,
1938); Denison (1938); Wheeler (1960); no one has discussed the entire fauna.
Granger recognized the pre-Bridger post-Lost Cabin age of the upper faunal zone
of the Huerfano formation (Letter to R. C. Hills dated 14 April 1919) but was
prevented from further discussion of the material by the pressure of other work,
particularly the Mongolian expeditions. The general consensus has been to equate
the upper Huerfano faunal zone with the relatively barren Bridger ‘A’ because
the Bridger ‘A’ occupies the appropriate stratigraphic position. Gazin informs me
(oral communication) that there may not be a Bridger ‘A’, the particular beds
being part of the Green River formation. I see no reason to change the relative
position of the upper faunal zone of the Huerfano formation, but there is a
semantic question about its temporal position: is it early or middle Eocene? I

* Published with the aid of a National Science Foundation Publication Grant No. GN-356.

2

GEOLOGY 3

prefer to consider it the former and discuss my reasons for doing so on page 15;
I recognize the essentially arbitrary nature of any placement. However, as Granger
noted (letter cited) the upper Huerfano fauna contains elements nicely bridging
the gap between the Lost Cabin and Black’s Fork (lower Bridger) faunas. I the
so-called Bridger ‘A’ fauna turns out to be equivalent to the upper Huerfano
fauna, the Bridger ‘A’ may have to be removed from the early middle Eocene
substage (Woodard, others, 1941).

Certain problems of the Huerfano fauna are not discussed here; these are:
cranial anatomy of the Microsyopidae based on skulls of Microsyops and
Cynodontomys collected from locality II and discussion of the quarry sample of
Hyracotherium from locality VU. M. C. McKenna is describing the Micro-
syopidae and D. B. Kitts will describe the Hyracotherium sample. A. E. Wood
described the paramyid rodents in his revision of the Paramyidae and Max Hecht
will describe the lizards and snakes. The Huerfano fauna includes at least 58
species of mammals belonging to 42 genera. In addition, perhaps 15-20 species of
birds, reptiles, fish and molluscs have been collected, which brings the total faunal
sample to approximately 75 species.

In many ways Huerfano Park is unique in having a mammal-bearing forma-
tion so intimately associated with orogeny. Certain areas of western Wyoming are
similarly associated but not as fossiliferous. Because of the association of Laramide
deformation and the Huerfano formation, a longer discussion of local and re-
gional geology is included than usually is in a faunal study.

ACKNOWLEDGMENTS

Many people have helped me by criticism, by offering data or both. I am
indebted to Drs. S. A. Northrup, V. C. Kelley, J. S. Findley and S. A. Wengerd of
the University of New Mexico for criticism of my initial efforts. Drs. L. I. Briggs,
E. N. Goddard, David McCulloch, Earle Kauffman and Herbert Tischler of the
University of Michigan discussed many of the Huerfano Park problems with me
and gave me much data. Drs. Max Hecht and A. E. Wood identified reptiles and
rodents, respectively, from the Huerfano formation. Mr. G. T. Benson of Yale
University discussed problems of southern Colorado geology with me and showed
me the geology of the Stonewall area. Dr. K. M. Waage of Yale has criticized the
manuscript and has discussed problems of Mesozoic stratigraphy.

The staff of the American Museum of Natural History have been very helpful
to me, particularly Drs. E. H. Colbert, Bobb Schaeffer, and M. C. McKenna, Mrs.
Rachel H. Nichols and Messrs. Louis Monaco, George O. Whitaker and Joseph
A. Nocera. Peter Rona, Ruben Aguirre and Peter Hilgeford helped collect fossils
in Huerfano Park.

I have discussed problems of Huerfano Park geology or paleontology with Mr.
Ross B. Johnson of the United States Geological Survey, Dr. C. Lewis Gazin of the
U. S. National Museum, Dr. David Kitts of the University of Oklahoma and Mr.
Giles McIntrye of Columbia University.

I am extremely indebted to Drs. Joseph T. Gregory formerly of Yale, now at
University of California, Berkeley, and George Gaylord Simpson of Harvard for
all the help they have given me. The Society of Sigma Xi, the American Museum
of Natural History and the John T. Doneghy Jr. Research Fund for Vertebrate
Paleontology at Yale University have aided the study with grants for field work.

Drs. Mary R. Dawson, Glenn L. Jepsen, John H. Ostrom and Elwyn L. Simons
have read the manuscript and offered welcome criticism.

4 FOSSIL MAMMALIA OF THE HUERFANO FORMATION

GEOGRAPHY

Huerfano Park is a northwest-trending intermountain valley located between
the Wet Mountains on the east and the Sangre de Cristo mountains on the west
in south-central Colorado. The north boundary of Huerfano Park is the drainage
divide between Huerfano River tributaries and streams flowing to the north
through the Wet Mountain Valley. The south boundary is a pediment extending
from the Spanish Peaks northward to the park. The Huerfano River and its
tributaries drain Huerfano Park; the river runs southeastward around the south-
east end of the Wet Mountains and then northeastward to the Arkansas River.
Muddy Creek, the main tributary of the Huerfano River, joins it at the town of
Gardner.

Several large hills are found in Huerfano Park. The northernmost is Black
Mountain or Promontory Bluff. Little Sheep, Sheep, and Rough Mountains and
Mount Mestas are a series of synaxial intrusives of Laramide age standing in the
fold belt of the east flank of the Sangre de Cristo Mountains. Dike Mountain, The
Black Hills and the Spanish Peaks represent three crossaxial intrusives that lie
to the south of Huerfano Park; the Spanish Peaks are noted for the dike networks
associated with them (Knopf, 1936, 1956).

Settlements in the area are: Gardner, a town of some 200 inhabitants located
at the confluence of Muddy Creek and the Huerfano River; Farisita, a hamlet
located at the junction of the Huerfano River and Turkey Creek, five miles
southeast of Gardner; and Badito, a cluster of houses at the south end of the Wet
Mountains where the Dakota sandstone plunges beneath the surface.

108° 1062 104°

40°

DENVER

Figure 1. An index map of Colorado showing the location of Huerfano Park and the approxi-
mate area (stippled) occupied by the Huerfano and Farisita formations.

GEOLOGY F

Two hamlets are found in the Huerfano Valley above Gardner: Malachite is
approximately six miles upstream and Redwing is two miles farther. Eight miles
up Muddy Creek from Gardner is the headquarters of the JM Ranch; Bradford,
a ghost town, is approximately five miles farther up the Creek.

CENOZOIC SYSTEM
PALEOCENE SERIES
PoIsoN CANYON FORMATION, Hits, 1888: EMEND. 1891.

The Poison Canyon formation crops out in a band around the western flank
of the Wet Mountains and in front of the foothills belt of the Sangre de Cristo
Mountains and southward in the marginal area of the Raton Basin. It rests un-
conformably (Black Hills area) or disconformably (Archuleta Draw, Poison
Canyon) upon the Pierre shale. The Poison Canyon formation underlies the
Huerfano formation conformably at Black Mountain and disconformably in
Poison Canyon and Archuleta Draw.

The Poison Canyon formation is composed of approximately 1300 feet of
yellow to brown, massive, cross-laminated sandstone beds and drab brown or
grey silty, often fissile, mudstones. ‘The sandstone beds are resistant and often

up\=
4
< WET MOUNTAINS ANTICLINE
SANGRE DE
CRISTO

mHRUST BELT

Figure 2. Tectonic map of the Raton Basin modified from John W. Gableman (1956).

6 FOSSIL MAMMALIA OF THE HUERFANO FORMATION

form cliffs along valley sides; the mudstone beds are usually covered. Impressions
of fossil leaves are common in the shale beds; Briggs and Goddard (1956) report
a tropical flora similar to that of the Denver formation from beds 80 feet below
the top of the formation at the type locality.

The unconformity below the Poison Canyon formation in Huerfano Park in-
dicates a depositional break and erosion prior to deposition of the formation.
Farther south, in the Raton Mesa region, Johnson and Wood (1956a, b) have
shown that the basal beds of the Poison Canyon formation intertongue with the
upper beds of the Raton formation in that area. The Trinidad sandstone and
the Vermejo formation of late Cretaceous age are present between the Pierre
shale and the Raton formation. Because the Poison Canyon formation rests
unconformably upon the eroded Trinidad sandstone and Vermejo formation in
the Black Hills area (Johnson, Wood and Harbour, 1958), these latter two forma-
tions probably extended farther north, perhaps into Huerfano Park. The Raton
formation may not have extended far north of the Spanish Peaks area and there-
fore not into Huerfano Park. The erosion that preceded the deposition of the
Poison Canyon formation is hard to estimate quantitatively. Generally the
Cretaceous and younger formations are thinner in Huerfano Park due to the
topography of the depositional site as well as to post-depositional erosion. As
much as 500 feet of pre-Poison Canyon erosion may have occurred, but the absence
of lower Laramide sediments may also be due to non-deposition. If the Trinidad
sandstone and the Vermejo formation were eroded from Huerfano Park, the
necessary uplift produced little structural discordance.

EOCENE SERIES
HUERFANO FORMATION, HILLs, 1888; EMEND. 1891

The Huerfano formation crops out in the center of Huerfano Park and south-
wards to the southern flank of the Spanish Peaks. As used here, the term Huerfano
formation includes the Cuchara formation of current United States Geological
Survey usage. In Huerfano Park the Huerfano formation is composed of ap-
proximately 2800 feet of pink, red, red-brown and brown silty mudstones and
lenses of yellow, tan or green sandstones. The mudstones often contain concretions,
which may be encrustations on fossil bone. Farther south, in the Spanish Peaks
area, approximately 5000 feet of Huerfano formation is present. The percentage
of sandstone increases southward; sandstone forms approximately 10 per cent of
the Huerfano formation in Huerfano Park and approximately 50 per cent (John-
son, Wood and Harbour, 1958) of the formation in the Spanish Peaks area.

The lower part of the Huerfano formation in the Spanish Peaks area is poorly
exposed; the upper part is mainly contact metamorphic rocks forming the major
portion of the Spanish Peaks.

Fossil vertebrates are generally found in the more extensive exposures of the
Huerfano formation. Since many of the fossils are small, collecting specimens may
require a trained eye. Fossils are more common in mudstones than in sandstones
and are more common in Huerfano Park than in the Spanish Peaks area. In
Huerfano Park two lower Eocene provincial substages, Lostcabinian and Gardner-
buttean, are present. Lower Eocene fossils are present (Robinson, 1960) less than
1000 feet above the base of the formation in the Spanish Peaks area.

FARISITA FORMATION, JOHNSON AND Woon, 1956

Johnson and Wood (1956) proposed the term Farisita formation for yellow,
tan, buff, white and grey poorly indurated sandstones and silty mudstones. As

GEOLOGY a

originally described, the Farisita formation was supposed to rest unconformably
upon the Huerfano formation. University of Michigan investigators have dis-
covered that the Farisita intertongues with the Huerfano formation (Briggs and
Goddard, 1956). Faunal evidence indicates that both of the Huerfano faunal
zones are present in the Farisita formation; Farisita beds may intertongue with
Huerfano beds throughout the entire thickness of the Huerfano formation.
Therefore, it seems that the published estimates of 1,000? feet (Briggs and God-
dard) and 0-1200 feet (Johnson and Wood) may need revising.

Outcrops of the Farisita formation are best exposed between William’s Creek
and Turkey Creek, north of Gardner Butte. Similar lithology occurs as inter-beds
in the Huerfano formation in the area west of William’s Creek; Farisita beds crop
out above Huerfano beds in Black Mountain.

erner and Briggs (1958) state that on the basis of lithologic comparisons the
source for the Farisita formation was probably the Front Ranges, especially the
Wet Mountains. The streams depositing the Farisita sediments are thought to
have come from the northwest, in contrast to the streams flowing from the south
or southwest that deposited the Huerfano formation. It is difficult to believe that
sediments derived from the Wet Mountains were deposited by streams flowing
from the northwest, as the Farisita formation lies on the southwest side of the
range. It seems more likely that if the Wet Mountains were the source of Farisita
sediments, then the sediments came from the northern part of the range and also,
perhaps, from the Front Range.

The Farisita formation is easy to distinguish from the Huerfano formation by
its generally light yellow or tan color, by the lack of induration of the sandstones
and by the generally greater percentage of sand in the mudstones. Moreover,
fossil wood is common in the Farisita formation and rare in Huerfano beds while
fossil vertebrates are scarce in Farisita beds and rather common in the Huerfano
facies.

Perhaps the evidence that the Farisita and Huerfano formations interfinger
through most of their thickness and that they are equivalent in age (except where
the Farisita formation overlies Huerfano formation at Black Mountain) should
be used as criterion for considering them one unit. The differences between the
Huerfano and Farisita are striking and make the two local units mappable. The
dissimilarities between the Huerfano and the Cuchara formations are not striking,
except at extreme ends of the outcrop belt. ‘The change from sandstone-poor
Huerfano beds to sandstone-rich Cuchara beds is gradual; the change from pink,
red and brown Huerfano mudstones to yellow and tan Farisita sandstones and
mudstones is abrupt.

Fossil localities in Farisita beds are listed with those from the Huerfano beds.
Both faunal levels present in Huerfano facies are present in Farisita beds; i.e. late
early Eocene Lostcabinian and Gardnerbuttean provincial substages.

FAciES CHANGES

Geologists studying the rocks of the Raton Basin have given formational names
to most of the facies of lower Cenozoic rocks displayed in the area. Recent work
by the United States Geological Survey has demonstrated facies relationships
between the Raton, Poison Canyon and Huerfano (= Cuchara) formations south
of the Spanish Peaks (Johnson and Wood, 1956).

In Huerfano Park, the Huerfano formation intertongues with the Farisita
formation (Briggs and Goddard, 1956) throughout most, if not all, of the thick-
ness of the Huerfano formation. At Black Mountain Farisita beds overlie the

8 FOSSIL MAMMALIA OF THE HUERFANO FORMATION

Huerfano beds unconformably; whether this unconformity can be traced within
the Farisita facies is not known. Fossils collected from the Huerfano facies in
Farisita-Huerfano intertonguing zones (Briggs and Goddard, 1956) and Farisita
fossils reported on below indicate general agreement in age of the two facies.
Unfortunately, no fossils have been collected from Farisita beds above the un-
conformity at Black Mountain.

Generally the contact between the Poison Canyon formation and the Huerfano
formation is disconformable, but it is gradational at Black Mountain. The basal
Huerfano beds in the northern part of Huerfano Park vary laterally from massive,
cross-laminated white and pink arkosic sandstones and rufous shales into red,
yellow, gray and bluish mudstones. The massive sandstones have been called
Cuchara formation by Hills (1889-1891), Burbank and Goddard (1937), Johnson,
Wood and Harbour (1958) and Briggs and Goddard (1956). ‘These bright pink
and white sandstones are unlike the sandstones found in the type Cuchara, which
are yellow to brick red in color.

Detailed study shows that lateral changes in Huerfano beds are locally
prominent. Near the head of Yellowstone Creek in Sec. 7 and 8, T28S, R69W, two

PROVINCIAL | HUERFANO PARK SPANISH PEAKS
SUBSTAGE

BRIDGER 'B'

| GARDNER
BUTTE Zz Z
LOST CABIN HUERFANO FM.

Eras oy
LYSITE Y
GREYBULL
? 2

POISON CANYON FM.

iJ
=
Lid
oO
Oo
Lj

?

PALEOCENE

Figure 3. A chart showing the inferred stratigraphic and age relationships of the Huerfano and
Farisita formations in Huerfano Park and the Spanish Peaks regions, Huerfano County,
Colorado.

GEOLOGY 9

striking variations are present. One of these is a 50-foot unit of massive, yellow,
cross-laminated, conglomeratic sandstone that extends eastward about | mile and
then either grades into mudstones or is covered. Individual beds of sandstone
may be 6-8 feet thick. On the opposite (south) side of Yellowstone Creek is a red,
sandy mudstone containing much detrital mica.

Similarly, local changes in lithology are striking in the Poison Canyon and
Black Mountain area. In addition to the facies changes mentioned in connection
with the contact of the Poison Canyon formation and Huerfano formations, there
are beds of conglomerate containing large boulders. The one unifying feature of
the many local changes in Huerfano lithology is their presence at the western
limit of the formation, where structural complications are common, and where
local irregularities in the Eocene drainage would have been most pronounced.

Berner and Briggs (1958) state that the source of Huerfano sediment was
south or southwest of the present exposures in Huerfano Park. This interpretation
is compatible with the increase in percent of sandstone southward, especially
in the Spanish Peaks area. The thickness of Laramide sedimentary rocks is greatest
in the Spanish Peaks area (Johnson and Wood, 1956, isopach maps) indicating
that subsidence was greatest there and perhaps indicating proximity to source
of sediments (Culebra Range of Sangre de Cristo Mountains).

TERMINOLOGY OF THE LOWER CENOzoIc Rock UNITs IN
HUERFANO PARK

Which formation name is valid for these lower Eocene rocks, Huerfano or
Cuchara? Hills’ first paper (1888) used two terms for the lower Cenozoic rocks of
Huerfano Park: Huerfano beds (p. 148) and Poison Canyon series (p. 152) or
Poison Canyon conglomerates (p. 151). These terms applied to all three units
described in his generalized section on p. 149. His section is (descending order):

“Red and yellow sandy clays and marls, sometimes shaly,
alternating with yellowish, white, gray and greenish

sands ... 2000 feet. Light-red, white, brownish or
variegated soft sandstones alternating with red and

yellow sandy clays and marls .. . 1500 feet. Yellowish,

or light-colored, soft sandstones and conglomerates with
occasional beds of yellow clay or marl. . . 3500 to 4500 feet.”

Hills noted the similarity of the two upper units, noting the dominance of
sandstones in the middle unit. The thickness of Poison Canyon beds reported is
probably due to Hills’ failure to notice the anticline in Poison Canyon and there-
fore the repetition in strata, or may be due to his not noticing the change in dip,
which decreases westward. Hills later (1889) changed his mind regarding the thick-
nesses of the individual units, but the total was similar. Hills revised section is
(1889, p. 218):

““Marls, clays, soft shales and sands, of red, gray, yellow,

green and purple colors, red predominating........ 3300 feet
Pink and white massive sandstones................ 300 feet
Soft sandstones and fine conglomerates of a yellowish

tint, with occasional bands of yellow clay or marl... .3500 feet.”

He noted that the last figure might be in excess.
Hills stated that the pink and white sandstones of his “middle division”

10 FOSSIL MAMMALIA OF THE HUERFANO FORMATION

formed most of the exposures in the Cuchara Valley (1889, p. 219). No specific
terms were applied to these beds. In 1891, Hills decided to apply names to his
subdivisions of the lower Cenozoic beds which had been called ‘‘Huerfano beds,
Huerfano series, and Poison Canyon series” all three terms being synonymous
and purposely general (1891, p. 7). His terminology was (1891, p. 9):

Huerfano beds
“Huerfano series Cuchara beds
Poison Canyon beds”

Hills’ larger unit would be a group in present usage. Hills stated that the type
localities of the units are as follows: Huerfano beds—along Muddy Creek-
Huerfano River divide from Mouth of Poison Canyon into the valley of Muddy
Creek (1891, p. 7); Guchara beds—Cuchara River Valley especially beds north and
south of La Veta; Poison Canyon beds—Poison Canyon, an arroyo entering Muddy
Creek from the southwest. However, Hills’ description of the Cuchara beds was
taken from the exposures near the mouth of Poison Canyon, 20-25 miles north of
the type locality. At Poison Canyon, beds called Cuchara form massive pink and
white arkosic sandstones of limited lateral continuity. In the La Veta area,
sandstone beds of this pastel colored lithology are absent; instead dark massive,
red, micaceous sandstones are present.

The term “Huerfano” beds or formation is well entrenched in the literature
(works of Hills, Osborn, Burbank and Goddard) while the term Cuchara, almost
as old, was not in common usage until more recently (Burbank and Goddard,
Johnson and his co-workers). The type locality of the Huerfano beds is good,
having approximately 2800 feet of rocks exposed. At the type locality of the
Cuchara formation are 5,000 feet of poorly exposed or contact metamorphosed
rock (thickness from Johnson, 1958), assuming that the Spanish Peaks can be
included in Hills’ “exposures . . . south of La Veta.”

Few exposures of Eocene rocks are present between Yellowstone Creek and
La Veta. The existing outcrops are in valley walls; the valley bottoms and the
drainage divides are covered by alluvium. Robinson (1960) reported the presence
of one fossil of early Eocene age in the “Cuchara” formation and noted that two
others had been collected from the La Veta area. Locality VIIJa in Huerfano
Park is in beds included in Cuchara formation by Johnson, Wood and Harbour
(1958). Lambdotherium at this locality indicates a Lostcabinian age. The 4,000
feet of rock above the known fossil from the La Veta area indicates that the
Huerfano formation in that area may include beds younger than lower Eocene.
Therefore, Huerfano beds in Huerfano Park and in the La Veta area are of
general time equivalence.

The two areas have lithologic continuity as well. Huerfano beds overlie Poison
Canyon beds in Huerfano Park, in the Spanish Peaks area and between (Johnson,
Wood and Harbour, 1958). Thick sections, containing the upper beds of the
Huerfano formation, are preserved in Huerfano Park and in the Spanish Peaks;
only lower beds are found in the exposures from Gardner Butte southwards to La
Veta (that is, in beds usually called Cuchara). One might separate the Huerfano
and Cuchara formations on age criteria, considering all the beds of Lostcabinian
age (Garcia Canyon local fauna) as Cuchara formation and considering the beds
of Gardnerbuttean age as Huerfano formation. However, a formation, being a
rock unit, is, or should be, defined on lithologic grounds.

The recent geologic map of Raton Basin and Huerfano Park by Johnson,
Wood and Harbour (1958) shows the inferred contact between the Cuchara forma-

GEOLOGY 11

tion and Huerfano formations in the divide between Archuleta Draw and South
Oak Creek. The divide is capped by a pediment, therefore critical exposures are
confined to valley sides north and south of the divide.

Reasons for considering the two formations synonymous are:

1) The two typical lithologies occur only at extreme ends of the outcrop belt;

2) The two formations are general time equivalents;

3) The two formations occupy the same stratigraphic position (overlie the
Poison Canyon formation);

4) Exposures in valley walls between La Veta and Huerfano Park indicate
that one unit underlies the alluvium throughout most of the intervening distance.

Reasons for preferring the term Huerfano formation are:

1) The type section is well exposed, with exposed lower contact;

2) The lithology of the type section of the Cuchara formation is mostly
hidden under cover or altered by contact metamorphism;

3) The term “Huerfano” has more distribution in geologic literature and
priority (1888 vs. 1891).

Environment of Huerfano Park during the deposition of the Huerfano and
Farisita formations:

The Huerfano and Farisita formations are interdigitating units of water-
deposited sandstone and mudstone. The streams that deposited these bodies of
sediment came from highlands in the south and southwest (Huerfano facies) or in
the north (Farisita facies) (Berner and Briggs, 1958). Huerfano Park, during the
Eocene, must have been a flat plain extending from the Sangre de Cristo Moun-
tains eastward; perhaps the Wet Mountains formed its eastern limit. Most of the
sediment accumulating as the Huerfano facies came from the Culebra unit of
the Sangre de Cristo Mountains. At Yellowstone Creek, Poison Canyon and Black
Mountain, the Crestone-Blanca unit contributed sediment.

The Farisita facies is derived from a “Front Range,” possibly the Wet
Mountains, (Berner and Briggs, 1958). The Farisita streams were either more
competent or had less fine material to transport than Huerfano streams did, as
the Farisita facies generally has a greater percentage of course material. The
abundance of coarse material may also reflect a closer source.

Huerfano rocks are generally red, red-brown, brown or pink, possibly indicat-
ing a source area with an annual rainfall of some 40 inches and a warm climate in
well-drained areas (Dunbar and Rodgers, 1957, p. 210). In contrast to the
Huerfano rocks, Farisita rocks are tan, buff or yellow. The significance of the
color change caused by a change from ferric oxide to ferric hydroxide is not fully
known. In the Washakie and Bighorn basins similar color changes occur in Eocene
rocks (Van Houten, 1944, p. 188-191, 195-199). In both examples the yellow
facies (Green River and Tatman formations) are lake deposits whereas the red
facies (Knight and Willwood formations) are flood plain deposits. Perhaps the
color change (therefore mineral change) is due to conditions in the provenance,
but perhaps the change reflects depositional environment as well.

If we assume that the environments of the source areas of Huerfano and
Farisita sediments were the same, and were such that red soils were forming, then
the difference between present colors of the Farisita and Huerfano formations is
due to the effect of depositional or post-depositional environments upon the red
sediments. The preservation of the red color in the Huerfano sediments suggests
that the conditions of deposition of the sediments were similar to the conditions

be FOSSIL MAMMALIA OF THE HUERFANO FORMATION

of formation of them. The predominance of ferric hydroxide (“limonite”’) as a
coloring agent of the Farisita facies suggests that the area was less well drained
than the Huerfano area, since ferric oxide would probably be preserved in a well
drained area (it forms in well drained areas, Dunbar and Rodgers, 1957, p. 210).
Drainage in the Farisita formation area was poor enough to inhibit the destruction
of much of the organic material by soil bacteria, because plant fragments are
preserved in the Farisita formation.

If we assume that the differences now shown in the color of the Farisita and
Huerfano formations are due to differences in the climate in the respective source
areas, then depositional conditions must have been good for preserving the dif-
ferences.

As in most geologic problems, the answer is probably that both differences in
the provenance and in the depositional sites control the present color (therefore
iron mineral content) of the beds. Certainly the fact that Berner and Briggs (1958)
have been able to differentiate source areas for the Huerfano and Farisita beds by
studies of the cross-lamination indicates that a different mineralogy in the source
areas could affect the resulting sediments. I think that the Farisita formation
accumulated in a wetter environment than the Huerfano formation did, perhaps
in perennial or annual swamps.

The possible presence of swampy or periodically swampy land to the east of a
flood plain gives rise to speculation about the nature of the areas east of Huerfano
Park, areas in which no supporting evidence to hypotheses about them is likely
to be found. Perhaps the Farisita facies is the record of a near-sea deposit. This
may seem like an outrageous suggestion, but marine rocks formed the Cannonball
of Paleocene age, and the possibility of occurrence of marine beds in other interior
Cenozoic deposits should not be overlooked. If the early Eocene is the record of
a period of relative quiet in the Laramide orogeny, it might indicate a time
when a readvance of the sea could occur. As stated above, the crucial areas are
barren of Eocene rocks; whether this is due to non-deposition as well as erosion
is a question not likely to be answered.

Faunal evidence of environment is useful in that similar or the same species
lived in Huerfano Park and in Wyoming during Eocene time and presumably
their ecological requirements were similar. Lepidosteus, and crocodiles, indicate
warm climates and permanent rivers. The occurrence of presumably arboreal
primates such as Notharctus, Anaptomorphidae and Omomyidae indicates the
presence of forest areas. Large ungulates do not prove the presence of savannahs
but indicate that open country might have existed. The carnivores probably do
not indicate any special environment; however, Didymictis is a large dog-like
beast and may have been a forest dweller. Other large carnivores, such as Mesonyx,
Oxyaena and Patriofelis, were probably specialized for certain habits, such as
scavenging, but we cannot deduce their habitats.

Detailed study of the lizards and snakes may prove useful for determining
habitats.

Most of the faunal elements are found at Locality II indicating a definite
thanatocoenose. Fish, crocodiles, ungulates and arboreal primates did not occupy
the same habitat in life, but they could have been closely associated. The lack of
articulated material (only snakes occur in articulation there) at Locality II adds
to the evidence in favor of death association. Of all the mammals found at this
locality, Microsyops lundeliusi most probably lived nearby. This is indicated by
the abundance of this species and the relatively complete preservation of the
remains, which include a skull, several pairs of jaws, and jaws with coronoid and

GEOLOGY 13

TABLE 1

List of the genera found in upper and lower faunal zones of the Huerfano formation and
their distribution in faunal levels above and below the Huerfano faunas.

Wasatchian Bridgerian
Lost Huerfano Black’s
Genera Lysite Cabin Lower Upper Fork

Peratherium x i? x
Nyctitherium ? iy x x
Talpavus x x
Scenopagus ? x x
Palaeictops x x x x
Cynodontomys x x x x
Microsyops x x

A patemys ? ? x x
Phenacolemur x x

Loveina x? x x

Absarokius x x x
Shoshontus x x ?
Notharctus x x x x
Stylinodon x x x x
Esthonyx x x x

Trogosus x x x
Metacheiromys x x
Mesonyx xX me
Oxyaena x x x

Patriofelis x x
Sinopa x x x x x
Viverravus x x ore x x
Didymictis Ke x X x

Vulpavus x x x x
Miacis x x x
Uintacyon x x Xe x
Oédectes iy x x
Coryphodon x x x x
Bathyopsis x x mi
Hyopsodus x x x x x
Phenacodus x x bre

Hyracotherium x x x x
Lambdotherium x x

Eotitanops x x x
Palaeosyops x x
Helaletes x x
Heptodon x x x

Hyrachyus x x x x
Diacodexts x x x x
Bunophorus X xe x x
Antiacodon x x
Paramys x x x x x
Thisbemys x x *
Leptotomus x x x x x
Reithroparamys x x x x
Microparamys x ? x x

14 FOSSIL MAMMALIA OF THE HUERFANO FORMATION

TABLES?

Mammalian species of genera of mammals common to Lostcabinian (or older) and
Gardnerbuttean, or Gardnerbuttean and Blacksforkian (or younger) substages

Species Lostcabinian— Gardnerbuttean Blacksforkian+
Talpavus nitidus cf x
Nyctitherium velox cf x
Microsyops lundeliust x x
Notharctus nunienus x x
Trogosus grangert x
Sinopa strenua a cf
Viverravus gracilis x x x
Viverravus sicarius x x
Vulpavus asius x x
Miacis parvivorus * x
Uintacyon asodes x cf
Bathyopsis fissidens x cf
Hyopsodus wortmant x x
Hyopsodus walcottianus x
Hyopsodus paulus x x
Hyrachyus modestus cf x Ke

angular processes preserved. No other skeletal parts are currently referable to
Microsyops.

Costillo Pocket (Locality VIII) is the only location where much articulated ma-
terial occurs, and this is mainly Hyracotherium, an ubiquitous early Eocene genus.

Perhaps more information about the post-cranial skeletons of many of the
mammals found in Huerfano Park would allow inferences about their habitats
and therefore the habitats present in Huerfano Park.

The data on Eocene floras summarized by Dorf (1955) for other western forma-
tions can be applied to the Huerfano formation because the same animals occur
there and in Wyoming. Huerfano Park was probably a low moderately flat area
of tropical or subtropical climate.

FAUNAL LEVELS IN THE HUERFANO AND FARISITA FORMATIONS

Lostcabinian faunal level—characterized by the presence of Lambdotherium
popoagicum, Eotitanops borealis, Loveina zephyri, Hyopsodus walcottianus,
Cynodontomys scottianus, Didymictis altidens and the following genera: Phena-
colemur, Esthonyx, Oxyaena, ?Heptodon, Phenacodus. This level is the Huerfano
A of Osborn and later authors and shows close correspondence with the Lost-
cabinian faunal level of the type area in the Wind River Basin (Van Houten,
1945; White, 1952; Osborn, 1897).

The Lostcabinian faunal assemblage in the Huerfano formation is here named
the Garcia Canyon local fauna. Garcia Canyon has produced more of the lower
faunal zone fossils than any other locality.

The Lost Cabin beds of the Wind River formation are divisible into two
faunal levels, the upper one characterized by the presence of Eotitanops borealis
and Lambdotherium popoagicum, and the lower one by the presence of L. popo-
agicum and the absence of Eotitanops (Osborn, 1929). The same two levels are
probably present in the Lostcabinian beds of the Huerfano formation. The
presence of Trogosus sp. cf. T. latidens in the Cathedral Bluffs Tongue (Gazin,
1952, 1962) may be evidence for a Gardnerbuttean or later age for part of the

GEOLOGY 15

Cathedral Bluffs tongue. Absarokius witteri (Morris, 1954) of the Cathedral Bluffs
tongue is clearly more specialized than A. noctivagus noctivagus from the Wind
River or A. n. nocerai from the upper Huerfano beds. The Didymictis from
Cathedral Bluffs is closer to D. altidens than to D. vancleveae. The Hexacodus of
the Cathedral Bluffs tongue is evidence for a Lostcabinian age of that locality,
because its presumed descendant Antiacodon is present in Gardnerbuttean beds.
Morris’ (1954, fig. 1) localities are separated by a total of 25 miles, and their relative
stratigraphic position is not indicated in his paper. He does not state from which
of these localities the Trogosus was collected but does state the locality of the
A bsarokius.

Gazin (1962, p. 5, 16) indicates that the Dad local fauna at the top of the
Hiawatha member of the Wasatch formation is early Lostcabinian. The Tipton
tongue of the Green River formation separates the Hiawatha and Cathedral
Bluffs members of the Wasatch formation.

Gardnerbuttean faunal level—characterized by the presence of the following
species of Lostcabinian or earlier affinities: Absarokius noctivagus (but a distinct
subspecies A. n. nocerat), Cynodontomys knightensis, Microsyops lundeliust,
Shoshonius cooperi, Notharctus nunienus, Bathyosis fissidens, Hyopsodus wortmant,
Paramys excavatus gardneri; and of Blacksforkian or later affinities: Viverravus
sicarius, Miacis parvivorus, Hyopsodus paulus, Helaletes sp. cf. H. nanus, Leptoto-
mus grandis. ‘The following genera are of Lostcabinian or older affinity: Cory-
phodon, Hyracotherium, Eotitanops, Didymictis, Bunophorus, Diacodexis. ‘The
following genera are of Blacksforkian or younger affinity: Patriofelis, Oddectes,
Mesonyx, Palaeosyops, Antiacodon. As far as known, Huerfanius, new genus, is
restricted to the Gardnerbuttean substage. The following species or subspecies are
restricted to the Gardnerbuttean substage: Absarokius noctivagus nocerat (new
subspecies), Trogosus grangeri, Didymictis vancleveae, Eotitanops minimus,
Paramys huerfanensis, Paramys excavatus gardneri, Leptotomus huerfanensis,
Antiacodon pygmaeus huerfanensis (new subspecies).

This faunal level is the “Huerfano B” of Osborn and later authors. The
presence of Hyracotherium, Coryphodon, Cynodontomys and Didymictis espe-
cially shows its relationship to the Wasatchian stage. The occurrence of Antt-
acodon, Scenopagus, Patriofelis, Mesonyx and Oddectes shows a close relationship
with the Blacksforkian faunal level. Osborn (1919, 1929) correlated the upper
faunal zone with the Bridger A of Matthew (1909). Palaeosyops fontinalis is the
only fossil known to have come from the area of Bridger ‘A’ exposures. Recent
work by C. L. Gazin (1962, p. 5) indicates that there may not be any Bridger ‘A’,
but instead that Bridger ‘B’ rests on the Green River formation.

I propose to refer the assemblage of fossils found in the upper faunal zone of
the Huerfano formation to the Gardner Butte local fauna and erect a new substage
within the early Eocene, the Gardnerbuttean. The name is taken from Gardner
Butte, a prominent local landmark located near the southeastern limit of beds
containing the Gardner Butte local fauna. The Gardnerbuttean substage is
located between the Lostcabinian substage of the Wasatchian stage and the
Blacksforkian substage of the Bridgerian (middle Eocene) stage.

H. E. Wood (1934) proposed the term Black’s Fork member of the Bridger
formation for the Bridger ‘A’ and ‘B’ of Matthew (1909). The faunal assemblage
that defines the Blacksforkian substage comes entirely from Bridger ‘B’ beds.
Fossils that have been reported to come from Bridger ‘A’ may come from the
Green River formation (Gazin, 1962, p. 5). The lithologic change indicates that
perhaps a time lapse is present. The presence of Palaeosyops fontinalis in the

16 FOSSIL MAMMALIA OF THE HUERFANO FORMATION

so-called Bridger ‘A’ is scant, but pertinent, evidence for a correlation of the
Bridger ‘A’ of authors (perhaps the Laney shale member of the Green River
formation, Gazin, 1962, p. 5) with the Gardner Butte local fauna of the Huerfano
formation. Morris (1954, p. 199) correlated the Cathedral Bluffs tongue of the
Wasatch formation in the Washakie Basin with the Bridger ‘A’ of the Bridger
Basin. Gazin (1962, p. 18; 1959, p. 135) states that Morris’ Cathedral Bluffs’ fauna
is of Lostcabinian age, but may be somewhat younger than the Lost Cabin beds
of the Wind River formation.

Discussion. Correlation of beds in different depositional basins is always a
matter of opinion based on available evidence. Certain criteria are more valuable
than others (Dunbar and Rodgers, 1957), but weighing the value of different units
of the same criteria (in this case fossil mammals) is hazardous. I believe that large
cursorial mammals are more valuable for correlative purposes than small arboreal
or fossorial mammals for two reasons: 1, the large cursors are more likely to spread
out and more likely to do it quickly; 2, larger animals are more likely to be pre-
served, or at least, are found more easily and are more likely to be collected.
Rapidity of evolution has always been a criterion for determination of good taxa
of correlative value. Certain of the small mammals might evolve more rapidly but
not enough is known about them now to be useful in correlation. I am following
criteria of standard usage in placing most reliance upon the Perissodactyla and to
a slightly lesser degree upon the Pantodonta, Dinocerata, Artiodactyla and Condy-
larthra.

From the evidence of distribution of various mammals in the Huerfano forma-
tion and from data available in recent literature it is obvious that certain species
were present in one area at earlier times than they were in other areas. Microsyops
lundeliusi is a good example: in the Wind River formation it is associated with
Esthonyx acutidens, Hyracotherium vasacciense venticolum, Hyopsodus wortmani,
Heptodon brownorum and Eotitanops sp. (White, 1952, p. 203); in the Gardner
Butte local fauna Microsyops lundeliusi is associated with Eotitanops minimus,
Palaeosyops fontinalis, Trogosus grangeri, Hyopsodus wortmani, Hyracotherium
v. vasacciense. In the Wind River formation Lambdotherium is present at the
same levels as M. lwndeliusi even though it is absent at the type locality of M.
lundeliust (White, 1952). Several species occur earlier in Huerfano beds than they
do in known deposits in Wyoming: Hyopsodus paulus, Antiacodon pygmaeus,
Scenopagus edenensis are a few. The presence of two titanotheres, E. minimus and
P. fontinalis in the Gardner Butte local fauna which could have evolved from the
same upper Lostcabinian species, E. borealis, is evidence for post-Lostcabinian age
of the Gardner Butte local fauna. P. fontinalis is the probable ancestor of the
Blacksforkian P. paludosus providing good evidence for pre-Blacksforkian age
of the Gardner Butte local fauna. The presence of Hyracotherium and Cory-
phodon and the absence of Orohippus is good support for a pre-Blacksforkian age
for the Gardner Butte local fauna. The occurrence of Trogosus in both the Cathe-
dral Bluffs member of the Knight formation and the Gardner Butte local fauna
in the Huerfano formation does not necessarily imply time equivalence. If the
Trogosus locality in the Cathedral Bluffs tongue is in beds containing Hexacodus
as well, it may indicate that Trogosus appeared earlier in the Washakie basin.
All the elements of a faunal assemblage do not appear simultaneously.

?PLIOCENE SERIES
Devit’s HOLE FORMATION, JOHNSON AND Woop, 1956

The Devil’s Hole formation consists of several hundred feet of water-laid tufts.

GEOLOGY 17

and a few andesite flows found on the flanks of the Wet and Sangre de Cristo
Mountains. Although this was one of the first units to be recognized in the area
(Hills, 1888), it was among the last named (Johnson and Wood, 1956a). The age
of the Devil’s hole formation is ?Pliocene. This age determination is based upon
horse and camel teeth found by R. C. Hills in the area between Muddy and
Turkey Creeks (1889, p. 220-221). Hills did not send the fossils to O. C. Marsh for

.
z ‘ Clx) '
= \A \ we q Te25)S3
S % : rs
@
NS MT ( \ As
~
=-.2 ad ia ine i
i ey Hea ES
i ae I S
Bi r= SS by ‘
: Se | Ss Sy Gardner Gardner Butte
= Beer rw T™*
sw oie =) 1265

v re
is eae ian
“ot 1X a)
Cre SF
‘ Tees:
- 0
Hep Villa
: |
R. 70 W. R. 69 W.

Figure 4. A sketch map of the Gardner area, Huerfano County, Colorado showing the location
of the major fossil localities and geographic features.

identification so the identification is probably his own (letter to O. C. Marsh,
dated 26 October, 1889). I do not know where these specimens are now stored.

STRUCTURAL GEOLOGY

General Statement. Three features determine the basic structure of Huerfano
Park: The Greenhorn (Wet Mountains) Anticline, the La Veta Syncline, and the
Sangre de Cristo Complex of folds and faults. Minor folds, faults and intrusions
are related to the major structure.

In east-west profile, the Colorado Rockies are characterized by an eastern
anticlinal mountain range (Front Range, Wet Mountains) occupying the site of
the Paleozoic Colorado Mountains (King, 1959, p. 104, 105, 118); a structural and
depositional basin west of the anticlinal mountains (North-Middle, South Parks;
Wet Mountain Valley-Huerfano Park) and a western mountain range or ranges
(Northern Sangre de Cristo, Sawatch, Mosquito, Park) which generally has major
thrust fault zones and can have a thick section of late Paleozoic rocks making
up much of the range (Sangre de Cristo, Mosquito). The syncline and the western

18 FOSSIL MAMMALIA OF THE HUERFANO FORMATION

range are predominantly Laramide structures, the eastern mountain range is a
rejuvenated late Paleozoic trend (King, 1959; Gableman, 1956, p. 37).

The Greenhorn Anticline. The Greenhorn Anticline (Johnson, Wood and
Harbour, 1958) is a southwestern bifurcation of the Wet Mountains Anticline
which plunges at Badito. The Apishapa Arch merges with the Greenhorn Anti-
cline east of Huerfano Park and the combined structure forms the axis of the Wet
Mountains. This latter structure, an en echelon extension of the Front Range,
occupies the site of a late Paleozoic positive area, part of the Colorado Mountains
(King, 1959, p. 118).

The Apishapa Arch extends southeastward and connects with the buried
Las Animas and Sierra Grande arches (Gableman, 1956, p. 36), all structures
forming part of the remnants of late Paleozoic highlands that connected the
Colorado Mountains with the Oklahoma ranges (King, 1959, p. 105).

Minor faults occur at the southern end of the Wet Mountains, and an extensive
thrust fault is present along the northeastern flank (Gableman, 1956); these struc-
tures do not greatly alter the anticlinal nature of the range.

The La Veta Syncline. The La Veta Syncline (Johnson, Wood and Harbour,
1958) is the structural axis of the Raton Basin, Huerfano Park and, probably, the
Wet Mountain Valley (Johnson and Wood, 1956; Gableman, 1956). The Green-
horn Anticline, Apishapa Arch and Sierra Grande Arch border the syncline on
the east and the Sangre de Cristo Complex borders it on the west. The axes of
the eastern arch system, the La Veta Syncline and the Sangre de Cristo Complex
diverge as the structures are traced southward. A small eastern prong of the
La Veta Syncline, the Del Carbon Syncline, fits into the fork formed by the
Greenhorn Anticline and the Apishapa Arch (Gableman, 1956). Similar inter-
digitations of fold axes are found in the Canon City Embayment and at the north-
ern end of the Front Range (Blackstone, 1953). Many of the minor structures
connected with the Front Range and related ranges trend northwestward (Gable-
man, 1956; Boos and Boos, 1957; Blackstone, 1953).

Wet Mountain Valley is apparently the uneroded northern continuation of the
Raton Basin and Huerfano Park. The axis of the Wet Mountain Valley Syncline
( = La Veta Syncline) extends into Pleasant Valley between the Mosquito and
Sawatch Ranges (Gableman, 1956). This syncline complex extends from near
Salida south to the latitude of Taos, forming one of the major, and more con-
tinuous, structural units of the Rocky Mountain region.

The Sangre de Cristo Complex. The Sangre de Cristo Complex is a series of
parallel folds, thrust faults and intrusions that extend from near Salida, Chaffee
County, Colorado to the vicinity of Las Vegas, New Mexico. This complex is here
divided into five units: the Salida unit from Salida south to Orient, Colorado; the
Crestone-Blanca unit from Orient south to the La Veta Pass area; the Culebra
unit from La Veta Pass south to the Colorado-New Mexico boundary; the Mount
Wheeler unit to near Taos and a southern unit composed of several small ranges
(Truchas, Pecos, Cimarron, Rincon) from Taos south to Las Vegas.

The Salida unit is characterized by thrust faults on the western margin (Litsey,
1958; Gableman, 1952) which relate it to the Mosquito Mountains-Coffman Ridge
uplift and not to the southern units of the complex. This unit is probably an en
echelon extension of the Mosquito Mountains structure.

The Crestone-Blanca unit has been described by Burbank and Goddard (1937)
and by Briggs and Goddard (1956). This unit is characterized by the flat lobate
Bruff Creek Thrust and related thrusts, by a belt of folds on the eastern flank of

GEOLOGY 19

the Sangre de Cristo Mountains and by a series of synaxial instrusives occupying
the center of the fold belt. These intrusives form the core of Little Sheep, Sheep,
and Rough Mountains and Mount Mestas. The thrust faults involve a thick
section of upper Paleozoic rocks (Burbank and Goddard, 1937). The Thrust plate
is imbricate. Marginal, high angle reverse faults related to the thrust fault cut
the Huerfano and Poison Canyon formations of early Eocene and Paleocene age.

The Culebra unit has relatively high angle thrusts with little displacement
(Asquith, 1958; G. T. Benson, oral communication). This unit differs from the
Crestone-Blanca unit in not having an eastern fold belt and in not having stocks;
all the synaxial intrusions are dikes, sills or sheets (Benson, oral communication;
Johnson, Wood and Harbour, 1958).

The Mount Wheeler unit consists of a Precambrian massif with an eastern
margin buried under Cenozoic lava flows; this unit may be a structural saddle
(G. T. Benson, oral communication). The southern unit consists of several ranges
with thrust faults on the eastern flanks.

The western margin of the Sangre de Cristo Complex is a series of normal
faults that mark the eastern boundary of the Rio Grande Trench. In most areas a
Precambrian core is exposed west of the crest of the Sangre de Cristo Mountains.
Recent mapping (University of Michigan parties; G. T. Benson) indicates that
much of the crest of the Crestone-Blanca and Culebra units is formed by upper
Paleozoic rocks.

Minor Structures. The Spanish Peaks and Dike Mountain are two intrusive
stocks with radiating dike networks that occupy locations on or near to the axis
of the La Veta Syncline. The Spanish Peaks are well known for their dike system
and the sequence of intrusions displayed there. Petrology of Dike Mountain has
not been reported on yet; it may be a single intrusion and dike network or a
compound system like the Spanish Peaks. Dikes from these stocks cut the marginal
structures of the Sangre de Cristo Mountains and therefore the instrusives are
younger than the folding.

The cores of the Little Black Hills and the Black Hills are formed by small
stocks located at the southern end of the Greenhorn Anticline (Johnson, Wood
and Harbour, 1958) and may be late Laramide in age.

GEOMORPHOLOGY

Huerfano Park is the product of late Cenozoic erosion. The park contains
remnants of several surfaces which produce an illusion of a flat intermountain
valley. In reality at least 2,000 feet of rock has been removed from the center of
the basin and perhaps more from the flanks.

Three major surfaces are present in Huerfano Park. The oldest is the present
surface of the Wet Mountain Valley which can be traced southward along the
flanks of the Sangre de Cristo and Wet Mountains and which caps Black Mountain
(L. I. Briggs, oral communication).

The second surface slopes to the south indicating that the streams that flowed
over it were south flowing, a reversal of conditions found in the old surface.

The third (young) surface is a constructional feature formed by the filling in
of valleys cut into the second surface. Recent erosion has cut gullies up to 30 feet
deep in parts of the young surface.

An understanding of the surfaces is necessary since most exposures of the
Huerfano formation are found in valley walls exposed between the middle and the
young surfaces, and mapping Cenozoic contacts is a case of finding them in
adjacent gully sides. Most of the Cenozoic rock beds are hidden by one or another

20 FOSSIL MAMMALIA OF THE HUERFANO FORMATION

of these surfaces and their related deposits.

Isolated hills such as Rough Mountain, Sheep and Little Sheep Mountains,
and the Black Hills produce local irregularities in the pattern of surfaces. Sub-
sidiary surfaces are also present indicating less important episodes in the erosional
history. The young surface often merges with the middle surface near the heads
of the modern arroyos; the middle surface intersects the old surface in the
northern part of Huerfano Park.

At Gardner the young surface is approximately 7200 feet above sea level and
the middle surface about 100 feet higher. The young surface rises to the northwest
and is 76001 feet at the JM Ranch (eight miles up Muddy Creek from Gardner).
The middle surface is about 50 feet higher than the young surface at the JM.
Traced southward the middle surface decreases in elevation to Badito and then
remains more or less level (in north-south profile) until the vicinity of La Veta,
where it rises again; the rise is due to the presence of the Spanish Peaks. Between
Badito and the Spanish Peaks the surface slopes eastward, reflecting the dominant
trend in drainage. Locally, outcrops of resistant rock, such as sandstone beds or
igneous dikes, produce minor fluctuations in the general trend.

GrEoLocic HisToryY

The Laramide orogeny produced the present structural pattern, probably in
several stages (Burbank and Goddard, 1937). The early Laramide geology of the
Wet Mountains indicates that the area was relatively quiet. It is likely that Lara-
mide structures in the Front Ranges are really rejuvenated late Paleozoic trends.

Sandstone lenses in the upper Pierre beds (Johnson and Wood, 1956a) in the
Raton Basin record the initial movements of the Sangre de Cristo Mountains. The
Trinidad sandstone is the deposit of a retreating strand (Johnson and Wood,
1956a), and the Vermejo, Raton and Poison Canyon formations record the
dominance of terrestrial conditions. Several unconformities and disconformities
in the Laramide sequence testify to periods of renewed erosion probably caused
by renewed uplift.

Coincident with the Laramide uplift of the Sangre de Cristo Mountains was
the Laramide depression of the Raton Basin. Isopach maps of the Trinidad and
Vermejo formations (Johnson and Wood, 1956a) show that the axis of greatest
sedimentation coincides with the axis of the La Veta Syncline. The thickest
section of Laramide rocks is preserved in the Spanish Peaks area where at least
8,000 feet of terrestrial rocks occur. Laramide sediments thin out to the east and
west of the axis of the La Veta Syncline and less markedly north and south of
the Spanish Peaks. Data accumulated by Berner and Briggs (1958) indicate a
southwestern (i.e. Culebra Range) source for most of the Huerfano formation in
Huerfano Park, and the increase of sandstone in the Huerfano formation in the
Spanish Peaks area agrees with the structural and other stratigraphic conclusions.
The Culebra range of the Sangre de Cristo Mountains was probably the major
source of Laramide sediments, and therefore possibly the most active of the units
of the Sangre de Cristo Mountains during the Laramide orogeny. Unfortunately
Laramide sediments derived from the Sangre de Cristo Mountains are not found
south of the Raton Basin. The southward thinning of the Laramide sediments
within the Raton Basin indicates that the basin probably did not extend much
farther southward.

1 Altitudes are taken as near the axis of the basin or the nearest stream as possible in order to
give some impression of actual slope.

GEOLOGY 21

The Huerfano formation (including the Cuchara formation) is comprised of
relatively fine-grained sedimentary rocks and indicates a period of relative quiet.
However, coarse conglomerates with boulders several feet in diameter are present
in the northwestern part of the Huerfano outcrop area (Poison Canyon and Black
Mountain) indicating local streams of great competence. ‘The proximity of these
conglomerates to the Bruff Creek Thrust Fault indicates the possibility of the
thrust being active during Huerfano time. If this were so, Huerfano deposition
ceased with the folding and faulting present in the Black Mountain area; renewed
quiet is indicated by the Farisita beds that overlie the Huerfano beds uncon-
formably at Black Mountain.

On the other hand, the Farisita formation records uplift in the Front Ranges,
probably the Wet Mountains, during the same interval. When the movement of
the Bruff Creek thrust had subsided, Farisita rocks were deposited over the top of
the thrust and related faults and folds, showing that active erosion (therefore
uplift?) was still in progress in the Front Ranges. The lack of angular unconformi-
ties between the Pierre shale and Poison Canyon formation, and between the
Poison Canyon formation and the Huerfano formation in the southeastern part
of Huerfano Park shows that pre-Huerfano movements in the Wet Mountains
were gentle. However, Farisita sediments overlie the Poison Canyon formation
unconformably on ‘Turkey Creek, dating the earliest strong movements of the
Wet Mountains orogeny as Eocene, probably late early Eocene. Possibly the Wet
Mountains uplift was never strong enough to affect beds in the center of the
basin so that deposition continued uninterrupted during part or all of the first
major pulse of the orogeny. The increase in amount of sediments of the Farisita
facies and their spread over the wesiern part of the basin after late Huerfano time
indicates either that sedimentation from the Wet Mountains orogeny was sufficient
to mask deposition from the Sangre de Cristo Mountains, that the Sangre de
Cristo Mountains were not being actively eroded after late Huerfano time, or that
depositional conditions had changed to favor the Farisita type lithology.

The synaxial intrusives of the Crestone-Blanca unit of the Sangre de Cristo
Mountains are probably contemporaneous with the folding or faulting of the
sedimentary rocks. This evidence of repeated uplift suggests that the present struc-
ture may have developed as a result of several movements. Most of the synaxial
intrusives were probably emplaced in the Eocene. The involvement of Poison
Canyon and Huerfano beds in the folding that occurred with the Little Sheep
and Sheep Mountains intrusions indicates a post-Huerfano age for the movement.
The relationship of these intrusives to the folds suggests that they are closely
related in time, if not contemporaneous with folding.

The Spanish Peaks and Dike Mountain are located east of the fold belt and
almost directly upon the axis of the La Veta Syncline. This sequence of intrusions
of the dike system of the Spanish Peaks was established by Hills (1901) and Knopf
(1936, 1956). All of the Spanish Peaks and Dike Mountain dikes are post-Huerfano
and probably post-tectonic intrusion as well, because the dikes from these intru-
sives cut the folded belt.

Several of the igneous bodies are located well for critical age determination.
Dates close to the boundary between the early and middle Eocene could be
obtained from Little Sheep Mountain and from a small dike in the overturned
anticline east of the JM Ranch.

The post-Farisita history of Huerfano Park is not well known, but several
inferences can be made. The Devil’s Hole formation of probably Pliocene age
rests unconformably upon Farisita beds, leaving a sedimentary gap for most of the

92 FOSSIL MAMMALIA OF THE HUERFANO FORMATION

=

middle Cenozoic; pyroclastic rocks of the Devil’s Hole formation record the
presence of middle or late Cenozoic vulcanism.

The Devil’s Hole formation is capped by the present surface of the Wet
Mountain Valley. Remnants of this surface occur on the Sangre de Cristo and Wet
Mountains, and on top of Black Mountain. Younger surfaces are south-sloping,
cut on Huerfano, Farisita and older rocks, showing a change from north-draining
to south-draining streams and indicating that at least 2,000 feet of rock has been
eroded from the central part of Huerfano Park since the cessation of Devil’s Hole
deposition.

PART at
PALEONTOLOGY

HUERFANO AND FARISITA FORMATION FossiL LOCALITIES

Eleven major and several minor localities have produced fossil mammals (see
locality map). Two definite faunal levels are preserved in the Huerfano facies: a
lower faunal level of Lostcabinian age preserved at localities VI, VIII, VIIa, IX;
an upper faunal level constituting the Gardner Butte local fauna at localities I,
II, II, V. Both faunal levels occur in the Farisita facies: locality IV represents
the Lostcabinian, and localities from one mile east to five miles north of Gardner
Butte represent the Gardnerbuttean.

Locality VII is in the Huerfano facies and probably in the lower faunal zone.
Eotitanops borealis from locality VII is a Lostcabinian species but comes from beds
higher than the lowest Lambdotherium specimens in both the Huerfano and
Wind River formations.

Scanty evidence suggests that the fauna of the Farisita facies may differ slightly
from the fauna of the Huerfano facies. Except at locality IV, Farisita fossil
vertebrates are rare and poorly preserved. Faunal difference is indicated by: the
relative abundance (12 specimens) of Hyopsodus walcottianus at locality IV and
its scarcity (6 specimens) at locality VI (a relatively rich locality); the lack of
Hyopsodus wortmani at locality IV, though it is common at most of the Huerfano
facies localities; the possibility that the Hyracotherium at locality IV is H. vasac-
ciense venticolum; and the presence of a small Bunophorus at the locality five
miles north of Gardner Butte.

The lithologies of the Huerfano and Farisita formations are different, record-
ing in part different source areas (Berner and Briggs, 1958). Possibly the two
lithologies also record different depositional conditions. If this is true then a
difference in the fauna should be expected.

The localities have the following relative positions.

Huerfano facies: Farisita facies:
Youngest I ?X Youngest 5 miles N of Gardner Butte
DOs Ds Vi PX 1 mile N of Gardner Butte
PX 14 mile E of Gardner Butte

VII ?X Oldest IV (2 miles east of Gardner Butte)
VI, VIII, VIIa
Oldest IX

PALEONTOLOGY 93

The exact position of most specimens from locality X is not known, but their posi-
tion is probably in the upper faunal level.

Locality I. Huerfano Muddy Divide, Sec. 14, 15, 16, T26S, R70W. Most specimens are
from below the white bed (unit 20 of measured section).

Cynodontomys knightensis

Microsyops lundeliusi

Absarokius noctivagus nocerat, new subspecies
Notharctus nunienus

Trogosus grangert

Paramys excavatus gardnert
Viverravus sicarius

Didymictis vancleveae, new species
Bathyopsis sp.

Hyopsodus wortmani

Hyracotherium vasacciense vasacciense
Palaeosyops fontinalis

Helaletes sp. cf. H. nanus

Hyrachyus modestus

Locality II. “Fossil Creek,” a small tributary arroyo to the arroyo that runs near the Roman
Catholic Church in Gardner; in NW), Sec. 12, T26S, R70W. Most of specimens from
unit 9 of measured section.

?Peratherium sp.
Cynodontomys knightensis
Microsyops lundeliust
Apatemys, small species
Apatemys, large species
Absarokius noctivagus nocerat, new subspecies
Huerfanius rutherfurdi, new genus and new species
Notharctus nunienus
Stylinodon sp.

Trogosus grangert
Leptotomus huerfanensis
Leptotomus grandis
Paramys excavatus gardneri
Thisbemys nini

Paramys copet

Paramys huerfanensis
Sciuravidae—several species
Mesonyx obtusidens
Sinopa sp. cf. S. strenua
Viverravus gracilis
Viverravus sicarius
Vulpavus astus

Miacis parvivorus
Uintacyon sp. cf. U. asodes
Oddectes herpestoides
Coryphodon sp.
Hyopsodus wortmani
Hyopsodus paulus
Hyracotherium vasacciense vasacciense
Palaeosyops fontinalis
Eotitanops minimus
Helaletes sp. cf. H. nanus

24 FOSSIL MAMMALIA OF THE HUERFANO FORMATION

Hyrachyus modestus
Bunophorus sp. cf. B. macropternus
Antiacodon pygmaeus huerfanensis, new subspecies

Locality III. East side of arroyo in Elf Sec. 3, T26S, R70W. The arroyo is called either
Milligan’s Arroyo or CCC Draw by local residents. A Mr. Milligan had a house near the
mouth of this arroyo in the last decade of the Nineteenth Century; some of R. C. Hills’
specimens were collected near the house.

Scenopagus priscus, new combination
Scenopagus edenensts

Nyctitherium sp. cf. N. velox
Cynodontomys knightensis

Microsyops lundeliusi

Absarokius noctivagus nocerat, new subspecies
Notharctus nunienus

Trogosus grangeri

Paramys copei

Paramys huerfanensis

Paramys excavatus gardneri
Thisbemys nini

Leptotomus grandis

Sciuravidae

Mesonyx obtusidens

Patriofelis ulta

Viverravus gracilis

Oddectes herpestoides

Bathyopsis fissidens

Hyopsodus wortmani

Hyopsodus paulus

Hyracotherium vasacciense vasacciense
Antiacodon pygmaeus huerfanensis, new subspecies

Locality V. A small tributary arroyo entering William’s Creek from the west about 2 miles
north of the junction of William’s Creek and the Huerfano River. The locality is in the
El% Sec. 1, T26S, R70W. The fossils were collected from a red-to-pink mudstone which
may be correlative with unit 9 of the locality II section. Locality V is separated from
locality II by a small pediment-capped divide.

Microsyops lundeliusi

Notharctus nunienus

Trogosus grangeri

Paramys excavatus gardneri
Viverravus gracilis

Hyopsodus wortmant

Hyracotherium vasacciense vasacciense
Palaeosyops fontinalis

Hyrachyus modestus

Locality VII. An arroyo entering the Huerfano River from the south in Sec. 29, T26S,
R69W. The fossil-bearing exposures are in the NEl4 Sec. 31 and the NW), Sec. 32 of
the same township. Granger called this arroyo “Apodock Gulch,” but the apparent
locality of Apodaca Gulch is Sec. 33 and Sec. 28 of the same township. This latter loca-
tion is the next arroyo northwest of Garcia Cafion and is part of Locality VI of this
report. This locality is probably high in Lower faunal zone.

Loveina zephyn
Paramys copet
Viverravus gracilis
Eotitanops borealis

PALEONTOLOGY 25

SCATTERED LOCALITIES IN THE UPPER FAUNAL ZONE

Locality of University of Michigan. Center of Sec. 31, T25S, R69W, from Huerfano facies
in zone of intertonguing between the Huerfano and Farisita formations.

Hyopsodus wortmani

Eotitanops minimus
Locality SEY, Sec. 26, T25S, R70W. Huerfano facies in zone of intertonguing of Huerfano
and Farisita formations.

Rodent
R. C. Hills’ localities. R. C. Hills collected fossil mammals from several localities which I
have not been able to relocate. His localities which have been relocated are included in
the American Museum locality numbers. Most of Hills’ Huerfano specimens are in Yale
Peabody Museum. The notable exception is the type of Trogosus hillst in the U. S. Na-
tional Museum. Locality #5 of R. C. Hills. Upper faunal zone.

Trogosus grangeri
Palaeosyops fontinalis
Helaletes sp. cf. H. nanus

Near Hausero’s Ranch or | mile south of Hausero’s. Upper faunal zone.

Stylinodon sp.
Palaeosyops fontinalis

“Box Canyon” (see Osborn 1897). Upper faunal zone.

Patriofelis ulta
Locality—I1 mile ‘‘a little southeast” of Gardner Butte. Upper faunal zone.

Palaeosyops fontinalis

This important locality is undoubtedly the lowest upper faunal zone locality in Huerfano
Park. The locality is probably in Sec. 20, T26S, R69W, or less than 1 mile west of locality
IV in the Farisita facies, and near to AMNH locality ‘4 mile east of Gardner Butte.”

Locality IV. A small arroyo north of Colorado Highway 69, across the road from the small
Roman Catholic cemetery about two miles east of Gardner Butte. SW14 Sec. 21, NW4
Sec. 28, T26S, R69W. The best collecting is from gray-brown mudstone that crops out in
the NE part of the arroyo. The bed lacks concretions and has a “soft” texture. The bone
from this locality is broken but often has an almost “recent” appearance and color. This
locality is in the Farisita facies.

Cynodontomys scottianus

Viverravus gracilis

Coryphodon sp. (14 mi NW of other specimens, in main part of the arroyo).
Hyopsodus walcottianus (common)

Hyracotherium vasacciense ?venticolum

Lambdotherium popoagicum

?Heptodon sp.

Bunophorus macropternus

SCATTERED LOCALITIES IN THE FARISITA FACIES

1 mile north of Gardner Butte. Sec. 17 or Sec. 18, T26S, R60W. upper faunal zone (?)
Metacheiromys sp.

5 miles north of Gardner Butte, east side of William’s Creek. Probably Sec. 29, T25S,
R69W.
Bunophorus macropternus

Y% mile east of Gardner Butte; NW1{ Sec. 20, T26S, R69W. Possibly near to Hills’ locality
“1 mile a little southeast of Gardner Butte.” Probably upper faunal zone.

26 FOSSIL MAMMALIA OF THE HUERFANO FORMATION
Hyracotherium vasacciense vasacciense

Locality VI. Huerfano facies. Exposures in Garcia Cafion and Apodaca Gulch Sec. 33 and
Sec. 34, T26S, R69W and in Sec. 3, 4, 5, T27S, R69W. This is the best locality in the lower
faunal zone beds. Most of Wortman’s collection of 1897 came from here and probably
from unit 13 of measured section; unit 13 has consistently produced good specimens and
matches the description of the best bone-bearing layer given by Wortman to Osborn.
Granger and Olsen also made good collections here.

?Diacodon or ?Palaeictops sp.
Cynodontomys knightensis
Cynodontomys scottianus
Phenacolemur jepseni simpsoni, new subspecies
Loveina zephyri

Notharctus nunienus
Stylinodon sp.

Esthonyx acutidens

Paramys excavatus gardneri
Oxyaena sp. cf. O. lupina
Viverravus gracilis
Didymictis altidens
Coryphodon sp.

Hyopsodus wortmani
Hyopsodus walcottianus
Phenacodus vortmant
Hyracotherium craspedotum
Hyracotherium vasacciense vasacciense
Lambdotherium popoagicum
Bunophorus macropternus
Diacodexis chacensis

Locality VIII. Exposures on the northeast side of Oak Creek near the road that runs from
Farisita westward on the south bank of Huerfano River. Most of the specimens come from
the four excavations known as “Costillo Pocket.” NWI, Sec. 2, T27S, R69W.

Talpavus sp. cf. T. nitidus

Palaeictops bicuspis

Cynodontomys knightensis

Esthonyx acutidens

Leptotomus costillot

Didymictis ?protenus

Coryphodon sp.

Hyopsodus wortmant

Hyracotherium craspedotum
Hyracotherium vasacciense vasacciense

Locality VIIIa. Exposures at the northwest end of the divide between Oak Creek and
South Oak Creek, about 14 mile south of the headquarters of the Silverstine Ranch. NWI4
Sec. 20, T27S, R69W.

Cynodontomys knightensis
Coryphodon sp.

Hyopsodus wortmani
Lambdotherium popoagicum

Locality IX. Archuleta Draw, the arroyo that runs between Oak and South Oak Creeks.
Fossil bearing beds are in Sec. 11, T27S, R69W. The fossils came from the lower part of
unit 6 of the measured section.

PALEONTOLOGY Di

Coryphodon sp.

Phenacodus vortmani

Hyracotherium craspedotum
Hyracotherium vasacciense vasacciense

Locality X. Black Mountain or Promontory Bluff. Exposures along the southwest face of
Black Mountain in Sec. 25, T25S, R71W and Sec. 30, T25S, R70W. The Huerfano forma-
tion at locality X is unconformably overlain by the Farisita formation and grades down-
ward into the Poison Canyon formation. The section is complicated by faulting and the
lower contact is locally hidden beneath the hanging wall of a fault. The lower beds of
the Huerfano formation dip steeply or are overturned; the dips decrease higher in the
section (northeastward). Complete sections of the Huerfano formation, though probably
present, could not be measured due to the faulting and the lack of continuous exposures.
The Huerfano formation may be thicker at locality X than at the type locality in the
Poison Canyon-Huerfano River-Muddy Creek area.

Only one fossil has been collected here in recent years, a tooth of Didymictis vancleveae
whose stratigraphic location is noted in Section 7. Granger and Olsen collected a rodent
skeleton, Reithroparamys huerfanensis, high in the exposures on Black Mountain and
surely from beds equivalent to the upper faunal zone beds a few miles farther southeast-
ward.

TABLE 3
Non-mammalian fauna of the Huerfano formation

Lower faunal Upper faunal

Mollusca zone zone
Gastropoda, at least three species of snails x x
Chordata
Osteichthyes
Semionotoidea
Lepidosteidae
Lepidosteus sp. x me
Reptilia*
Chelonia oS x
Squamata
Anguidae x
Glyptosaurus hillst Gilmore x
? Peltosaurus sp. <i x
Varanidae
Saniwa sp. O% x
sp. indet. x
Aniliidae
Contophis carinatus Hecht be
Colubridae
Cheilophis huerfanoensis Gilmore x
Crocodilia x x
Aves mS

* Provisional identification of reptiles by Dr. Max Hecht.

‘TAXONOMY

Measurement of Specimens. Every effort has been made to be as accurate as
possible in taking measurements of teeth. I must admit to a personal dislike for
the use of tooth length measurements, since the manner of arrangement of most
mammal teeth in the jaw does not allow for accurate tooth length determination.
Isolated teeth are another matter. Many isolated M 1’s and M 2’s are so similar

28 FOSSIL MAMMALIA OF THE HUERFANO FORMATION

that they cannot be located in the series. Tooth length measurements are taken
either lingually or buccally depending on which seems to give the best approxima-
tion of the actual length, the approach being uniform for any given species. In
a relative sense, these measurements are valid, but what I consider a tooth length
another may not.

Tooth widths are more accurate measurements. However, many students
measure only the maximum width of a tooth. Where only one possible part of a
tooth could be a maximum width, such as across the protoconid of most lower
premolars, or across the trigonid of M, of Uintacyon, maximum widths are usable
measurements. However, many mammals have molars with trigonids and talonids
of similar width. In one specimen of a species, the trigonid may be wider on M,
and in another, the talonid may be wider. This is particularly true of the common
genera, Hyracotherium and Hyopsodus, in which widths of M,.2. can be greater
either fore or aft. A table of maximum widths of such teeth is then a summation
of a partial sample of two variables. For this reason I have included trigonid
and talonid widths of lower teeth and anterior and posterior widths of upper
teeth where I thought confusion could arise.

ABBREVIATIONS
Museums:
AMNH American Museum of Natural History
USNM United States National Museum
YPM Yale Peabody Museum

Teeth: Subscript numbers-lower teeth,
superscript numbers-upper teeth.

I Incisor

C Canine

P Premolar

IDE Deciduous premolar
M Molar

tr Trigonid

tal Talonid

buc Buccal side

ling Lingual side
Measurements:

L Length

W Width

D Depth

mm Millimeters

ft Feet

N Number of Specimens
OR Observed Range

M Arithmetic Mean
SD Standard Deviation

Vv Coefficient of Variability

PALEONTOLOGY 29

CLtass MAMMALIA
OrpeER MARSUPIALIA
Famity DIDELPHIDAE

?Peratherium sp.
Plate I, figure 7

AMNH field no. 1952-328 from locality II is a broken jaw fragment with a damaged
M;. The jaw has the inflected angular process and internal mandibular foramen of
marsupials, and the preserved part of the tooth indicates that the specimen is probably
Peratherium.

Orver INSECTIVORA
FAMILY ERINACEIDAE
Talpavus sp. cf. T. nitidus Marsh, 1872
Plate I, figure 1

AMNH 55226, a fragment of a left jaw with P,-M, and at least three anterior alveoli,
from locality VIII is very similar to the type of Talpavus nitidus Marsh. The type speci-
men, YPM 13511, leaves some doubt regarding the specific identity of the Huerfano speci-
men; the difference in stratigraphic position (Lostcabinian vs. Twinbuttesian) adds to this
doubt.

In 55226, the parastylid of P, is low and well in front of the protoconid and is placed
on the midline. The heel of P, of 55226 consists of a simple median cusp in the posterior
margin; the cusp is separated from the protoconid by a slight, externally directed groove.
The same groove is present in Centetodon pulcher (= Hypacodon praecursor, YPM
13619), but it is more pronounced (McKenna and Simpson, 1959, p. 10).

Scenopagus McKenna and Simpson, 1959

McGrew (1959, p. 151) and McKenna (1960) called attention to the dissimilarity be-
tween Talpavus nitidus and Nyctithertum priscum on the one hand and Nyctitherium
velox on the other and stated that the former two species probably did not belong in the
genus Nyctithertum where Matthew (1909) had placed them. With only the type specimens
for comparison, it would be hard to draw generic distinction between T. nitidus and N.
priscum; the latter species is larger and distinct. More complete specimens show that suf-
ficient differences exist to warrant generic separation, and that N. priscum and Scenopagus
edenensis (McGrew, 1959) belong in the same genus.

The morphology of the teeth of Scenopagus is very similar to Proterixoides (Stock,
1935), and Scenopagus makes a logical ancestor for the Sespe genus. The differences noted
between Scenopagus and Proterixoides indicate a “fattening” of the teeth in time; many
Erinaceidae have robust teeth and the trend in the Eocene forms is probably normal.

The premolar teeth of Scenopagus are aligned on a different axis than are the molar
teeth (See Plate III, figure 5). This may indicate that Scenopagus was one of the “‘narrow-
snouted” erinaceids.

The anterior root of P, is preserved and is directed ventroposteriorly, indicating some
crowding of the premolar tooth roots and the possibility of a procumbent incisor of the
Proterixoides type.

Scenopagus priscus (Marsh, 1872) new combination
Plate I, figure 3

AMNH 55156 from locality III is referable to Scenopagus priscus. The Huerfano
specimen is about 25 per cent smaller than a referred specimen, YPM 14610-lb, from the
Bridger formation but is similar in size to AMNH 11488 also from Bridger beds. Matthew
(1909, plate 50, figure 7) referred the latter specimens to Nyctithertwm (= Talpavus)
nitidus.

The heel of the P, of AMNH 55156 is narrower than the trigonid; in Bridger speci-
mens the heel of P, is wider.

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snspqouarsy JO Y}99} JOMO] JO (SIdJOUITT]IJA, Ul) S}UWOINseof[
v HIGVL

PALEONTOLOGY 31

Scenopagus edenensis (McGrew, 1959)
Plate III, figures 4-5

Scenopagus edenensis is represented by one specimen, AMNH 17483, a jaw fragment
with P,-M, from locality III. The P, has a small, low paraconid antero-lingual to the
protoconid and lingual of the midline.

Measurements of S. priscus and S. edenensis specimens known to me are listed in
Table 4.

Famity LEPTICTIDAE
Palaeictops bicuspis (Cope, 1880)
Plate I, figure 2

Palaeictops bicuspis is represented by a single specimen, AMNH 55271, a left M,, from
locality VIII (Costillo Pocket). The paraconid is small and located on the midline of the
tooth as in other leptictids.

Diacodon or Palaeictops sp.

Two lower jaws, some upper teeth, and other skeletal parts of a leptictid came from
locality VI, AMNH 17555. The teeth are either broken or buried in matrix so that generic
identification is impossible.

FamMity NYCTITHERIDAE
Nyctitherium sp. cf. N. velox Marsh, 1872
Plate II, figure 3

One specimen of Nyctitherium, AMNH 55151, a fragment of the left jaw with M,z..,
was collected at locality III. It does not have the pronounced external cingulum on the
molars characteristic of the less worn specimens of N. velox, but a thin cingulum is present.
The Huerfano specimen is slightly larger than the type (YPM 13510) and agrees well
with several referred specimens (YPM 14936, 14935 and 14956).

McGrew (1959 p. 151) noted that N. velox is similar to AMNH 15103, reterred by
Matthew (1918 p. 605) to N. celatum but that the external cingulum is lacking in the latter
species. N. serotinum from Bridger B is very similar to N. velox but it is smaller and lacks
the external cingulum.

All of the Yale specimens of N. velox come from upper Bridger localities and two of
the three specimens of N. serotinum come from the lower Bridger beds (Grizzly Buttes)
and one specimen, YPM 13621, comes from a locezlity, Twin Buttes, that could have
either upper or lower Bridger fossils (fide Gazin, oral communication). The external
cingulum on the molars of the upper Bridger Nyctitherium may represent specialization.
The Tabernacle Butte N. velox is probably late Bridgerian (McGrew, 1959, p. 125). The
Huerfano Nyctitherium certainly is older than early Bridgerian but does have the
cingulum. Perhaps the occurrence of a cingulum is variable.

OrpER PRIMATES
Famity NOTHARCTIDAE (sensu Gazin, 1958)
Notharctus nunienus (Cope, 1881)
Plate VIII, figure 3

MATERIAL. Locality I: AMNH 17020; Locality II: AMNH 17479, 17478, 17481, 17494,
55157, 55158, 55159, 55160, 55772, 55228; Locality III: AMNH 17477, 17480; Locality V:
AMNH 17492; Locality VI: AMNH 17459, 17550, 55224.

Notharctus nunienus occurs in both faunal zones of the Huerfano formation. Three
specimens have come from locality VI, lower faunal zone; fourteen specimens have come
from localities I, I, III, and V, upper faunal zone. The two samples show little difference.

One specimen from locality Il, AMNH 55157, has nearly all teeth preserved. The first
upper incisor is wide (Gregory, 1920, p. 153); the crown is curved. The two lower incisors
are small and occlude with I’; I? is caniniform and occludes between the lower canine
and I,.

32 FOSSIL MAMMALIA OF THE HUERFANO FORMATION

AMNH 17478, from locality I, is large for N. nwnienus but resembles the other speci-
mens and has been included in the statistics for the upper faunal zone sample.

Notharctus increased in size during the middle Eocene (Robinson, 1957; Gazin, 1958).
N. nunienus is smaller than the Bridger Notharctus and also smaller than N. venticolus
from the Lost Cabin fauna of Wyoming (Granger and Gregory, 1917, p. 843). Measure-
ments of lower teeth indicate that the upper Huerfano population was composed of ani-
mals whose mean size was slightly larger than that of the lower Huerfano Notharctus.
The sample from the lower faunal zone is too meager for reliable analysis, but the
pertinent data are:

Lower faunal zone Upper faunal zone
N M N M
Length M2 3 5.00mm 11 5.37mm

This illustrates the trend for closely related populations of Notharctus to increase in
size in time.

TABLES

Measurements (in Millimeters) of lower teeth of Notharctus nunienus from the
Huerfano formation

Upper zone sample Lower zone sample
Variate N OR M SD V N OR M
P; Length 3 22723-6327 — — 1 3.8
Width Ga S=2 Se! Qe2i — — -— --
P, Length Si K656-4079 4 “10. 4410874 1 4.0
Width 8982243547 93.09) 107338 310268 1 3.4
M; Length Sraer4 6-5. 58 506" © 0238. 9 Siar 1 4.4
Width trigonid ~ 8° ~353=3.9 93°55) 0221 5492 1 325
Width talonid 8.) 368=476 7404-1030 7.43 1 3.8
M: Length 1 > Se 0S6n45 i536" VOn44e 852i 3. 4125.53 235208
Width trigonid 11 3.5-4.5 4.02 0.26 6.47 3 4.04.7 4.27
Width talonid 11 <420-5.1) 4.33" 0.25 S77 3 4.0-4.9 4.40
M; Length f eSO5=122 0 26. 169 0F61) 929290 2 .631=6.3) 16920
Width trigonid 7 3:0-4.1 3.73 0.37 9.92 1 4.1
Width talonid Soe Siil=su8ee 13555). 20630) W8245 il Sate

Famity OMOMYIDAE (sensu Gazin, 1958)
Loveina zephyri Simpson, 1940
Plate II, figure 2

Two specimens, AMNH 17554 from locality VI and AMNH 55219 from locality VII,
are referred to Loveina zephyri. The M, of No. 17554 resembles the type, AMNH 32517,
closely. The paraconid of P, of the type is located more internally than in the Huerfano
specimens. This, however, could be normal variation within the species.

Measurements (in Millimeters) of Loveina zephyrt are:

17554 55219

Length P, De 1.9
Width P, eth
Length M,

Width trigonid M,
Width talonid M,
Length M2

Width trigonid M2
Width talonid M2

mm RS DOR rR bt
Con OAK AO

PALEONTOLOGY 33

Shoshonius cooperi (Granger, 1910)
Plate III, figure 3

One specimen, AMNH 55153, from locality II, is referable to Shoshonius cooperi. The
three lower molars are preserved, and nothing can be inferred about the still unknown
premolars of this species. The external cingulum on the molars is more pronounced than
in the referred specimen AMNH 14665 (Matthew, 1915c, p. 455).

Measurements (in Millimeters) of AMNH 55153 are:

Width Width
Length trigonid talonid

Mi 2.4 1.9 1)
M: Z.3 1.6 Daal
M; 2.8 yf 1.8

Famity ANAPTOMORPHIDAE (sensu Gazin, 1958)
Absarokius noctivagus nocerai new subspecies”
Plate II, figure 1

Type. AMNH 55215, a fragment of left jaw with two anterior alveoli and P,-Msg.
Another specimen, AMNH 55270, is a fragment of the right jaw with P,-M,; 55270 is as-
sociated with AMNH 55215 and may be from the same individual.

Hypropicm. Type and AMNH 55217, 55218, 55152, 55154, 55155, 55270 and 55292.

Horizon AND Locaity. Upper faunal zone, Huerfano formation. Type and nos. 55270,
55292 from locality II; no. 55218 from locality I; nos. 55217, 55152, 55154, 55155 from
locality III.

O Huerfano
Absarokius O Lost Cabin
+ Lysite
M M2
n
S OO
O
ie (oe ®) O
= ae © o O
Or : 5
2) G ;
Wtal

O

“15 2.0 25 15 20 25mm. 1.0 5 20

Figure 5. A scatter diagram comparison of widths of trigonids (Wtr) and talonids (Wtal) of
lower molars of Absarokius from the Lysite, Lost Cabin and Huerfano beds.

Diacnosis. M, averages larger size than M, of A. n. noctivagus. M, larger than M, of
A. n. noctivagus. A. noctivagus nocerai is smaller than A. witteri.

2 This subspecies is named in honor of Mr. Joseph Nocera of the American Museum of Natural
History who collected the type specimen.

34 FOSSIL MAMMALIA OF THE HUERFANO FORMATION

Discussion. A. noctivagus nocerai is distinctly larger than A. noctivagus noctivagus
from the Lost Cabin member of the Wind River formation. M, of A. noctivagus nocerat is
about the same size as the Lost Cabin subspecies. The M, of A. n. nocerat is generally
larger but the size ranges of the two subspecies overlap. M, is always larger in the Huerfano
subspecies. A gradual increase in size in time is noted for M, and M, of Absarokius (figure
8, 9). A. witteri (Morris, 1954) from the Cathedral Bluffs tongue of the Wasatch forma-
tion is a large form that is probably not closely related to this subspecies.

The number of teeth in the jaw of Absarokius has been a matter of doubt. Matthew
(1915c, p. 465) decided that there were only two teeth in front of P, and gave 1.1.3.3. as
the lower dental formula. Morris (1954, p. 200) states that four or five alveoli are
present in front of P, in A. abbotii, AMNH 14673; the alveoli are actually in front of P,.
AMNH 55215, the type of A. noctivagus nocerat, has two alveoli in front of P,. P, is
single-rooted and P, is double rooted. The type specimens of A. n. noctivagus and A.

TABLE 6

Measurements (in Millimeters) of lower teeth of Absarokius noctivagus nocerat
new subspecies and A. n. noctivagus

A. n. nocerat A. n. noctivagus
AMNH no. 55215 55270 "So218 155247 55152 15601 15602
type type
Variate
P, Length NY — — — — -— _
Width i es — — — — _- ——
P; Length 1.9 EC — — 1.4 220 —_
Width 2.0 1.8 — — 1.4 2.0 —
P, Length 2.6 2.8 2.6 — 255 2 —
Width 2.6 220 255 — 2.5 2.6 2.6
M, Length 23 223 2.4 Ia) — 2.4 2a5
Width trigonid 9 1.8 Del DAO) — Zt 2.0
Width talonid jai 250 2.4 DeD Dea 2d 223
M, Length 243 2. 2:6 Diath 2.4 23 2.4
Width trigonid 2 20 2.4 2.4 Deo 2.0 2:0
Width talonid Ze 2.0 2.4 2-3 Dee 22 222
M; Length 205 — 392 2.8 U5) 2.4 —
Width trigonid a7 — OMA Det. 1.9 1.6 —
Width talonid 1.6 — — 178 1.8 1.5 —

Absarokius

E

=

a O ©

al © Huerfano
= ©
= O © Lost Cabin
= ‘Om noctivagus

’ Lysite

Length Mz

220 3.0 mm

Figure 6. A scatter diagram comparison of trigonid width (Wtr) and length of M, of Absarokius.

PALEONTOLOGY 35

wittert have double-rooted P,’s (Matthew, 1915c, p. 464, fig. 36; Morris, 1954, pl. 21, fig.
2). AMNH 55215 shows that there are eight teeth, but the homologies of the two anterior
ones are not certain. The alveoli of the two anterior teeth are of equal size; the first might
be an incisor or a canine, the second an incisor, canine or a premolar. This question must
remain unanswered until the anterior teeth are found.

A. noctivagus is the most abundant of the “‘tarsioid’”’ primates in the Huerfano forma-
tion. It is not present in the lower faunal zone, but only four ‘“‘tarsioids’’ have been found
in the lower zone, so the absence of A. noctivagus may be due to collecting bias.

Tooth measurements are listed in Table 6.

HUERFANIUS new genus®

Type. Huerfanius rutherfurdi new species, only known species of genus.

KNOWN DISTRIBUTION. Upper faunal zone, Huerfano formation.

D1acnosis. Lower molar teeth (as far as known) similar in size and morphology to
Uintanius; lower premolar teeth (as far as known) similar to but smaller than Absarokius,
not compressed antero-posteriorly.

Huerfanius ruikerfurdi+ new species
Plate III, figure 1

Type. AMNH 55216, fragment of left jaw with P,-M,.

Hypopicm. Type only.

LOCALITY AND DISTRIBUTION. Locality II, 2 miles north of Gardner, Huerfano County,
Colorado. Upper faunal zone, Huerfano formation, uppermost lower Eocene.

Diacnosis. As for the genus.

Discussion. Huerfanius rutherfurdi is similar to Uintanius ameghini in size and in
the morphology of the molars. Its premolars are similar to those of Absarokius. The speci-
men shows a stage of premolar development intermediate to the condition in Absarokius
and Uintanius; the premolars of Huerfanius lack the antero-posterior compression charac-
teristic of Uintanius. This specimen shows that Uintanius might have evolved from
Absarokius, passing through a stage similar to or represented by Huerfanius. The P, of
Uintanius, in addition to being compressed has a paraconid, while the P, of Absarokius
and Huerfanius lacks a paraconid.

Huerfanius is easily separable from most other anaptomorphids by its Uintanius-like
M.. In Absarokius, Anaptomorphus, Tetonius, and Trogolemur the paraconid of M, is
either absent or a small cusp close to the metaconid. Huerfanius and Uintanius, however,
have prominent paraconids placed on the midline of M,.

Measurements (in Millimeters) of the type specimen are:

Length P3 Det
Width P; ey
Length P, 24
Width P, 2VE
Length M, 2.0
Width trigonid M, 15
Width talonid M, 1.6
Length M, 1.8
Width trigonid M. 1.4
Width talonid Mz 1.6

3 Named for the Huerfano River.
4The species is named in honor of Mr. Hugo Rutherfurd of Gardner, Colorado, who gen-
erously aided the field parties of the American Museum and Yale.

36 FOSSIL MAMMALIA OF THE HUERFANO FORMATION

OrpvER PRIMATES (incertae sedis) or INSECTIVORA
Famity APATEMYIDAE
Apatemys, large species
Two specimens of a large Apatemys, AMNH 17454 and YPM 16444, have been collected
from locality II. AMNH 17454 has both rami present, but with the exception of an incisor
root, lacks teeth, whereas YPM 16444 has the root of the incisor and poorly preserved
P,-M,. The jaws are larger than those of A. bellus and smaller than the jaw of the type of
A. rodens (see Table 7). The teeth of YPM 16444 are similar in size to those of A. bellus.
Unfortunately the teeth are too poorly preserved to permit accurate comparison with
Bridger specimens. AMNH 17454 shows that the number of alveoli per tooth is P;, one;
P,, one; M,-M, two each. The single rooted P, indicates that this character does occur in
larger apatemyids (see Simpson, 1954, p. 3) and that the presence of two roots on P, may
not be significant taxonomically. However, the Huerfano Apatemys are sufficiently different
to warrant reservations in any reference to Bridger species.

Apatemys, small species

One specimen of a small Apatemys, YPM 16477, was collected at locality II. It consists
of a fragment of the right jaw with incisor root, alveoli of P,_, (one each) and M,; M, and
M, are present but poorly preserved. The jaw is comparable to that of A. bellus in size
but the teeth are smaller than those of A. bellulus. The specimen is not of good enough
quality to be used as a type; the application of a name awaits better material. Measure-
ments are given in Table 7.

Huerfano Apatemys are unusual in that the teeth are relatively small. In both species
the jaw is relatively massive, indicating that the Huerfano forms are relatively more
specialized than A. bellus or A. bellulus of the Bridger. The Huerfano specimens may
represent undescribed species, but their inclusion within A patemys is reasonable. Although
there is a great variability in the size of Apatemys jaws (see table 7) the variation in the
size of the teeth is less. The jaw of a referred specimen of A. bellulus, AMNH 12048 is
4.8 mm deep and that of the type of A. rodens is aimost twice as large, 9.3 mm. Yet the
difference in the length of the respective P,’s is 1.1 to 1.5 mm. There is a direct correlation
between size of incisor and depth of jaw; a correlation also exists between the depth of jaw
and molar tooth size, but the relative increase is less. A. bellulus and A. rodens cannot
now be shown to belong to the same species, but I would not be surprised if additional data
should indicate that they are conspecific.

FaAMILy PHENACOLEMURIDAE
Phenacolemur jepseni simpsoni new subspecies
Plate III, figure 2

Tyre. AMNH 2680, fragment of a right lower jaw with root of incisor, P,-M, and
alveoli of M..

Hypopicm. Type only.

DISTRIBUTION AND LOCALITY. Lost Cabin equivalent (lower faunal zone), Garcia Canyon
local fauna, of Huerfano formation, Huerfano County, Colorado. The specimen was col-
lected by Dr. Wortman in 1897 and the exact locality is not known. Most of Wortman’s
fossils from the lower faunal zone came from the Garcia Canyon area (locality VI).

Diacnosis. P, significantly smaller than that of type of P. j. jepseni from the strati-
graphically much lower Almagre facies of the San Jose formation. The lack of expanded
talonid heel readily separates this subspecies from the Almagre form. M, similar to P. 7.
jepsent.

Discussion. P. jepsenit simpsoni is more slender than P. j. jepseni. The reduced size of
the P, further exemplifies a trend for size reduction noted by Simpson (1955, p. 428).
Phenacolemur has been recorded from Lost Cabin beds (Simpson, 1955), but the where-
abouts of the Wyoming specimen are not known.

It is interesting that the Huerfano specimen, which has only recently come to light,
was probably the first Phenacolemur ever to be collected.

5 Named for Dr. George Gaylord Simpson who recently monographed the Phenacolemuridae.

TABLE 7
Measurements of Apatemys (in Millimeters)

A, bellulus Huerfano
small sp.
YPM* AMNH AMNH YPM
13513 12060 12048 16477
Type
I width _— — 1.3e 38)
depth — — 2.5e 3.0
P; length — — aaa —
width = = — —
P, length 1.1le 0.9 iL gal —
width — 0.7 0.8 —
M, length 1.8 1.8 17, IES)
width 12 i2 2 1.0
M: length 1.9 — 1.9 1.7e
width G8) — 1.4 1.0e
Depth of
Jaw at M; —_— — 4.8 5.0
A. bellus
YPM* USNM* AMNH AMNH* YPM YPM
13512 13276 11425 12047 13520 11766
Type
I width 15 1.6e — — — —
depth 3.0e oul — — — —
P; length — — —_— —_— _— —
width — — — — — —
P, length — LenS 145 — _- —
width — — 0.7 — — —
M;, length — — — 2.0 es —
width — — — 1.4 1.4 —
M:; length 223 2.4 223 Zed 25 225
width 1.6 ah 1.6 1.4 125 17
Depth of
Jaw at Mz 5.6 3 S60) — — —
Huerfano A. rodens
large sp.
YPM AMNH 17454 Y¥PM*, USNM*
16444 Right-Left 12973 13277
Type
I width 744) Zt Dep) 2-9 2-9
depth 4.1 3.9 3.8 5.4 6.0e
P; length 2.2e — — — 5.0e
width tla — — — Deal
P, length ie — — — iWees)
width 1.0 — — — —
M; length De, — — — —_
width 1.4 — — — —
M; length — — -- —
width — — — — —
Depth of
Jaw at M; 6.7 120 7.0 9.3 —

data from Gazin, 1958.
estimate.

38 FOSSIL MAMMALIA OF THE HUERFANO FORMATION

TABLE 8
Measurements (in Millimeters) of Phenacolemur jepsent specimens
P, Mi
|B W L_ W-trigonid W-talonid Depth of Jaw at

P. j. jepsent type

AMNH no. 48005 DOP lead Z.3 1.6 ay 7.1mm
P. j. simpsoni type

AMNH no. 2680 DAO Seiler Dell 5 16 5.0

Famity MICROSYOPIDAE

McKenna (1960) has re-erected Matthew’s family Microsyopidae to include the genera
Cynodontomys, Microsyops and Craseops. Three species of microsyopids are found in the
Huerfano formation: Cynodontomys scotttianus and C. knightensis in the Garcia Canyon
local fauna and C. knightensis and M. lundeliusi in the Gardner Butte local fauna. The
distribution of these species is listed in Table 9.

TABLE 9
Numbers of individuals of microsyopid species at Huerfano formation localities
Species Localities
I Pi Se Ve LY Ne VL Vina exe
C. scottianus —- —- — — 2 =? — —_- —
C. knightensis 1 1i 8 — — 3 1 1 1
M. lundeliusi 2 32 1 1 —- — — —- =
u
Cynodontomys from the Huerfano
formation
oO
nD O
a °
a Site
ee ao)
Z CO:
=
ow vs
localities
O™, wa
i © awe
o TT
O W tal My, “TL
aK) eas) 2.0 Zo 3.0 SS) 4.0mm

Figure 7. A scatter diagram comparison of widths of trigonid (Wtr) and talonid (Wtal) of My,
of Cynodontomys from several localities in the Huerfano formation.

PALEONTOLOGY 39

Cynodontomys scotitanus (Cope, 1881)
Plate IV, figure 1

Two specimens, AMNH 17543 and YPM 16468, both from locality IV, are referred to
this species, and AMNH 17544 from locality VI may also belong to it. C. scottianus is very
similar to Microsyops lundeliusi in size (see Tables 10, 12) and may be ancestral to it. The
P, of YPM 16468 is not as molariform as the same tooth in C. knightensis. The Huerfano
C. scottianus lies near the upper limit of the range of tooth size for the C. scottianus from
the Lost Cabin member of the Wind River formation. C. knightensis is at the lower end
of this range. This size difference could be explained if the two were actually competitors.
However, the known distribution shows that the two species probably inhabited different
areas and, perhaps, environments.

TABLE 10

Measurements (in Millimeters) of lower teeth of Cynodontomys scottianus from the
Huerfano formation

M 1 M 2
W- W- W- W-
[cocal=5 E> P; IPA thi tale tri- _tal-

Specimen hay eee DY, Eo OW OW. L gonid onid L gonid onid
AMNH

17543 left Iv — — —_—- — AA 29 632 AS 83 SS

17543 right WV 24°04 3.1 2:0 —- — —- — — 44 3.1 3.5

YPM

16468 Iv — — — a AD Sy 4:3. .73:3,,,,. 13:5 —_- — —
Cynodontomys ?scottianus

AMNH

17544 VI — — —_- — — — 44 — — 48 — 4.0

Cynodontomys knightensis Gazin, 1952
Plate IV, figure 2

MATERIAL. Locality I: AMNH 17471; Locality Il: AMNH nos. 17473, 17482, 55161,
55162, 55166, 55167, 55168, 55225, 55286, field no. 1952-342; Locality III: AMNH nos.
17019, 17028, 17022, 17470, 55223, 55163, 55164, field no. 1952-538; Locality VI: AMNH
nos. 55221, 55222; Locality VIII: AMNH nos. 55287, 55290, 55291; Locality VIIIa: AMNH
55288; Locality X: AMNH 17018.

This species is almost ubiquitous in both zones of the Huerfano formation except at
locality IV, where it is seemingly replaced by C. scottianus. At least 25 specimens are known
from both faunal zones. The absence of C. knightensis from locality IV and the presence
of C. scottianus at that locality is probably of ecologic significance, even though the sample
is small.

Gazin (1952, p. 20) noted that this species was the same size as C. latidens but morpho-
logically like C. scottianus. The Huerfano C. knightensis is similar to C. latidens in size,
but the mean of the Huerfano sample is slightly greater.

The sample of C. knightensis from locality II is composed of specimens whose mean
size is slightly smaller than those from locality III. This is shown in the scatter-diagram,
figure 7. This may be significant since Microsyops lundeliusi is so common at locality II,
where similar sized individuals of the two species might have been competitors. However,
the differences shown in figure 7 may be due to depositional agencies or to sampling error.

FOSSIL MAMMALIA OF THE HUERFANO FORMATION

TABLE 1
Statistics (in Millimeters) of lower teeth of Cynodontomys knightensis

Variate Locality N OR M
Length Ill 1 2.0
3 xX 1 Sei
Width III 1 1.3
Ps; xe 1 1.9
Length II 4 3.2-3.9 Se02
Py III 4 3.4-3.8 3.60
x 1 3.9

Width II 4 2.0-2.7 2.43
Py III 4 2.42.7 295
xX 1 2.6

Length II 6 3.2-3.6 3.45
Mi III 3 3.7-3.8 SE 1/7
VI 1 3.8
VII 2 3.2-3.6 3.40

Width trigonid II 6 2.2-2.5 2.28
Mi III 3 2.3-2.6 DAG
VI 1 225

VIII Z D2

Width talonid iD 6 2.42.8 Z.00
Mi ITI 3 2.6-3.0 2.80
VI 1 2.8

VIII 2 2.3-2.4 238

Length I 1 3.6
Me II 5 3.5-3.8 3.62
III 4 3.9-4.1 4.03

VI 2 3.4-3.9 305

Width trigonid I 1 2.4
M, II 5 2.3-2.6 2.46
III 4 2.7-2.9 2.87

VI Z 2.3-2.6 2.45

Width talonid I 1 2.9
M2 II 5 2.6-3.1 2.88
III 4 3.0-3.1 3105

Length I 1 4.2
M; II 3 3.8-4.2 4.10
III 2 4.44.5 4.45

VI 1 4.3

Width trigonid I 1 D2
M; II 3 2.2-2.4 BOX |
III 3 2.3-2.6 2.50

Width talonid I 1 2.8
M; II 3 2.3-2.7 253
III 3 2.5-2.8 2.67

VI 1 pie

PALEONTOLOGY 41

The greater relative abundance of C. knightensis in the upper faunal zone is probably
due to the fact that the upper zone is generally more fossilferous than the lower zone.

C. knightensis is very similar to M. elegans from the lower Bridger beds, and probably
is ancestral to the latter species. M. elegans has a more molariform P, than C. knightensis
does and is slightly larger.

Cynodontomys

OHuerfanolZ
© Huer.L, IIL
O Huer WT

o Lost Cabin

*Lysite

“ a5 3,0 55) 4.0mm

Figure 8. A scatter diagram comparison of widths of trigonid and talonid of M, of Cynodon-
tomys from the Lysite, Lost Cabin and Huerfano beds.

Microsyops lundeliusi (White, 1952), New Combination
Plate IV, figure 6

MATERIAL. Locality I: AMNH 55214, YPM 16485; Locality II: AMNH nos. 17463,
17464, 17465, 17466, 17469, 17493, 55169, 55170, 55171, 55172, 55173, 55174, 55175, 55176,
55177, 55178, 55179, 55208, 55212, 55213, 55283, 55285; YPM nos. 14614, 16452, 16453,
16454, 16456, 16482, 16484; Locality III: AMNH 17468; Locality V: AMNH 17467.

Microsyops lundeliusi is represented by at least 36 specimens from localities I, II, H1
and V. All but four of these specimens are from locality II. The material includes a skull,
several partial upper dentitions and many lower jaws. The skull, AMNH 55284, is being
described elsewhere by McKenna.

White (1952, p. 191) placed this species in Cynodontomys; the type specimen, USNM
18371, lacks the fourth lower premolar. This tooth is preserved in fourteen of the Huer-
fano specimens and is more like that of Microsyops elegans than that of Cynodontomys
scottianus. In C. scottianus the metaconid of P, is rounded and low. In C. knightensis the
metaconid is similar to that of M. elegans, i.e. well developed, but the paraconid is still
present. M. lundeliusi P, has a large metaconid, well separated from the protoconid, mak-
ing the trigonid as wide as the talonid. The paraconid is lacking.

Summations (Table 12) of the widths of P, and P, suggest that sexual dimorphism was
present in M. lundeliusi. The separation of the specimens into two groups of equal size is
best explained by the presence of males and females. Presumably the males are larger
(they are usually so in primates, and Microsyops is here considered a primate). ‘The separa-
tion disappears in histograms of widths of the molars. Measurements have been listed for
lower teeth only because upper teeth are rare.

The relative abundance of M. lundeliusi at locality II is interesting. Locality II is a
rich locality; therefore it would be likely to have a plurality of the specimens of any
species of upper Huerfano mammals. The relative lack of Cynodontomys (found in approxi-
mately equal numbers at localities II and III) and the small size (relative to other C.
knightensis) of Cynodontomys at locality II indicate that the two species may have been

42 FOSSIL MAMMALIA OF THE HUERFANO FORMATION

Micros yops

OBridger CD

Ww g
al © Bridger B
* Huerfano
Tibi
o)
(aN
225 3.0 S5 4.0 4.5 5.0mm

Figure 9. A scatter diagram comparison of widths of trigonid (Wtr) and talonid (Wta!) of M, of
Microsyops from the Huerfano and Bridger formations.

competitors. The possibility exists, but is unsupportable at present, that Microsyops lunde-
liusi might have been semiaquatic or a swamp-dweller. The fossil-bearing exposures at
locality II are all within 300 yards of a channel sandstone that is at the same level. The
abundance of M. lundeliusi may be related to the proximity of a flowing stream.

The size of M. lundeliusi (see figure 12) is its most distinguishing character. That the
earliest known Microsyops should be so large is startling. M. lwndeliusi is larger than most
of the M. annectans from the upper Bridger beds. M. lundeliusi is probably not the

TABLE 12
Measurements (in Millimeters) and statistics of lower teeth of Microsyops lundeliust
Variate N OR M SD V
P; Length 9 3.5-4.6 4.14 0.38 9.18
Width ?male 5 3.3-3.6 3.44 0.13 Seis
Width ?female 4 DO Ded 2.63 0.10 3.80
Py Length 13 5.0-6.5 5.67 0.51 8.99
Width ?male 6 4,3-4.5 4.43 0.20 4.51
Width ?female 7 3.6-3.9 Seip! 0.27 7.16
Mi Length 17 4.9-6.2 5053 0.36 6.51
Width trigonid 18 3.4-4.0 Seis 0.21 5.63
Width talonid 16 3.8-4.5 4.19 0225 5.96
M2 Length 18 5.2-6.3 Seal 7 0.27 4.67
Width trigonid 18 3.5-4.2 4.01 0.24 5.99
Width talonid 19 4.1-4.7 4.53 0.17 3315
M; Length 9 5.8-7.9 6.78 0.58 8.63
Width trigonid 9 3.3-4.2 3.76 0742) 10801
Width talonid 9 3.8-4.5 4.19 0.31 7.40

PALEONTOLOGY 43

ancestor of either M. elegans or M. annectans. C. knightensis, especially the Huerfano
sample, would seem to be a proper morphological precursor of the Bridger forms. Perhaps
M. lundeliusi arose from C. scottianus. Then the genus Microsyops (as here defined) would
be polyphyletic in origin. Perhaps M. lundeliusi should be placed in a separate genus, but
I cannot recognize any morphological reason for doing this. Placing Cynodontomys in
synonymy with Microsyops would solve the semantic problem but not alter the inter-
pretation.

M. lundeliusi may be the ancestor of Craseops sylvestris, but the latter might have arisen
from M. annectans as well. The upper molars of Craseops are more specialized than those
of Microsyops (Stock, 1934).

OrpvEeR TILLODONTIA
Famity ESTHONYCHIDAE
SUBFAMILY EsTHONYCHINAE
Esthonyx acutidens (Cope, 1881)
Plate V, figure 8

Five individuals of Esthonyx acutidens have been collected from the lower faunal zone
of the Huerfano formation. Four of the specimens are very poorly preserved but one,
AMNH 17531 has the left P,-M, and right P,-M,. No. 17531 came from locality VI: the
remaining specimens are not catalogued.

SUBFAMILY TROGOSINAE
Trogosus grangert Gazin, 1953
Plate VIII, figure 2

PROBABLE SyNonyM: T. hillst Gazin, 1953

MatTERIAL. Locality I: AMNH 17008, type of T. grangert; AMNH 17009; Locality II:
AMNH 17495, YPM 16449; No locality data: USNM 17157 (Type of T. hills?).

Trogosus grangeri is probably the commonest mammal in the upper faunal zone of the
Huerfano formation; it is generally poorly preserved. Fragments of Trogosus incisors and
cheek teeth are ubiquitous and are the most useful index fossils for the upper zone because
of their large size and distinctive appearance.

Gazin’s (1953) revision of the Tillodontia placed two species of Trogosus in the upper
Huerfano faunal zone. T. grangeri and T. hillsi are based on skulls and lower jaws with
poorly preserved teeth. Gazin (1953, p. 47) noted that the two specimens might be sexual
dimorphs of one species. The two individuals might also show age differences. ‘The
basicranial differences noted by Gazin might be those of sexual dimorphism. The upper
tooth rows of the two types (AMNH 17008, T. grangeri, and USNM 17157, T. hillst) are
of similar size: AMNH 17008 P*-M®-85.0 mm, USNM 17517 P®-M*-83.8 mm (Gazin 1953, p.
46, 48).

The Huerfano Trogosus show considerable variation in individual size. The length
of the lower tooth series (P,-M; at the alveoli) varies from 89.9 mm (AMNH 17008) to 122.2
mm (YPM 16449). The coefficient of variability is large for all variates for which it has
been calculated; the variation is from 13.87-17.28. The largest sample is composed of four
specimens. In reference to the variation, the difference in size between the same teeth in
opposite jaws of the same individual is great. YPM 16449 has as much as a 12 per cent
difference in one variate and over five per cent difference in three others. If the larger
specimens of the Huerfano Trogosus represent a distinct species, it cannot be either T.
grangeri or T. hillsi since these species are described from specimens at the lower end of
the size range. The largest specimen collected from the Huerfano formation, YPM 16449,
has the peculiar crest between the entoconid and hypoconid of M, mentioned by Gazin
(1953, p. 44). This interesting morphological character found in all unworn M,’s from the
Huerfano formation, indicates a relationship between all the Huerfano Trogosus possess-
ing it and adds to the evidence in favor of a single, variable population.

Trogosus grangeri has been collected at localities I, II, III and V.

44 FOSSIL MAMMALIA OF THE HUERFANO FORMATION

TABLE. 13

Measurements (in Millimeters) of lower teeth of Trogosus grangert

Statistic AMNH nos. 17009 17008 17495 YPM 16449 V

left right
P; 1b, —= -- —- — 13.4
W —_ — 9.4
P; Ie ilsied/ 14.2 15.9 17.8 18.6 14.16
W 12.9 14.2 14.3 ibe 7 16.4 13.87
M, ILL 16.8 15/50 20.1 — 18.8
W-trigonid 1329 1529 — — 19.5
W-talonid 13.0 — — 18.1 16.7
M: L 20.0 18.2 22.0 22eS
W-trigonid 1507 15.8 17.8 20.6 19.3
W-talonid 1552 15.9 eS 19.4 18.9
Monk Sil if 28.9 38.8 38.9 39.1
W-trigonid 1578 15.6 —- Zea 18.5
W-talonid 14.1 14.9 152 20.1 17.6
W-hypoconulid 10.7 12.9 116 12.3 1253
P;-M; Lat alveoli -= 89.9 —- os Ae oD 17.14
M.-M; Lat alveoli 70.0 65.0 88.4 84.4 85.7 14.85

Note: Note the variation between right and left sides of the same individual, YPM
no. 16449.

OrverR TAENIODONTA
Famity STYLINODONTIDAE
Stylinodon sp.

Plate V, figure 1

MATERIAL. Locality II: AMNH 17451; Locality VI: AMNH 17525; Locality “South of
Hausero’s Ranch” (Collected by R. C. Hills): YPM 14616.

Three isolated Stylinodon teeth have been collected from the Huerfano formation.
The genus being represented in both faunal zones. AMNH 17451 is from a smailer animal
than the other specimens.

OrpvER EDENTATA
SUBORDER Palaeancdonta
Famity METACHEIROMYIDAE
Metacheiromys sp.

Plate I, figures 4, 5

AMNH 18666, an astragalus, from 1 mile north of Gardner Butte is referable to
Metacheiromys. The specimen is larger than YPM 13501 referred to M. tatusza by Simpson
(1931, p. 305, 356) and may be about the size of M. marsht. A row of small pits is present
under the head of the astragalus; the pits follow the rim of the condyle from one side to
the other.

Comparative measurements are:

Bridger Huerfano
M. tatusia Metacheiromys sp.
YPM 13501 AMNH 18666
Width trochlea 7.0 mm 10.0

Width head Aa] 6.4

PALEONTOLOGY 45

OrDER RODENTIA
Famity PARAMYIDAE

A. E. Wood has recently (1962) monographed the paramyid rodents including those
of the Huerfano formation. As Wood did not indicate which locality most of the specimens
came from I do so below.

SUBFAMILY PARAMYINAE
Paramys copei copei Loomis, 1907

MaTERIAL. Locality II: AMNH nos. 55118, 55124, 55127, 55128, 55134, 55195, 55198;
Locality V: AMNH 17455; Locality VI (?): AMNH 2682; Locality VII: AMNH 17546.

It is not clear from Wood’s statistical treatment (1962, p. 45, table 8) whether he has
included all the specimens from various localities in his chart. If he has, and the sample
size indicates so, then the statistical treatment is open to question. In that case samples
from widely disparate localities (Wind River, Huerfano and San Jose formations among
others) are handled as if they were part of one population.

Paramys excavatus gardneri Wood, 1962
MatTEerIAL. Locality I: AMNH nos. 17024, 55146; Locality II: 55120, 55129, 55130,
55133, 55137, 55150, 55193 (type); Locality III: Nos. 17456, 17458, 17459, 55141, 55143,
55196, 55199; Locality V: 17455, 55138, 55139; Locality VI: 17545.
Paramys huerfanensis Wood, 1962
MatTERIAL. Locality II: AMNH nos. 55114 (type), 55115; Locality III: 17025.

Leptotomus costillot Wood, 1962
MateriAL. Locality VIII: AMNH nos. 55110, 55111 (type), 55113.

Leptotomus grandis Wood, 1962

MatERIAL. Locality II: AMNH nos. 17453, 55126, 55192; Locality III: 17452, 17457;
Locality 5 of Hills: USNM 20137 (type, misprinted 10137 in Wood, 1962, p. 80); Locality
C of Hills: USNM 20135.

Leptotomus huerfanensis Wood, 1962

MateRIAL. Locality II: AMNH nos. 55121, 55125 (type), 55149.

Leptotomus parvus Wood, 1959
MATERIAL. Locality HI: AMNH 55951.

Thisbemys nini Wood, 1962

MatTERIAL. Locality II: AMNH nos. 17026, 55132; Locality III: 17023, 17454, 55937,
55197.

SUBFAMILY REITHROPARAMYINAE
Reithroparamys huerfanensis Wood, 1962

MATERIAL. Locality X: AMNH 17031 (type).

SUBFAMILY MICROPARAMYINAE
Microparamys sp. B

MATERIAL. Locality Il: AMNH 55200.

Wood used the accepted designation of early Bridgerian for the upper faunal zone of
the Huerfano formation. However, the paramyid rodents offer some of the best evidence
for considering the upper faunal zone late Wasatchian. The presence of Paramys copet
copei, Paramys excavatus and Thisbemys nini all indicate Wasatchian age. Wood (1962, p.
80) was uncertain whether Leptotomus grandis was present in the Bridger formation. Only

46 FOSSIL MAMMALIA OF THE HUERFANO FORMATION

Leptotomus parvus is definitely present in the Huerfano and Bridger formations (Wood,
1962, p. 85).

Famity SCIURAVIDAE

Several Sciuravid rodents are present in the Huerfano formation; most of them come
from the upper faunal zone. The material is currently being studied by Mary R. Dawson.

TABLE 14
Distribution of the rodents in the Huerfano formation

Species Locality iy alg ith Mig VItVV, Vio Vale TX:
Paramys

copet copet ees ee ee ek Me ee

e. gardneri D> STL ETA MOBY et SS OH tl petit

huerfanensis Actes; AED EE) Pee) Ae Bary Bee) eee es
Thisbemys

nint S55 Pi Doman We Sete at poke 23 3) ately
Leptotomus

costillot Soe Se eS

huerfanensis = ee

grandis ee et

parvus Se eee i ee ee
Reithroparamys

huerfanensis a pee os (See ee eee
Microparamys

sp. B i ee ss ee ee

OrDER CARNIVORA
Famity MESONYCHIDAE
Mesonyx obtusidens (Cope, 1872)
Plate VI, figures 3, 4

Two specimens from the upper faunal zone of the Huerfano formation are referable to
Mesonyx obtusidens. AMNH 17423, from locality III, is a jaw fragment with the canine
and P.-M, preserved; the cheek teeth are badly chipped. The length, C-M,, of AMNH
17423 is 122 mm, only 5 mm smaller than that given by Matthew (1909, p. 489) for the
species: 127 mm.

The second Huerfano specimen, AMNH 55272, from locality II, has P*-M? preserved.
AMNH 55272 is from a younger individual than the specimen figured by Matthew (1909,
p-. 494, figure 94) and has a small metacone on P*. In Matthew’s specimen, AMNH 12643,
this cusp has been obliterated by wear. The parastyle and metastyle of M’-M* of AMNH
55272 are less developed than that of AMNH 12643; therefore the upper molars are shorter
in the Huerfano specimen.

Measurements (in Millimeters) of AMNH 55272 are:

Length M! 17.0
Width M1 15.9
Length M2 13.8
Width M2 15.4

FAMILY OXYAENIDAE
Oxyaena sp. cf. O. lupina Cope, 1874
Plate V, figures 6, 7
MATERIAL. Locality VI: AMNH nos. 2683, 17557, 55265, 55298.
Four fragmentary specimens of Oxyaena have been collected from locality VI. Osborn
(1897, p. 255) described O. huerfanensis, basing the species on AMNH 2683. Denison
(1938, p. 169) placed O. huerfanensis in synonymy with O. lupina, the type species of the

PALEONTOLOGY 47

genus, and referred AMNH 17557 to O. forcipata. As Denison noted, the Huerfano
Oxyaena are larger than typical San Jose individuals of O. lupina. The four Huerfano
specimens seem to belong in a single population whose individuals were intermediate in
size between O. lupina and O. forcipata of the San Jose formation.

The Huerfano sample of Oxyaena is younger than the San Jose sample. Although the
specimens are either too poorly preserved or too fragmentary for adequate determination,
I think the Huerfano sample is closer to O. lupina.

Denison’s chart of the progressive development of M, is best when used with a larger
sample. However, the statistics trigonid width/trigonid length of M.,, talonid length/length
of M.,, and shear angle of M., are nearly the same for O. lupina and O. forcipata.

Patriofelis sp. cf. P. ulta Leidy, 1870
Plate VI, figure 2

Synonyms: P. coloradoensis Matthew, 1909, P. compressa Denison, 1938

MATERIAL. Locality III: AMNH 17017 (Type of P. compressa); “Box Canyon,” a
locality of R. C. Hills mentioned also by Osborn (1897, p. 251) but not located on any
map. YPM 16461; “Upper beds” AMNH 2691 (Type of P. coloradoensis).

Three specimens of Patriofelis sp. cf. P. ulta have been collected from the upper faunal
zone of the Huerfano formation. All of these specimens are lower jaws; two have been
made the types of species: Patriofelis coloradoensis Matthew, 1909 and P. compressa Deni-
son, 1938. The type specimen of P. coloradoensis, AMNH 2691, has badly worn teeth but
the form of the jaw is Patriofelis-like (Denison, 1938, p. 173). The type specimen of P.
compressa, AMNH 17017, is 11 per cent larger than AMNH 2691 and has slightly narrower
premolars (Denison, 1938, p. 173). The third specimen, YPM 16461, lacks teeth, but the
dentary is almost whole and resembles AMNH 17017 closely.

The type of P. ulta is a toothless jaw fragment. Enough of the jaw is preserved to show
the distinctive masseteric and temporal fossae that are characteristic of Patriofelis. P. ulta
(plastotype YPM 10070) differs from the Huerfano sample mainly in the thickness of the
jaw; P. ulta is slightly longer. If the Huerfano population is distinct it is likely to be of
only subspecific rank and Matthew’s 1909 name, P. coloradoensis, has priority.

?Patriofelis

AMNH 17427, fragments of the left maxilla, both zygomae and the sagittal crest from
locality I, is questionably referred to Patriofelis. The infraorbital foramen is unusually
close to the alveolus of the canine, Part of the apparent abnormal closeness in this speci-
men may be due to fracture of the canine alveolus. AMNH 17427 is the size of P. ulta.

Famity HYAENODONTIDAE
Sinopa sp. cf. S. strenua (Cope, 1875)
Plate VI, figures 1, 5

MATERIAL. Locality II: AMNH nos. 17421, 17422, 17431, 55211, 56501, 56506, 56510.

Eight specimens of Sinopa have been collected from locality II. The material is poorly
preserved and fragmentary. The sample from locality II resembles Tritemnodon in the
closeness of the paracone and metacone of M** but differs from it in the possession of
lingual cingula on the upper molars and in the slender proportions of the dentary.

Sinopa strenua is recorded from the Grey Bull and Lost Cabin faunas (Matthew, 1915a,
p- 76); its possible presence in the upper faunal zone of the Huerfano formation is of
little importance but does emphasize the lower Eocene affinities of that zone.

Famity MIACIDAE
SUBFAMILY VIVERRAVINAE
Didymictis sp. cf. D. protenus (Cope, 1874)
Plate VII, figures 1, 7

One specimen of Didymictis, YPM 16458 from locality VIII is referable, with doubt, to
D. protenus. YPM 16458 has parts of both jaws with right M,., and left M, preserved. It is

48 FOSSIL MAMMALIA OF THE HUERFANO FORMATION

smaller than specimens of D. altidens from the Lost Cabin (see Table 15) or Lysite
substages (Kelley and Wood, 1954, p. 349) and is close to the size of D. protenus curtidens
from the Grey Bull beds (Simpson, 1937, p. 16).

Pertinent measurements are listed in Table 15.

Didymictis altidens Cope, 1880
Plate VII, figures 3, 5
AMNH 2677, and M,., and other tooth fragments, from locality VI is referable to
D. altidens. Several other tooth fragments in the American Museum collection are prob-
ably referable to this species.
Measurements are listed in Table 15.

TABLE 15

Measurements (in Millimeters) of lower teeth of Didymictis from the Huerfano formation
and the Lost Cabin beds of the Wind River formation.

D. ?protenus D. altidens D. vancleveae
YPM AMNH AMNH
16458 4792 4793 4911 4794 2677 17424 56507
P2 Length — type — — — — 10.9 —
Width — — — — — — 4.7 —
P; Length — —_ — — — — 12.9 —
Width — — — — — — 62 —
P, Length -— — — — — — 14.4 —
Width — — — — —_ — 7:3 —
Mi Length aS — — — 15.6 13.0 18.0e 16.9
Width trigonid 6.8 — 10.1 — OFS" © #326 10.7 LS)
Width talonid 59 — — — TSP O27 8.0 Tlie
M2 Length 7.4 S45 B29 929° = 8.6 10.8 —
Width trigonid 4.7 5s On PLONO? "OL ON ei 55.6) 6.8 —
Width talonid 4.3 AOE. SOG O85) ae 4.7 6.1 —
Depth of jaw
at M2 17.4 20.5 — —_— — — 3120 —

Didymictis vancleveae new species®
Plate VII, figures 2, 4, 6

Typr. AMNH 17424, a fragment of the left jaw P.-M,; M, damaged and lacking
paraconid.

Hypopicm. Type and AMNH 17030, a skull with the muzzle missing; AMNH 17426,
tooth fragments and left M**, AMNH 56507 and M,.

Horizon AND Locatity. Upper faunal zone, Huerfano formation, South-central Colo-
rado. Specimens from localities I and X.

Dracnosis. Larger than D. altidens, one lingual cusp on trigonid of M,, jaw deep and
stout.

Discussion. Didymictis vancleveae is most easily distinguished from D. altidens by its
larger size. The metacone of M’ seems to be less reduced in referred specimens of D.
vancleveae, AMNH nos. 17030, 17426, than in a referred specimen of D. alttdens, AMNH
14750, from the Wind River formation. M’ resembles the same tooth in D. protenus.

The single lingual cusp on the trigonid of M, may be a variable character. Only the
type specimen of D. vancleveae has this tooth preserved. One specimen from the Wind
River formation here referred to D. altidens, AMNH 4911, is somewhat larger than most
D. altidens material (Table 15) and has the paraconid and metaconid quite close together,
and the anterior cingulum of AMNH 4911 is broader than normal, more nearly like

6 Named in honor of Mrs. Eleanor van Cleve of Walsenburg, Colorado, who gave very generous
support to the field work related to this study.

PALEONTOLOGY 49

D. vancleveae. The single lingual cusp of the trigonid of AMNH 17030 is directly lingual
to the protoconid. Perhaps the paraconid fused with the metaconid, AMNH 4911 repre-
senting an intermediate structural stage. The location of the lingual trigonid cusp in
D. vancleveae is intermediate to the positions of the metaconid and paraconid in D.
altidens.

Didymictis vancleveae is, perhaps, the youngest known species of Didymictis. Un-
fortunately Didymictis is rare in the Huerfano formation, but the meager sample available
indicates that the members of this genus increased in size as they evolved. The skull of
D. vancleveae must have been at least 190 mm long (estimated length, occipital condyle
to premaxilla) compared with about 155 mm for D. altidens (estimate). Giles MacIntyre
is revising the Miacidae and the description of this skull is left to him.

Viverravus gracilis Marsh, 1872
Plate V, figure 3

ProBABLE SyNonyM: V. dawkinsianus Cope, 1881

MATERIAL. Locality II: AMNH 17429; Locality III: AMNH 56505; Locality IV: YPM
16467; Locality VI: AMNH nos. 2678, 2679, 2681; Locality VII: AMNH 55210.

V. gracilis occurs in both upper and lower faunal zones of the Huerfano formation.
Wortman (1901, p. 145) included the Lost Cabin species V. dawkinsianus in V. gracilis;
Matthew (1915a) regarded the two species as doubtfuily distinct and stated that the Lost
Cabin species had smaller size. Tables 16 and 17 show that the Lost Cabin sample exceeded

TABLE 16

Measurements (in Millimeters) of lower teeth of type specimens of
Viverravus gracilis and V. dawkinsianus

Mi, M2
Py W- W- W- W-
Horizon L W L_ trigonid talonid L trigonid talonid
Bridger B
(YPM 11836)
type: V. gracilis 525 2.0 B23) Peous 2.8 40 — 2.0
Lost Cabin

(AMNH 4788)
type: V. dawkinsianus 5.1 1.9 Seow GOS pat Ab Die 2A: 2.0

the Bridger sample in the mean size and also generally the maximum size of the dental
dimensions tabulated. Moreover, the type of V. dawkinsianus exceeds the type of V.
gracilis (Table 16) in the length of its lower molars. Table 17 shows the complete overlap
of the Wind River sample by the more varied Bridger sample for molar widths, despite the
larger average size of the older forms. It also shows that the Huerfano sample coincides
with the Lost Cabin and Bridger B samples for the same parameters.

However, the Huerfano sample has individuals with a shorter P, and may represent a
distinct subspecies. No change is noted in the Huerfano specimens in time, most probably
due to the few available specimens. Viverravus is variable enough so that erection of a
new subspecies should await more material.

In the course of determining the species of Viverravus in the Huerfano formation, I
inspected all the Viverravus material in both the American and Peabody Museums. The
Huerfano specimens show that the hypocone of Mt’ is well developed in V. gracilis, where
it forms a broad cingular shelf. The same cusp is missing in V. acutus (Matthew, 1915a, p.
28, fig. 22) and the posterior lingual cingulum is absent. A heavy anterior lingual cingulum
occurs on M’ of V. gracilis, AMNH 56505, but the protocone separates it from the posterior
cingulum. The protoconal-parastylar distance is relatively greater in V. gracilis than in
V. sicarius.

50 FOSSIL MAMMALIA OF THE HUERFANO FORMATION

Viverravus sicarius Matthew, 1909
Piate V, figure 12

MATERIAL. Locality I: AMNH 56511; Locality II: AMNH nos. 17432, 56500, 56502,
56509, 56512, 56513, 56514, 56515.

Viverravus sicarius occurs at localities I and II. Both the upper and lower teeth are
known, and oddly, the upper teeth are more common. The distinguishing feature of V.
sicarius, aside from size, is the relative narrowness of the protcconal-parastylar distance of
P*, The mean size of the Huerfano sample is smaller than the dimensions of the type
specimen, AMNH 11521 from Bridger B. One Huerfano specimen, AMNH 56515, is larger
than the type. The hypocone of M?* is not as well developed in the Huerfano individuals
as it is in the type. Additional material from both the Bridger and Huerfano formations
may indicate a subspecific difference in the two populations; present data are not signifi-
cant because of the small size of the Bridger sample.

TABLE 17
Measurements (in Millimeters) and statistics of lower teeth of Viverravus gracilis
P, Length P, Width
Horizon or locality N OR M N OR M
Lost Cabin 4 5.1-5.6 5555 4 1.9-2.3 2.10
Huerfano VI 2 4.5-4.7 4.60 2 1.9 1.9
Huerfano IV — — — — — ——
Huerfano II 1 —— 4.2 1 —- ib e7
Huerfano VII — =: — -- — —
Bridger B 4 5.0-5.6 5e50 4 158=21 1.93
M; Length M, Width trigonid
Lost Cabin 5) 5.5-6.2 5.80 4 OES) 3.25
Huerfano VI 2 4.6-5.2 4.90 2 2.9-3.0 2R95
Huerfano IV fl — Sa 1 — oa2
Huerfano II 1 — 52 1 — 20
Huerfano VII 1 a Shi 1 —- 3.3
Bridger B 9 4.9-6.1 Bes) — — —
M, Width talonid M: Length
Lost Cabin 4 2.42.8 2.60 4 4.1-4.2 4.18
Huerfano VI 2, — 2S 1 — 4.0
Huerfano IV iL oe Do 1 —- 4.0
Huerfano II 1 a 1.9 — — —
Huerfano VII 1 — Bd se) il — 4.3
Bridger B 9 2.0-2.6 23 3 3.8-4.4 4.07
M; Width trigonid M: Width talonid
Horizon or locality N OR M N OR M
Lost Cabin 2 2.4-2.5 2.45 3 1.9-2.0 1.97
Huerfano VI 1 -= Df? = = =
Huerfano IV 1 — 2.3 1 — Deal
Huerfano II — — — — = =
Huerfano VII 1 ae De) 1 -- 2A0)
Bridger B 2 1.9-2.3 2:10 3 1.5-2.0 1.83

PALEONTOLOGY 5]

TABLE 18

Measurements (in Millimeters) of lower teeth of Viverravus sicarius from the
Huerfano and Bridger formations

Mi M2
Py W- W- W- W-
Locality No. EL W L_trigonid_ talonid L _trigonid talonid
Huerfano AMNH
II 17432 Vga agers 7.8 4.0 SI a —
V 55209 — 2.5 6.8 3.6 Se 4.9 2.6 28
II 56509 G: E275 7.4 Sai) 3h — ~- _
Bridger B AMNH
tL AS aaa’ a ina seo: 8.2 4.8 3.4 53 — -—
YPM
13116 —_- — (het) 4.5 3.3 — -- “=
12882 —_— — 8.7 4.7 Shel! —_ — —
* type V. sicarius.
TABLE 19

Measurements (in Millimeters) of upper teeth of Viverravus sicarius from the
Huerfano and Bridger formations

ps
AMNH L-protocone M}
Locality nos. L-buccal metastyle W L-buccal L-lingual W
Huerfano II 56512 8.0 9.4 a2 — — —-
II 56500 8.2 10.3 6.4 Sed 3.6 —
II 56502 — — — Dee Seal 8.1
II 56511 8.6 10.0 5.6 Sa 3.4 8.4e
I 56511 ors 10.7 5.6 — — 6.5e
Bridger B 1211 9.4 10.2 6.0 6rd 3.6 Sou

* type V. sicarius.

SUBFAMILY MIACINAE
Miacis sp. cf. M. parvivorus (Cope, 1872)
Plate V, figure 10

AMNH 17435, a left M’ with roots of M* and two alveoli of M°, from locality IT is close
to if not conspecific to Miacis parvivorus. The specimen differs from M. latidens of the
Lost Cabin in having the posterior margin of the tooth deeply concave. Specimens of
M. parvivorus, for example AMNH 11500 (Matthew, 1909, p. 364, fig. 15), have a similar
outline. M. latidens and M. parvivorus are of similar size.

Pertinent measurements of AMNH 17435 are: Buccal length M’, 3.0 mm; lingual
length, 2.3 mm; width, parastyle to protocone M’, 6.5 mm.

52 FOSSIL MAMMALIA OF THE HUERFANO FORMATION

Uintacyon sp. cf. U. asodes Gazin, 1952
Plate V, figure 4

A fragment of the right jaw of Uintacyon from locality Il, AMNH 17434, with P,-M,
preserved, seems close to U. asodes as far as may be determined from comparison of the
photograph (Gazin, 1952, plate 6) of the damaged type specimen, USNM 19351. Measure-
ments of the two specimens, listed below, show their similarity in size, the main criteria
for association.

Width Width
Length P, Width P, Length M,; ttrigonid talonid M,

USNM 19351 (from Gazin) 6.1mm 823 ES 515 —
AMNH 17434 6.4 239 7.3 4.6 oul

Oddectes herpestoides Wortman, 1901
Plate V, figure 11

Two specimens referable to Oddectes herpestoides Wortman have been collected in the
upper faunal zone: one specimen, AMNH 55289, is from locality I; the other, AMNH
56504, a maxilla fragment with parts of P*-M? is from locality III. Both show great resem-
blance to O. proximus Matthew as well as to O. herpestoides Wortman and it is likely that
the two species are synonymous. O. herpestoides has priority. O. pugnax (Wortman and
Matthew) may also be a synonym, and it has priority over both of the above names.
However, the type of O. pugnax is a lower jaw, and direct comparison with the Huerfano
specimens is not possible. Giles MacIntyre is currently revising the Miacidae and will
resolve the problem of synonymy in Oddectes.

The Huerfano specimens are somewhat larger than the type specimen of Oddectes
herpestoides but not enough to warrant specific separation. Pertinent measurements are
listed in Table 20.

TABLE 20

Measurements (in Millimeters) of upper teeth of Oéddectes from the Huerfano and
Bridger formations

M:

No. ps re Lingual Anterior
AMNH J W 1G; W Buccal c W

55289 — — — — 3.4 es Si 7/

56504 4.5 225 5.4 4.3 — —_ Sse!

11495 — — 4.6 Se 7 3-1 23 Sa)

type of O. proximus from Bridger B
YPM
11861 — — 4.2 4.0 S)eil 2.0 Dez

type of O. herpestoides from Bridger B

?Oddectes
Plate V, figure 9

AMNH 2681 from the lower faunal zone (locality VI?) is a jaw fragment with P,-M,
preserved. Alveoli for Canine, P, (one), P; (two) and the roots of P, are present. Two
mental foramina lie below the alveolus of P, and the anterior alveolus of P;. The tips of
the protoconids of P, and M, and the talonid rim of M, are lost. The M, is peculiar in that
it is smaller than the M, but is not as small as is usual in Miacidae. The metaconid and
paraconid of M, are low and of equal size; the protoconid is tall. The paraconid and
metaconid are not as close together as in Oddecies, the only miacid that closely resembles
this specimen. This specimen may be an insectivore, but it is unlike any known to me.

PALEONTOLOGY 53

The miacid-like M, argues against any insectivore relationship. The smaller M, is unlike
the hyaenodonts.

Measurements (in Millimeters) of AMNH 2681

P, Mi M.
Length 3.0 Sal) 3.6
Maximum Width 2A 300 2e3

Vulpavus asius Gazin, 1952
Plate V, figure 2

Two specimens, AMNH nos. 56503 and 56508, referable to Vulpavus asius have been
collected at locality II. Both are jaw fragments with M, preserved, in which the paraconid
lies close to the metaconid, as noted by Gazin (1952, p. 58, plate 5), for M, and also
illustrated in his photograph of the type M,. The lengths of the two teeth are: AMNH
56503, 5.0 mm; 56508, 5.6 mm.

The proximity of the paraconid and the metaconid is not usual in Vulpavus. Most
American Museum specimens of early Eocene Vulpavus show the paraconid of M, placed
more centrally. One specimen, AMNH 16954 from Dorsey Creek in the Bighorn Basin,
has the paraconid shifted to the position in V. asius, showing that the condition existed
in some pre-Lostcabinian Vulpavus.

OrDER CONDYLARTHRA
Famity PHENACODONTIDAE
Phenacodus vortmant (Cope, 1882)
Plate X, figure 6

MATERIAL. Locality VI: AMNH nos. 17547, 55229, 55278, 55279, 55280, 55276. Locality
IX: AMNH nos. 55230, 56532. AMNH 17548 from locality VI is questionably referred to
P. vortmani.

Nine specimens, all fragments of lower jaws, from localities VI and IX are referred to
Phenacodus. The specimens possessing a P, agree well with the type of P. vortmani
AMNH 4824, also a P,. The measurements of the type are:

Length: 8.1mm Width: 5.5 mm

In most measurements the coefficient of variability is low, but for the measurements

of M, it is unusually high. This is due to the inclusion of one specimen, AMNH 17548.

The pertinent statistics are:

A: AMNH 17548 included: N OR M SD V

Length M; 5 7.8-10.1 8.66 0.94 10.85
Width trigonid 5 Sect a) 6.12 0.85 13.89
Width talonid 5 4.6-6.8 5.36 0.93 1) fs

B: AMNH No. 17548 excluded:

Length 4 7.8-8.8 8.30 0.58 6.99
Width trigonid 4 Se 4 5.78 0.40 6.92
Width talonid 4 4.6-5.8 5.00 0.54 10.80

Omitting AMNH 17548, the coefficient of variability for the talonid width of M, is
still high in set B but is of more reasonable value. The sample is admittedly small, and
the high coefficient of variability may be due to this, but the data suggest that the sample
of M,’s is heterogeneous. AMNH 17548 may be referable to either P. copei or P. intermedius
(Granger, 1915, p. 333) on size characters. Since the specimen has only the third molar, it
seems best to consider it P.? vortmani. The lack of other large Phenacodus specimens may
be significant.

Comparison of the statistics of the Huerfano and Wind River samples of P. vortmani

54 FOSSIL MAMMALIA OF THE HUERFANO FORMATION

(see Table 21) shows that in most parameters the Huerfano animals averaged smaller. The
Wind River sample used is small (three specimens: AMNH nos. 4824, the type, 17487, and
14801), and the Huerfano sample is not much larger. The evidence is insufficient to
establish the Huerfano population a subspecies of P. vortmani until the genus Phenacodus
is reviewed and possible synonymy determined. The Wind River specimens used in the
above comparison are the smallest Phenacodus from the Lost Cabin fauna at the American
Museum of Natural History. P. brachypternus, the only smaller species of Phenacodus, is
restricted to the lower part of the early Eocene (Grey Bull and Almagre faunas, Granger,
1915, p. 345).

TABLE 21

Measurements (in Millimeters) of lower teeth of Phenacodus vortmani from the
Lost Cabin levels of the Huerfano and Wind River formations

Huerfano Wind River
Variate N OR M SD V N OR M
P; Length 1 — 6.9 a = 2° 13h “T2359
Width 1 — 4.1 — — 2 — 4.5
Py Length 3. 7.7-8.0 8.00 — — 3 179-=8-4 5 Sede
Width 3 Dil=SOy OLE — — 3. 5.4-5.6 S50
M, Length Saal Hho Olek eS — = 3. ld=lawiaee
Width trigonid 4 6.2-6.6 6.35 0.19 3.00 2 — 6.9
Width talonid 2 — 6.4 —_ o 1 _- 6.9
M. Length So Sale MeO) BOnlor ats 2. 7.8=8.0, ) 4296
Width tagonid, 55 9674-698, 6.62)" (0-18 2272 2. TART SY eee
Width talonid 3). 8O.1=626; AO9327 ORI9. 3,01 2) = 1 0-1 AS
M; Length 4 7.88.8 8.30 0.58 6.99 2. 1.89.52 4598-56
Width trigonid 4 5.3-6.2 5.78 0.40 6.92 2- §.8-655.7 1695
Width talonid 4 4.65.8 5.00 0.54 10.80 2 5-1-Se6e55ec0

Famity HYOPSODONTIDAE
Genus HYOPSODUS Leidy, 1870

Hyopsodus, although, or because, it is the commonest lower and middle Eocene
mammal, is a systematist’s nightmare. The latest revision of the genus is found in Matthew
(1909 and 1915b). Since Hyopsodus is common, statistical treatment of the genus should
be more valid than for other less common beasts. Olson and Miller (1958) did not segre-
gate their Bridger specimens by individual localities, instead they segregated samples from
the two faunal levels (Matthew, 1909). Gazin (oral communication) believes that Matthew’s
determination of the stratigraphy of the Bridger formation is open to reevaluation, and
for this reason Olson’s and Miller’s conclusions are open to reevaluation. Kelley and
Wood (1954) examined the Hyopsodus from the Lysite member of the Wind River
formation and were able to show that three populations probably existed in that fauna:
H. minor, H. mentalis and H. powellianus. Kelley and Wood measured the maximum
width of M, and M.. In these teeth the maximum width may be either on the trigonid
or the talonid; a summation of maximum widths therefore is the summation of part of
the sample of two variables and is less useful. The maximum width of M, is always across
the trigonid.

The samples from the Lost Cabin member of the Wind River formation indicate that
three populations exist: these are: H. wortmani, the small animals, and H. walcottianus
and perhaps H. mentalis, the larger animals (Matthew, 1915b).

Two populations seem to be present in each level of the Huerfano formation. In the
lower level the equation of these samples with samples from the Lost Cabin member of the
Wind River formation is practical. The upper zone samples are harder to allocate.

The Garcia Canyon local fauna sample from the Huerfano formation is assigned to
H. wortmani and H. walcottianus.

PALEONTOLOGY 55

Frequency distributions of measurements of the trigonids of molars of Hyopsodus are
from the following levels: Lysite-Bighorn and Wind River basins; Lost Cabin-Wind River
and Huerfano basins, Gardner Butte-Huerfano basin; Black’s Fork Bridger Basin. These
distributions indicate that the populations of each level in each basin are distinct. The
closest similarity between population samples is between the Lost Cabin levels of the
Wind River and Huerfano basins. I have not examined the samples from the Largo and
Almagre levels of the San Jose formation, or from the Grey Bull level of the Willwood
formation. Although the number of named species of Hyopsodus is too great, each popula-
tion in each fauna probably deserves subspecific rank. H. mentalis was based on a specimen
from the San Jose formation. Referring samples from Wyoming to this species is probably
valid, but, until the variation of the San Jose sample is known, it is risky.

Determining the species of Hyopsodus on morphological differences is, at the present
time, impractical; the animals are variable. Olson and Miller’s treatment is invalidated
due to the lack of locality association (see above). My own analysis indicates only one
variable (in terms of topography of the tooth) population in the lower Bridger. The
sample from Grizzly Buttes (Bridger B) has low coefficients of variability for the parameters
used.

Hyopsodus wortmani Osborn, 1902
Plate X, figure 5

MATERIAL. Locality I: AMNH nos. 17029, 55253, YPM 16412; Locality IZ: AMNH nos.
Wists, 11219, 55256;-56521, 55237, 55233, 55240, 55236, 55258; 55232, 55239) 55234,°55235,
56518, 56519; Locality III: AMNH nos. 55245, 55244, 56520, 17476; Locality V: AMNH
nos. 55241, 55243, 55242; Locality VI: AMNH nos. 16907, 17452, 55255; Locality VIII:
AMNH 55257; Locality VIIIa: AMNH 55260.

Hyopsodus wortmani is present in both faunal levels of the Huerfano formation. The
sample from the upper faunal zone is composed of slightly smaller individuals than those
of the lower zone sample (Tables 25, 26). This may be related to the presence of H. paulus
in the upper zone. H. paulus, though larger than H. wortmani, is much smaller than
H. walcottianus from the lower zone. The small individuals of H. wortmani in the upper
zone may reflect the competition with a small related species of similar habit.

The sample of small Hyopsodus from the Lost Cabin level of the Wind River forma-
tion is bimodal (see Tables 22, 23, 24, frequency distributions of trigonid widths). Where
measurements are restricted to specimens from one locality in other formations the
separation of groups is sharp. Grouping the specimens from the Lost Cabin level of the
Wind River formation according to locality might resolve this, but it cannot be done now.
The smallest group in the Lost Cabin (Wind River) sample is H. wortmani. The sample
with which it intergrades in size may be H. mentalis. H. walcottianus is the large species
present. The statistics on the two smaller samples have been calculated together because
I have no way of separating them at this time. This explains the high coefficients of
variability.

Hyopsodus paulus Leidy, 1870
Plate X, figure 9

Two specimens, YPM 16435 from locality III and YPM 16486 from locality II are
referable to H. paulus. Both specimens are isolated lower molars and add nothing to our
knowledge of the species except its distribution.

Hyopsodus walcottianus Matthew, 1915
Plate X, figure 7

MATERIAL. Locality IV: AMNH nos. 17534, 17537, 17540, 17541, 55247, 55249, 55250,
55251, 55254, YPM nos. 16446, 16469, 16470; Locality VI: AMNH nos. 17535, 17536, 17538,
16906, 16905, 55259, YPM 16447.

W. walcottianus occurs at localities IV and VI, abundantly at the former. The range
of size of the Huerfano specimens overlaps the size range of the H. powellianus popula-

56 FOSSIL MAMMALIA OF THE HUERFANO FORMATION

tion from the Lysite fauna of the Willwood formation. The H. walcottianus sample from
the Wind River Lost Cabin consists of three specimens whose size range is almost the
same as that of the Huerfano sample (see Table 26). The Huerfano, Garcia Canyon, and
the Wind River, Lost Cabin, samples are obviously related and both show relationship
to the Willwood Lysite sample. Possibly H. walcottianus is a temporal subspecies of H.
powellianus, but actual designation of it as such awaits a revision of the genus Hyopsodus.

The relative abundance of H. walcottianus at locality IV and the absence of H.
wortmani from that locality is further evidence for the unique nature of Locality IV and
the Farisita formation in general.

TABLE 22

Frequency distribution of widths of trigonids of M, of Hyopsodus from Lysite, Lost Cabin,
Gardner Butte and Blacks Fork faunal levels

Willwood Wind River Huerfano Gardner Bridger

Width Lysite Lysite Lost Cabin Lost Cabin Butte Blacks Fork*

2.0 mm 1

Des

Den 1 1

Dye 2 1 2

2.4 2 3 1

259 2 5

2.6 3 1 2

oRSy| 3 4

2.8 2 4 + 6

DAO 3 3 1 13

3.0 2 2 8 26

Saul 1 2 18

S22 1 2 3

Sind 1 2 3

3.4 1 3 1

3.5 1 + 1

3.6 8 1

Sal, 3

3.8 3 1 2

3.9 3 3 1

4.0 4 1 yy

4.1 2 1 1

4.2 3 1 1

4.3 2 1

4.4 2 5

4.5 2 3

* All specimens from Grizzly Buttes.

PALEONTOLOGY 57

TABLE, 23
Frequency distribution of widths of trigonids of Mz of Hyopsodus
Willwood Wind River Huerfano Gardner Bridger
Lysite Lysite Lost Cabin Lost Cabin Butte Blacks Fork*
2.4mm 1 1
2-5
230 3
af 1 2 4
2.8 1 1 9
2.9 1 2 2,
3.0 1 3 3 1
Sol 1 7
3.2 3) 3 1 1 1
323 3 3 4 1 6
3.4 3 3 1 15
3:5 4 3 1 21
3.6 1 3 15
Siar 1 DZ 1 11
328 1 1
3.9 1 2
4.0 6 1 1
4.1 1 7
4.2 6 1
4.3 2 2
4.4 1 5 1
4.5 1 1 1
4.6 2 1 1
4.7 5 1 2
4.8 1 1 3
4.9 3 2.
5.0 1 4
Sea 2 1
a2 1 Z
SEG) 1
5.4
Sas) 1

* All specimens from Grizzly Buttes.

58 FOSSIL MAMMALIA OF THE HUERFANO FORMATION

TABLE 24
Frequency distributions of widths of trigonids of M; of Hyopsodus
Willwood Wind River Huerfano Gardner Bridger
Lysite Lysite Lost Cabin Lost Cabin Butte Blacks Fork*
2.2 mm 1
Des 2
2.4 2
2.5 1 4
2.6 2 4
Pal 1 1 3 1
2.8 2 3 1
2.9 3 3 2 2
3.0 1 7 2 1 4
one 4 2 15
g.2 2 2 4 19
303 4 15
3.4 11
Bye) 1 1 4
3.6 7 2
edh 5 1
3.8 4 il
3.9 2 2
4.0 3 3 1
4.1 1 2
4.2 1 2 1 2
4.3 2
4.4 2 1
4.5 2
4.6 2
4.7 1
4.8
4.9
5.0 1
She 1

* All specimens from Grizzly Buttes.

Measurements (in Millimeters) of trigonid widths of molars of small species of
Hyopsodus, excluding H. minor, from several faunas

Fauna

Lysite
Lysite
Lost Cabin
Lost Cabin

Gardner Butte

Blacks Fork

Lysite
Lysite
Lost Cabin
Lost Cabin

Gardner Butte

Blacks Fork

Lysite
Lysite
Lost Cabin
Lost Cabin

Gardner Butte

Blacks Fork

PALEONTOLOGY

Formation

Willwood
Wind River
Wind River
Huerfano
Huerfano
Bridger
AMNH
YPM

Willwood
Wind River
Wind River
Huerfano
Huerfano
Bridger
AMNH
YPM

Willwood
Wind River
Wind River
Huerfano
Huerfano
Bridger
AMNH
YPM

TABLE 25

W
w
NN DS WW

ra
oo
WW

RPnow.s AnuUHN

COmMnmN

wow

Mz

bo dS bd bd bd
le)
nN

WwW
So
paar

59

60 FOSSIL MAMMALIA OF THE HUERFANO FORMATION

TABLE 26

Measurements (in Millimeters) and statistics of trigonid widths of molars of
large species of Hyopsodus

Fauna Formation N OR M S V
Mi
Lysite Willwood 16 3.9-4.4 4.12 0.14 3.40
Lysite Wind River 27 3.3-4.2 3.66 0.49 13.39
Lost Cabin Wind River 3 4.0-4.5 4.33 — —
Lost Cabin Huerfano 7 3.6-4.5 4.19 0.26 6221
M;:
Lysite Willwood 19 4.1-5.1 4.68 0.35 7.48
Lysite Wind River Si 3.9-4.7 4.20 0.49 11.69
Lost Cabin Wind River 3 4.8-5.3 SS il7/ — —
Lost Cabin Huerfano 19 4.2-5.3 4.85 0.23 4.74
M;
Lysite Willwood 9 3.9-4.4 4.10 0.19 4.63
Lysite Wind River 25 3.6-4.2 3.81 0.52 13464
Lost Cabin Wind River 3 4.2-5.1 4.63 — —
Lost Cabin Huerfano 11 4.0-5.0 4.42 0.23 520

OrpvER DINOCERATA
Famity UINTATHERIIDAE
Bathyopsts sp. cf. B. fissidens (Cope, 1881)
Plate I, figure 6

Bathyopsts sp. cf. B. fissidens occurs at locality III and probably at locality I. AMNH
17438, a left P, (not ?P,; or P,, Wheeler, 1961) from locality III agrees well with the type
AMNH 4820. AMNH 17444, skeletal fragments of a uintathere, from locality I may pertain
to B. fissidens; the astragalus is smaller and less specialized than that of Uintatherium. No
uintathere remains have been found in the lower faunal zone.

Measurements (in Millimeters) of AMNH 17438 are:
Length Width trigonid Width talonid
14.8 8.9 8.4

OrpdER PANTODONTA
FaMity CORYPHODONTIDAE
Coryphodon sp.

Plate I, figure 8

Numerous fragmentary specimens of Coryphodon occur in the lower faunal zone, and
one specimen, AMNH 56543, a left P,, was collected at locality II. The specimens now
prepared are too fragmentary for specific identification. Better material and a revision of
the genus Coryphodon will be necessary before accurate determinations can be made.

Specimens of this genus occur at localities VI, VIII, VIIa, IX and an isolated specimen,
YPM field no. 59-12, was collected in exposures about 14 mile west of locality IV. AMNH
nos. 2690 and 17556 are the only catalogued specimens from the lower faunal zone.

The Coryphodon specimen from the upper faunal zone may be the youngest record of
the genus in North America.

PALEONTOLOGY 61

OrDER PERISSODACTYLA
FAMILY EQUIDAE
Hyracotherium craspedotum (Cope, 1880)
Plate IV, figure 3

MATERIAL. (K) = Kitts’ sample: Locality VI: AMNH nos. 17509(K), 17510(K), 17513(K),
17521, 55100(K); Locality IX: AMNH nos. 56530, 56532.

The sample of horses used in this study differs from Kitts’ (1956) sample for several
reasons: Kitts included material from Locality VIII (Costillo Pocket) in his study, and
did not include, in most cases, material from the upper faunal zone. Also, I have the
advantage of having material collected since Kitts’ study was completed. Kitts omitted
several specimens with numbers of the 2,000 series (collected in 1897) and the 17,000 series
(collected in 1916, 1918) from his studies. Differences in data between Kitts’ sample and
mine arise from using some different individuals.

TABLE 27

Measurements (in Millimeters) of lower teeth of Hyracotherium craspedotum
and H. vasacciense from the Huerfano and Farisita formations:

Variate Locality N OR M SD V Species
M, Length TY SEV, A 2-756 7.40 — — H. vasacciense
VI 9 6.48.4 1232 00..68y 9.29 fe
IV 2 7.8-9.0 8.40 — = 2
Vi, Xs 4 8.8-9.6 9.20 — — 4H. craspedotum
Width trigonid II, III, V. 4 5.2-5.3 5.28 — ——
VI 9 4.5-5.9 5.04, 0.50, 5.85
IV 2 5.6-6.1 5.85 —
VIE IX 4 6.2-6.5 6.40 — -—
Width talonid II, III, V. 4 5.2-5.5 5.335 ——
VI 10 4.6-6.2 2 nad) 28. OD
IV 2 5.8-6.5 6.15 —
Vi; 1x 4 6.5-6.7 6.58 — —
M: Length 116 (yd 11) Gee Ve P07 ASI sd 7.61
VI 10 7.1-8.5 7.61 0.54 7.06
IV 3 8.1-9.2 8.65
VI, IX 6 9.7-10.4 10.01 — as
Width trigonid II, III, V. 7 4.9-5.8 5.49 —
VI 11 5.06.3 S257, 10,48 8.53
IV 3 6.0-6.5 6.17 —
Vi, ix 6 6.6-7.3 7.02 — —-
Width talonid II, III,V. 7 5.0-5.8 5.44 —
VI tly. 457-636 5.65 0.61 10.80
IV 3 5.8-6.8 6.30
VI, IX ind Oo 6.90 — —
M; Length II, II, V. 7 10.0-11.8 10.830 —
VI 10 9.7-11.1 10.40 0.50 4.80
IV 2? 1213.52" 912620 —
Vin ix 3 13.8-14.0 13.93 — —
Width trigonid II, III, V. 7 4.8-5.8 5.37 — —
VI 9 4.9-6.0 5,52 (0:34 “6.14
IV 2 6.1-6.3 6.200 — —
Vir tx 3h 720-73 7.170 — —-
Width talonid II, III, V. 7 4.5-5.6 5.07 — a=
VI 10 4.4-5.5 5.05 0.45 8.91
IV Zin S9=6.1 6.00 —
VinelxX 3 6.6-6.8 6.70 — —

62 FOSSIL MAMMALIA OF THE HUERFANO FORMATION

Hyracotherium vasacciense (Cope, 1872)
Plate IV, figures 4, 5, 7

MATERIAL. Lower faunal zone: Huerfano facies. (K) = referred by Kitts. H. v. vasac-
ciense. Locality VI: AMNH nos. 2586, 17511(K), 17512(K), 17514(K), 17575(K), 17516(K),
17517(K), 17518(K), 17520(K), 55103(K), 55104(K), 55105(K), 55277, YPM 16455; Locality
VIII: Kitts referred AMNH 55101, these specimens have not been studied other than to
note the presence of this species in the quarry sample. Locality IX: AMNH 56531. Upper
faunal zone: Huerfano facies. Locality I: AMNH 56529; Locality II: AMNH nos. 17446,
17447(K), 17449, 55180, 55181, 55183, YPM nos. 16479, 16481; Locality III: AMNH nos.
17021, 17448(K); Locality V: YPM nos. 16440, 16448. Upper faunal zone: Farisita facies, Y
mile east of Gardner Butte: AMNH 55185. H. v. (?) venticolum. Lower faunal zone,
Farisita facies: Locality IV: AMNH nos. 17522, 55107, 56533, YPM 16436.

Hyracotherium vasacciense is present at localities I, II, III, IV, V, VI, VIII and IX and
therefore occurs in both faunal levels. Horses are scarcer in the upper faunal zone, but
those present closely resemble the lower zone sample. Probably through unfamiliarity with
the Huerfano localities, Kitts (1956, p. 46) included two specimens, AMNH nos. 17447 and
17448, from the upper faunal zone in his analysis of the lower zone sample.

TABLE 28

Frequency distributions of talonid widths of Ms; of Hyracotherium
from the Huerfano formation

Width (in Locality
Millimeters) VI, IX IV TL Tia
4.4 1
4.5 1
4.6
Aa 2
4.8 2 1
4.9 1
5.0 1
Sat 1
4 1 H. vasacciense vasacciense
aS 1
Sac! 1
55) 3 1
556 1
Sees
5.8
5.9
6.0
6.1 1 WH. vasacciense ?venticolum
Gn2
6.3 1
1

1 H. craspedotum

CONT DN Ue

PALEONTOLOGY 63

Kitts placed the smaller Huerfano hyracothere in the subspecies H. vasacciense
vasacciense on size criteria and the morphology of P*. He stated that the smaller horses
were easily separable from the larger (H. craspedotum) on the basis of size; I found this
true for most molar measurements, but I found some overlap in talonid widths of M,
(see Table 28).

Twinning of the metaconid in molars, noted by Kitts (1956, p. 12) is common in
Huerfano specimens of H. vasacciense. ‘Twinned metaconids are also present on DP,., of
AMNH 55185.

Without premolars for comparison, it is almost impossible to distinguish between the
lower jaws of some smaller horses from Bridger, Huerfano and Wind River formations.
Kitts (1957, p. 5) cites the shorter heel of M; as a basis for separation of Orohippus and
Hyracotherium, but some specimens of M, from these formations are indistinguishable.

New data on tooth replacement of Hyracotherium is provided by AMNH 55185. The
specimen consists of both jaws, several upper teeth and numerous skeletal fragments. The
right jaw has DP,_, and M,-;, M; not fully erupted. M, was in the process of eruption prior
to the shedding of DP, , or .. AMNH 55185 is from low in the upper faunal zone, col-
lected about 14 mile east of Gardner Butte (Farisita facies).

Four specimens of horses from locality IV (Farisita facies) are questionably assigned to
H. vasacciense venticolum. They are large for H. v. vasacciense and small for H. craspe-
dotum. These are the only horse specimens collected from locality IV and their presence
suggests that, if they are correctly assigned to subspecies, H. v. vasacciense and H. v. ventt-
colum occupied different habitats in the same basin. AMNH 55185, mentioned above,
also comes from the Farisita facies and is one of the smallest horses collected. It is, how-
ever, from several hundred feet higher in the upper faunal zone beds. If the locality IV
horses are H. v. venticolum, then the known distribution of this subspecies is extended
from the Wind River and Debeque formations to include the Farisita formation.

The measurements of teeth of specimens of H. v. vasacciense from locality VI have
bimodal distribution (see Table 28), best shown in talonid widths of M,. Because the
number of specimens in each group is about equal, I suggest that the difference is due
to sexual dimorphism. The sample from the upper faunal zone is not sufficient to show
this grouping.

FAMILY BRONTOTHERIIDAE

SUBFAMILY LAMBDOTHERIINAE
Lambdotherium popoagicum (Cope, 1880)
Plate IX, figure 4

MATERIAL. Locality IV: AMNH nos. 17530, 56534, YPM 16466; Locality VI: AMNH
nos. 2688, 17526, 17527, 17528, 56535, 56536, 56537, 56541; Locality VIIIa: AMNH nos.
55264, 55263, 56538.

Bonillas (1936, p. 141) placed all other described species of Lambdotherium in
synonymy with L. popoagicum. The type specimen of L. magnum (Osborn), AMNH 17527,
comes from locality VI of the Huerfano formation. Although that specimen is the largest
lambdothere in the American Museum or the Peabody Museum collections, it is within
the probable range of variability for the species L. popoagicum.

Most of the specimens of Lambdotherium from the Huerfano formation are jaw
fragments. Statistics of measurements of lower teeth for both the Huerfano and Wind
River specimens in the American Museum are listed in Table 29. The Huerfano sample
of Lambdotherium resembles its counterpart in the Wind River formation more than
any other pair of mammalian samples from these formations.

64 FOSSIL MAMMALIA OF THE HUERFANO FORMATION

TABLE 29

Measurements (in Millimeters) of lower teeth of Lambdotherium popoagicum from the
Lost Cabin levels of the Huerfano and Wind River formations

Variate Formation N OR M SD V
P, I, Huerfano 7 7.3-8.4 7.85 —— —
Wind River 4. 7.5-8.0 PE 0.21 Pegi
P; W Huerfano 2 4.1-5.0 4.65 — —
Wind River 4 4.1-4.7 4.43 0.28 6.33
Ps Ec Huerfano 4 8.4-9.7 8.90 0.59 6.63
Wind River 10 8 .3-9.4 8.99 0.31 3.45
Ps W Huerfano 4 5.46.3 5.85 0.47 8.03
Wind River 10 5.3-6.6 5.82 0.46 7.90
P, 1 Huerfano 6 8.7-10.0 9.37 0.35 Sieh
Wind River 9 9.1-10.1 9.43 0.25 2.65
P, W trigonid Huerfano 6 6.3-7.2 6.72 0533 4.91
Wind River 9 6.3-7.3 6.76 O53 4.59
P, W talonid Huerfano 6 6.5-7.5 7.02 0.33 4.70
Wind River 9 6.6-7.7 7.04 0.44 6.25
Mi 16 Huerfano A AO S7—12705 sil 23 0.40 3.50
Wind River 10 10.0-11.8 10.99 0.61 5255
Mi W trigonid Huerfano 5 7.2-8.2 7.84 0.38 4.85
Wind River 10 6.9-8.5 TSH 0.35 4.56
M, W talonid Huerfano 5 7.5-8.7 8.12 0.55 6.77
Wind River 10 7.3-8.5 1.95 0.37 4.65
M: IF Huerfano AS AL 7-120 12ets O. 5 4.19
Wind River OFF TD A0S12 65 alles 0.33 2.68
Me W trigonid Huerfano + 8.6-9.6 OAS 0.44 4.81
Wind River 10 7.8-9.5 8.81 0.38 4.31
M: W talonid Huerfano 6 7.5-9.6 8.85 0.76 8.59
Wind River 9 8.2-9.5 8.89 0.41 4.61
M; 1 Huerfano 8 15.418.5 16.79 1.13 6.73
Wind River 7 15.8-17.8 16.99 0.68 4.00
M; W trigonid Huerfano 9 8.2-10.1 8.94 0.63 1205
Wind River if 8 .3-9.6 9.03 0.43 4.76
M; W talonid Huerfano 7 7.0-9.5 8.18 0.79 9.66
Wind River 8 7.5-9.2 8.23 On55 6.69
Mjes ae Huerfano De AIO -4A4S 42/275 a= ——
Wind River 8 37.1-42.2 40.09 1.74 4.34

SUBFAMILY PALAEOSYOPSINAE
Palaeosyops fontinalis (Cope, 1882)
Plate I, figure 9, Plate VIII, figure 1, Plate IX, figures 1, 3

SyNonyM: Eometarhinus huerfanensts Osborn, 1919

MATERIAL. Locality I: AMNH nos. 17450, 17013, 17416, 56540, 17411, 17412, YPM
16462; Locality II: AMNH nos. 17417, 17425, YPM 16450; Locality V: AMNH nos.
55282, 17415, 17413, 17474; Locality No. 5 of R. C. Hills: YPM 16463; 1 mile south of
Hausero’s (Collected by R. C. Hills): YPM 16451; 1 mile a little southeast of Gardner
Butte: YPM 16459.

The type specimen of P. fontinalis is a partial skull of a young animal with DP*-M*.
Another juvenile specimen, YPM 16451, has DP**, M*, and DP,,, and is the only
specimen of this species, known to me, that has lower and upper teeth associated. An
excellent upper dentition, YPM 16450, consisting of left C-M* and right P’-M?, was col-
lected by Peter Hilgeford in 1958. Partial lower dentitions are commoner, but none are

PALEONTOLOGY 65

well preserved. No lower dentition with both deciduous and permanent teeth is known to
me. Therefore, lower jaws are referred to this species on size criteria and without com-
parison to YPM 16451.

The inclusion of Eometarhinus huerfanensis in P. fontinalis is based on comparison
of the type of E. huerfanensis, AMNH 17412, with skulls of other palaeosyopsines.
Osborn’s reconstruction of the skull (1929, fig. 355) is, I think, misleading. The orientation
of the nasals is speculative since no true contact remains. Restoration of the nasal posi-
tion can be made to agree as well with palaeosyopsines such as AMNH 5104, type of
Limnohyops laevidens, or with the type of P. fontinalis, AMNH 5107. The latter has
very strongly arched nasals for a young animal. The nasal bones of palaeosyopsines are
thin; they might have curved in dessication following death, as some bones do. The
teeth of AMNH 17412 are poorly preserved but agree in outline and size with AMNH
17411 and YPM 16450. The maxilla and premaxilla of AMNH 17412 resemble AMNH
5104 closely. The apparently high maxillonasal contact is partly due to crushing. The
“horn bosses” mentioned by Osborn (1929, p. 420) are apparently misinterpretations
of the nasofrontal suture. No evidence for a hypocone on M, exists as that portion of
the tooth is absent.

Future restudy of the Palaeosyopsinae will probably reduce the number of species and,
perhaps, genera. P. fontinalis may eventually be considered a subspecies of P. paludosus,
but it seems best to let the species stand until such time as detailed studies reveal its posi-
tion.

Measurements of teeth of P. fontinalis from the Huerfano formation are given in
Tables 30, 31.

TABLE 30

Measurements (in Millimeters) of lower teeth of Palaeosyops fontinalis
from the Huerfano formation

AMNH nos. YPM nos.
Variate 17450 17417 17013 17416 55282 56540 16459 16463
Po, & —— — — — — —- 16.2 --
W — —_ — — — —- 9.1 —
Py ©L — ~- a -- 16.4 16.4 1527 =
W -— = — 9.6 8.8 9.2 --
ay ey — — -- ISSO ehiay, — 15.8 --
W trigonid — — - 10:2 1046 — ORS) —
W talonid — —_— -- 10.7 -- -— a =
Mi, -- — 20.5 — 20.6 — — ~-
W trigonid — — 1245 -= 13.6 — a Sil, —
W talonid —- -- ilejeul — 1303 — 14.3 --
M: L -- DS ie tas iear — ~- —- 28.5 =
W trigonid — 16527) 16.0 — — — aye. —
W talonid oa Vip S16)..6 — 16.5 — — —_—
M, L = a — — — — — 39.7
W trigonid — a -= -- 18.0 — ~- 19.1
W talonid 16.5 -- -= -— 16.4 ~- -- 18.4

Genus EOTITANOPS Osborn, 1907

Eotitanops first occurs a few hundred feet above Lambdotherium in both the Wind
River and Huerfano formations. The species first described, E. borealis (Cope), is from
the Lost Cabin level of the Wind River formation. Analysis of the Eotitanops material in
the American Museum indicates that one population of this genus existed in upper Lost
Cabin time in the Wind River basin. This species, for which the name E. borealis has
priority, is also found in upper beds of the lower faunal zone of the Huerfano formation.

A second species of Eotitanops, E. minimus, is present in the upper beds of the Huer-

66 FOSSIL MAMMALIA OF THE HUERFANO FORMATION

TABLE 31

Measurements (in Millimeters) of upper molars of Palaeosyops fontinalis
from the Huerfano formation

Buccal Lingual Anterior Posterior

Specimen length length width width
Mi
YPM nos.
16451 -= 19.0 23.6 —
16450 23.4 19.5 24.0 23.9
AMNH nos.
17411 —- 19.2 27.3 24.5
5107* 26.6 20.5 29.0 25.9 Type
17413 26.9 21.6 28 —
17425 — 2120 28.3 _—
M,
YPM no.
16450 29.5 DIRS, 30.5 28.4
AMNH nos.
17411 Si0 24.7 ot 29.7
17425 S33 26.3 8527 —
M;
YPM no. Width
16450 31.0 21.00 29.0
AMNH nos.
17411 3752 2273 3027
17415 — I —
17413 36.5 Dey 35n3
17425 Sas) DES 33.8
17414 38.2 26.4 34.3

* (From Osborn, 1929, Figure 270)

fano formation. Palaeosyops fontinalis occurs alongside E. minimus; the former is larger
than E. borealis and the latter is smaller. I think that the two upper zone species are
possible descendants of E. borealis. Morphologically, E. borealis resembles P. fontinalis
more than it does E. minimus. E. minimus has the hypoconulid of M, relatively reduced,
and therefore can be separated from E. borealis on morphological as well as size criteria.

As far as I know, E. minimus is found only in the upper faunal zone of the Huerfano
formation.

Eotitanops borealis (Cope, 1880)
Plate IX, figure 2

One specimen, AMNH 17441, an M,, from locality VII, is referable to E. borealis.
Osborn (1919) referred this specimen to E. brownianus, but it is very similar to a referred
specimen of E. borealis, AMNH 14890, (Osborn, 1929, p. 290). The type of E. borealis
is an upper dentition and direct comparison is impossible.

Measurements (in Millimeters) of AMNH nos. 17441 and 14890

Ms; Length Width trigonid Width talonid

17441 Doiae 11.8 1.2
14890 23). = 11.3

PALEONTOLOGY 67

Eotitanops minimus (Osborn, 1919)
Plate IX, figure 7

MateErIAL. AMNH nos. 17418, 17439 (type), 56539 and YPM 16439.

Eotitanops minimus is present in the upper faunal zone of the Huerfano formation,
all four of the poorly preserved specimens coming from locality II. Osborn (1919, 1929)
referred AMNH 17418 to E. gregoryi, but it is smaller than specimens from the Lost
Cabin sample (Table 32).

TABLE 32

Measurements (in Millimeters) of second lower molars of Eotitanops from the
Huerfano and Wind River formations

Width Width

Huerfano Length trigonid _ talonid
AMNH nos. 17439 14.5 9.1 9.3 Type EL. minimus
17418 iS 10:2 10.9
56539 15.4 9.3 9.8
YPM no. 16439 = 9.8 1022
Wind River
AMNH nos. 14890 20.0 12-5 1265
14888 18.6 1176 12.4
14889 17.0 10.6 10.2 Type E. gregoryi
14891 LOR 1275 12.2

Famity HELALETIDAE
Helaletes sp. cf. H. nanus
Plate IX, figures 5, 8

MATERIAL. Locality I: YPM 16464. Locality I: AMNH nos. 17503, 55262. Locality
No. 5 of R. C. Hills: YPM 16457.

Several fragmentary specimens of Helaletes, collected from the upper faunal zone,
resemble the Bridger species H. nanus. Radinsky (1963, p. 46) considers the upper Huer-
fano specimens as possible intermediates between Heptodon and Helaletes.

?Heptodon sp.

Three fragmentary specimens from locality IV are referable, with doubt, to Heptodon.
These specimens are AMNH nos. 17523, 17524, 17563. They might also be Helaletes.

FAMILY HYRACHYIDAE
Hyrachyus modestus (Leidy, 1871)
Plate IX, figure 6

MATERIAL. Locality I: AMNH nos. 17014, 17436. Locality II: AMNH nos. 17440,
55261, field nos. 1952-277, -342, -407, -476. Locality V: AMNH 17442. Wood referred nos.
17014, 17436, 17440, 17442 to this species.

H. E. Wood (1934, p. 192, 196-7) referred the Huerfano specimens of Hyrachyus to
H. modestus. As Wood noted, the material is fragmentary, and subsequent collections
have not added significantly to knowledge of the species. At present the genus is known
only from the upper faunal level. A complete lower molar series is provided by AMNH
17440 and DP,_, by AMNH 55261. AMNH 17436 has fragmentary limb and foot bones.

Measurements of H. modestus are listed in Table 33.

68 FOSSIL MAMMALIA OF THE HUERFANO FORMATION

TABLE, 33

Measurements (in Millimeters) of lower teeth of Hyrachyus modestus from the
Huerfano formation

field no.
Specimen no. AMNH 17442, 17440, 55261, 1952-407
Locality: V 11 II II
Variate
Ps. SE 8.4 -- -= —-
W 553 -- = --
Ps — 10.0 — —
W — 4.2 — -——
Pa ae os 11.9 ~- —
W -- 8.8 -— —
DE; -- — 13.8 —
W trigonid ~- = Gif, —
W talonid — — 7.4 —
DEA == — 1279 —
W trigonid — — (eS) —
W talonid — —- S.0 —
M, L 14.6 14.2 13.9 1354
W trigonid ORs 9.3 OF? —
W talonid 9.9 -— 9.5 —
M; = 16.9 — ==
W trigonid -- 10.3 -— —
W talonid —- ftite3 — —
M; L 1 L7/e) ibfeadh os —
W trigonid 10.8 10.8 — —
W talonid 10.3 10.2 —- o-
Mi-23 L — 49.9 — —

OrpvER ARTIODACTYLA
FamMity DICHOBUNIDAE
SUBFAMILY DIACODEXINAE (sensu Gazin, 1955)
Genus BUNOPHORUS Sinclair, 1914

Bunophorus specimens occur in both the upper faunal zone, localities II and V, and
the lower faunal zone, localities IV and VI, of the Huerfano formation. A single specimen
was collected from the Farisita formation five miles north of Gardner Butte.

Gazin (1952, p. 72-73) states that distinction between Bunophorus and Wasatchia is
difficult, and he draws attention to the nature of the wear of the cusps of upper teeth of
Bunophorus noting the bunodonty and the circular areas of wear. The protocone,
protoconule and metaconule of Wasatchia form a large worn cresent following wear
(Sinclair, 1914, p. 262, fig. 6). In older specimens of Bunophorus the worn patches coalesce,
the protocone and protoconule patches join first and then the metaconule patch joins. In
extremely old specimens it may be impossible to tell the two genera apart. However,
Bunophorus molars wear flat, while those of Wasatchia wear in a band, from front to back,
across the center of the tooth. This comparison is drawn from one specimen of Wasatchia,
AMNH 15673, the type of Wasatchia dorseyana, and four specimens of Bunophorus
(given in order of increasing wear), YPM 16472, AMNH nos. 17485, 56524, and 17486.
Admittedly, the discussion of Wasatchia is based on insufficient data.

The lower teeth of these genera are equally hard to distinguish. Gazin (1952, p. 72)
notes that Wasatchia seems to have a paraconid and a hypoconulid, and inflated molars,
but these characters can also be found in Bunophorus. Worn lower molars of Wasatchia
have a raised trigonid whereas those of Bunophorus are flat. These wear differences cor-

PALEONTOLOGY 69

relate with the upper teeth and indicate that the two genera probably had different
chewing motions.

Bunophorus sp. cf. B. macropternus (Cope, 1882)
Plate X, figures 8, 10, 11

MATERIAL. Locality II: AMNH nos. 17485, 17486, 17487, 17488, 17489, 55204, 55252,
56524, 56525, 56527; YPM nos. 16472, 16475. Locality IV: AMNH 17553. Locality V:
AMNH 55206. Locality—‘‘East side William’s Creek, five miles north of Gardner Butte.”
This set of exposures is in the Farisita formation. AMNH 17561.

Two species of Bunophorus have been described, B. macropternus (Cope, 1882, p. 179)
and B. etsagicus (Cope, 1882, p. 189). The Huerfano specimens have a small basin on the
heel of P, which B. etsagicus lacks. The P, of B. macropternus is not known, therefore
designation of the Huerfano Bunophorus as B. macropternus is doubtful. AMNH 17561,
from the Farisita facies, is noticeably smaller than Huerfano facies specimens.

The sample from the lower faunal zone is not sufficient to indicate any possible change
between the populations of the two levels.

TABLE 34

Measurements (in Millimeters) and statistics of lower teeth of Bunophorus sp. cf. B. macro-
pternus from the upper faunal zone of the Huerfano formation

Localities II and V.

Variate N OR M SD V
Py i Z 7.7-8.1 7.90 - —
W 2 4.2-4.6 4.40 —- --
M, L 7 6.5-7.3 6.90 0.26 Seely
W trigonid i 4.7-5.4 5.01 0.35 6.99
W talonid 7 5.5-6.2 5.80 0.26 4.48
M: i 6 7.3-8.0 ee dh 0225 3.22
W trigonid 6 6.0-6.7 6.38 0.26 4.08
W talonid 5 6.4-7.2 6.84 0.32 4.68
M; ae 4 8.0-10.3 9.38 0.99 10.55
W trigonid 4 6.0-7.0 6.58 0.34 Sell?
W talonid 5 5.3-6.2 5.80 0.32 5.52
Mies 9 4 23.6-25.8 24.70 0.90 3.64

Diacodexis chacensis (Cope, 1875)
Plate X, figure 4

One specimen, AMNH 17552, from locality VI is referable to D. chacensis. The speci-
men is small for D. chacensis but is within the limits of size stated by Sinclair (1914, p.
291). Measurements are quoted below.

Measurements (in Millimeters) of D. chacensis, AMNH 17552

P, Length 4.2
Width 2.2
Mi Length 3.8
Width trigonid 2.6
Width talonid 3.0
M: Length 4.2
Width trigonid 3.0
Width talonid 3.4

70 FOSSIL MAMMALIA OF THE HUERFANO FORMATION

Diacodexis sp. cf. D. secans (Cope, 1881)
Plate X, figure 3

One specimen of Diacodexis, AMNH 17560, was collected from exposures in the
Farisita formation one mile north of Gardner Butte. It resembles Hexacodus Gazin, but
the hypoconulid of M,., is not situated as far behind the hypoconid as in Hexacodus.
The entoconid of M,., bears accessory cuspules. The dimensions of M, are close to those
mentioned by Gazin for a Knight specimen (Gazin, 1952, p. 71).

Measurements (in Millimeters) of Diacodexis sp. cf. D. secans, AMNH 17560

P, M, M;
Length 5.6 4.3 4.7
Width trigonid a2 a2 3.9
Width talonid Se) 4.2

SUBFAMILY HOMACODONTINAE (sensu Gazin, 1955)
Antiacodon pygmaeus huerfanensis new subspecies?
Plate x figs- 1,2

Type. AMNH 17490, fragments of both jaws with right P,-M, and Left M, ..

Hypopicm. Type and AMNH nos. 17472, 55202, 17491, 55203, 56528.

Horizon AND Loca.itry. Upper faunal zone, Huerfano formation, uppermost lower
Eocene. Type and AMNH nos. 17472, 55202, 56528 from locality II, AMNH nos. 17491
and 55203 from locality III.

D1acnosis. Slightly larger than A. p. pygmaeus from the Black’s Fork member of the
Bridger formation. P, similar to that of Hexacodus, with paraconid and metaconid imper-
fectly separated from protoconid.

Discussion. The similarity of the fourth lower premolar of A. p. huerfanensis to
Hexacodus adds support to Gazin’s (1955, p. 11) hypothesis that Hexacodus might be the
ancestor of Antiacodon.

The size of the individuals in the Huerfano sample is generally larger than that of the
Bridger sample measured (collections at the American and Peabody Museums of Natural
History), as listed in Table 35.

Measurements (in Millimeters) of AMNH 17490, type of Antiacodon pygmaeus huerfanensis
new subspecies:

P, M; M:,
Length 5.0 4.5 4.8
Width trigonid 2.9 Sal Sal
Width talonid SES 4.1

7 Subspecific name in reference to Huerfano Park, Colorado and to the Huerfano formation.

PALEONTOLOGY 71

TABEE 35

Measurements (in Millimeters) and statistics of Antiacodon pygmaeus from the Huerfano_ .
formation and from the Blacks Fork member of the Bridger formation

Huerfano
Variate N OR M SD V
Pao y 5.0-5.4 5.20 — —
W 2 2./-2.9 2.80 — -=
M: L 1 — 4.5 —
W trigonid 1 — Syn! — —
W talonid 1 — 3:5 _ =
M: L 4 4.8-5.4 5.10 0.26 5.10
W trigonid 4 320-300 3.65 0.10 2.74
W talonid 4 3.8-4.4 4.08 0.21 5.14
M; L 3 5.0-5.5 S27 — ——
W trigonid 4 3.0-3.8 3.45 0:38. MeOL
W talonid 4 2.9-3.6 S825 ison, tO i,
Bridger
N OR M SD V
Py, 3 2 4.8-4.9 4.85 — —-
W if — 226 — —
M, L 7 4.24.6 4.41 0.26 5.90
W trigonid 6 2.7-3.0 2.87 0.13 4.53
W talonid 6 2.9-3.5 Sey 0.22 6.94
M: L 7 4,5-4.8 4.64 0.12 2.59
W trigonid 6 3.1-3.8 3.38 0.26 7.69
W talonid 6 3.3-4.0 3.66 0.24 6.54
M: L 5 5.2-5.5 5.32 0.13 2.44
Wtrigonid 4 3.0-3.4 ees) 0.17 Gye)
W talonid 5 2.9-3.1 2.98 0.09 3.02

APPENDIX

STRATIGRAPHIC SECTIONS
Sections listed from south to north
SECTION 1. ARCHULETA DRAW

Starts in Sec. 1, T27S, R69W, and continues to Sec. 11, T27S, R69W.
Pediment: Thickness
Huerfano formation (in part): Feet

6. Mudstone, alternating red and brown, beds 5 to 15 feet thick, many
concretions, some lenses of sandstone in valley walls, Phenacodus vort-
mani, Hyracotherium vasacciense, Hyracotherium craspedotum in

TOWER NOU CCE are renee Nasote: si ensye'e a aie, SPccaieyo!s sora ns era SIM crace toenerae eee 385 feet
5s Goveredy 202.07. 5 <6 Geb se oc. 2 eioic wd wie 6 cinta nae cigereeee 20.4
4. Sandstone, medium to fine grained, tan, poorly sorted, very poorly
cemented, grains usually subangular; calcareous ............-...02- 28.0
3. Mudstone, sandy, red-brown and standstone, grey-green in alternating
beds; outerop weathersitam, COncretIONS o 0 e 26... ces een. eee see 29.6
2. Claystone, dark red, silty, forms dark red layer in outcrops, some green
CIAYStONE SS ERIM ETS. 5. vge oper Ne ciclo. hs auenois ie che Si Syste ge SKopabousYaxoy IIS gs esse, > ono S22
1. Mudstone, dark red-brown, sandy partly covered, concretions ........ 53.9

Total measured thickness 530 feet
Poison Canyon formation:

Sandstone, yellow, arkosic, locally conglomeratic, grains subangular to subrounded,
poorly sorted, silt to small pebble size; mudballs; upper surface undulatory. Structurally
conformable with unit 1 above.

SECTION 2. GARCIA CANYON
Starts in Sec. 34, T26S, R69W and continues into Sec. 3, T27S, R69W.

Pediment: Thickness
Huerfano formation (in part): feet
18. Mudstone, sandy, and sandstone, silty, tan, brown. some red layers... 56.0
7. Mudstone,;sandyered-bro wit .ij2 ste ahs: «ix, tevae os s.0) oie tere o Mea Sere ele 5.6
16. Mudstone, sandy, light brown, color reddens near top, green stringers
OVS 5050) BR oreirtadlS sips 4.0. aot ORICON Gt On Oo Oa CIoiocle on oem ee 50 0c 21.4
15. Mudstone, red-brown, sandy, becomes browner and sandier at top, top
tan; grades into\sandstone laterally... <. 25. eeoune oc ee eee ome 16.8
14. Mudstone, sandy, brown, weathers tan, large concretions ............ 9.1

13. Mudstone, red-brown, sandy, small concretions; light green siltstone
layer 1.5 feet thick at 11.5 feet above base; unit becomes browner near
top, Hyracotherium vasacciense, Hyopsodus walcottianus, crocodile,
from neat POttont OF MIMIC. 10:50. 2/spas « Scien eee eels eee eree 30.0
12. Sandstone, coarse grained, conglomeratic, some conglomerate lenses,
arkosic, cross-laminated, surface of unit 11 channeled; fragments of

turtle, small siltstone lenses in standstone. Color grey to green ........ 47.8

Pie) Mudstone: dark-brown, San yi ois.ciciicseresciseo ce ses ei oeietae C earere 5.1
10. Sandstone, yellow to yellow-green, arkosic, conglomeratic, coarse ..... 5.4
9. Sandstone, silty, light brown, some green mudstone lenses ........... 3.6

U4

APPENDIX

Garcia Canyon Section (continued)

Hy StH SI CO

. Sandstone, light brown, silty, becomes siltier and darker near top ....
sp AVSCOME, sDTO WM: SATI CY a¥-tchs0toi0\sict svete sets} aoejtalahisy (0 ahs: sss oie) 289) e's) aha l’s
eeCOncreron layer ndense iCal CareOuUsy sé ofaysiaps) <1s:ayciatavavain aay o> vm Ce iss dati =
Be COVCT CO ots otore bey chan nZ- 0625 ORE Poy h Suess /a1-yoheyeelssaic.e Al'siois aidiehsekchoPauaioim eee ote cd ve

SOR WeY0 |) hath Aa HUA ath Se re BAG A i AD St i A UA aa So ee be

. Sandstone, silty, brown, medium grained, arkosic jointed, weathers as

HALTS TOUNG ISI DOWIGETSH ayers seicis so oi cies ocd od aeetetefe Ee atle eteles Se

. Mudstone, brown, sandy; concretions, concretions white, sandy, large,

bedi weathersjyellows imap laces va). 0.i geste sae ci- nis eye. sheen eyer leicht ves ays

. Sandstone, gray-green, arkosic, calcareous, grains angular and coarse ..

Total measured thickness

Alluvium

SECTION 3. “FOSSIL CREEK”

In Sec. 12, T26S, R70W.

Pediment:
Huerfano formation (in part):

16.
15.
14.

es
12.
1
10.

9

Mudstone;dishtoneen, samGiyr jaw.) shi ee eee anteaters erento
Mudstone, red-brown, sandy; several concretion beds ...............
Mudstone, green-brown, sandy, prominent 0.5 thick concretion layer
MLOotraboverbase OL WMI chien ine Saale caps clots hiee ce sateen tale
NEWS tone browns SATIGYs « 1 Jala vie) s/el re alate tia 0 wo sr ara otal wae TM Pee
MUGSTONe .PLEEM-DLOWM, SATIGY) stirs c)(tta cones ceaie bar tehaiteeae eee aos
Minrcstone;: Drow SAN Gy x arses ciet dels vom Nake ins abe ce nee erate
Mudstoneeneen- brow .SAMdy: gd, 8 142 cise Na charset ieee tle ai hae
Mudstone, red-brown to brown, many concretions, some green clay-
stone stringers; grades laterally into white sandstone. This is the bed
that produced most of the fossils at locality II. All species reported on
faunal lst tom locality ll ypresentimythis bedi i004). tale ae ee eels

. Sandstone, gray-green, silty, micaceous, arkosic, coarse to fine grained

subangulat grains caleareousy s 5). 5a4.so darn iichs a eebteie ciate etcleee ete e

. Sandstone, yellow and white, coarse, silty micaceous, arkosic, yellower

bands-are conplomeratic; Harisita faciestseieibaostcaee ile acta

. Sandstone, gray-green, silty, arkosic, micaceous; upper part grades into

unit 7, thin seams of gypsum cutting across bedding ................

. Mudstone, sandy, red-brown, becomes greenish near top, Notharctus

MUNTENUSM eat DasceOlmUnNitas4 4 5c eee Eee

. Sandstone, gray-green, silty, micaceous, arkosic; subangular, coarse to

finjeserained: (Calcarcouisintsiesisss pacer davasiac Se a ons sivhclc wlaleadhandejer aie eae

. Mudstone, dark red-brown, some green stringers, large concretions

(NEES UY So es oon dicta BAG ECO CLE OO Cn bOI CIO IGE NOs ede ree eee

. Mudstone, brown, micaceous, sandy. Green concretionary layer 1 foot

DELOWMEO Pree error teeta acta ctete dia ahah AA ere, jaycis “ievcietsishs, ciniete wiaiow sos

. Sandstone, green-gray, micaceous, arkosic, silty, poorly cemented, cal-

CALCOUS, CHAINS AME ated. Gel ae exe eo esto ere sie apel aera byes cist whet sts svete

Total measured thickness

Alluvium

73

5.6

15.8
15.8

308 feet

Thickness
feet

ies
17.8
28.0

9.0

255 feet

fics

FOSSIL MAMMALIA OF THE HUERFANO FORMATION

SECTION 4. HUERFANO RIVER-MUDDY CREEK DIVIDE

Bottom of section in Sec. 14, T26S, R70W and continuing into Sec. 16 T26S,
R.70 W. This is the area of locality I and the upper part of the type section of the
Huerfano formation. The most persistent bed is unit 20 of this section which is probably
the same bed as unit 63 of section 5. Unit 16 of section 3 may be the same bed. This is the
only marker bed in the Huerfano formation. Most of the fossils from locality I come from
below this bed but a few from Sec. 16 come from above it.

Pediment

Huerfano formation (in part): Thickness
feet
Sie Mardstone: rem, silty 0). scree ccets eee: cigs eve ee repeat eae eee 10+

30. Sandstone, yellow to tan, conglomeratic, arkosic, coarse, lenses of red
BUNIAOLS LOMO? Mea redogruei rail coe ecm cr ssa Lore eho! aio lave aie a a We ole ooltecarevorerevet certo 28.0
29a Sandstone, coarse tO ane orammeds tail «2s oso 0. cjale al -tore 2 ee alee ee 16.8
28..Mudstone, brown, ted .and green, sandy 2.165... 0402 ac) oe = ae eee 31.2

27. Sandstone, yellow, coarse to fine grained, arkosic, layers peel off in
WEAtEKIMO” ChOSS-latMaIM Stes tel. ye eieisier ote) eet tel erel sates et) tee 16.6
26. Mudstone, red-brown and green, sandy, concretionary ............-+-. 8.6
25, EONCretiOn layers its eave tro eho he clea 5) eier ieee eae ee arctan 0.5
2A Mardstone, sOrGwil o)cip ieee cis « «See oral ee so gaie elena te eet ee ee 2.0
23a CONGCKCHOM lay ell mee ecie cou oe leis ecehe sess sie ae eee ain eee 0.7
22. Sandstone, tan, coarse, arkosic, cross-laminated, silty near top ......... 10.1
21.) Mudstone! (red-brown; SaniGy fac). oi sy 20's eves sta sees ee eis are sere ee 2:2
20s Mudstone, Mehtereen, weatiens Wimtle sc. ese ee a> om ire eee 124
19. Mudstone, red-brown, mottled with green .........0.000ccccccceeees 5a
18. Mudstone, red-brown, sandy, some green stringers, concretions ........ 22.4
17. Sandstone, yellow to tan, poorly sorted, arkosic, silty, conglomeratic .... 4.0

16. Mudstone, dark red-brown, color changes at top to dark brown; con-
GEECIOMARY, yo isyays a yopouowone ¥ovs) sv oreh =vakoy <¥ spel =jehe//as0.01 shot ed ee heothons) sie eRaete ini tok eee nN 8.4
NSE Madstone, JOTEEN, SATIGY y--ceueryeicr-ass-voncieioie eater hae ete eT 4.6
14> Mudstone, dark red-brown; \concretionaty (.).. p21 bis oats ele 14.7
3-0 Mindstomes stanly SariGy, 0 patay<reyevev-hes-y-veiai set eee iatoetet oa mnevehehs CP ey eee 15.7
12. Mudstonex brown, noticoneretionarys. 3hscis\ 2s oaniacteta lols erotica ens 15:2
1g; ‘Sandstone, light’ green; arkosic; coarse, Silty). .% selec lec ieee eee 3.0
105 Mudstone;tan,.sandy,, botie) scrap) = cis 2/alactsle tefaieter = -feueictose ie tai a 25.4
9. Concretion lens, brown calcareous mudstone ...........02.-2-eeeeees 0.4
8. Mudstone, dark red-brown, sandy, concretionary, darkens at top ...... 22 bee
7: Mudstone} tan ,.Ssandy 755 y44e)1 sas 14 5 os Alem seeps eine ie ho eee 18.7
6. Sandstone, tan, silty, poorly cemented, coarse to fine grained, arkosic... 8.6
5b Mudstone; tan, Sandy, cOncreftonany, -)..1-1 Fo -eisia = ieee gall yee ie eee ere 10.7
4. Sandstone, tan, silty, poorly cemented, coarse to fine grained, arkosic... 5.6
SM MAUGStONE, tal SATAY, \OOMEN SERA es ops ae cieiel Natal elo els) oat efoto Nala) ote eter teeter 33.1
2: Sandstone, tan’ to’green, coarse to fine grained, silty . <0... isc ve ele 5.0
le Mudstome, sred-browil, COMCLELIONS ety. /.(c)-\<1</-t1te) fete eats oir nh tanel ra 27.0
Motal measured) thickmessiyc.ce 2.0 his eieleta ets 379 feet

Alluvium

APPENDIX 75

SECTION 5. POISON CANYON-MUDDY CREEK

Base of section in Sec. 18 T26S, R70W; section measured eastward into Sec. 17 T26S,
R70W. This is the type section of the Huerfano formation as designated by R. C. Hills
(1891, p. 7). Although this section is truncated by a pediment (as most of the Huerfano
formation sections are) it is almost fully exposed. This is the only locality in Huerfano
Park where anything approaching a complete surface section can be measured.

Pediment

Huerfano formation (almost complete section): Thickness
feet
66. Mudstone, grey and brown, with lenses of tan sandstone .............. 50.4
65. Mudstone, red-brown, with tan sandstone lemses ................00: 25.4
Gt. Mudstone; red-brown and! browul; saM@y «ce. <6.<,0:5 oiei< <5 = 2j0.4 ose 3 vse 109.7

63. Mudstone, green, silty, weathers white, grades laterally into coarse yellow
conglomeratic, avkOsic SanGstONe << o/c). 10<)s diss scidiere. 5, < dias seis ag ches oa) 4% 21.8
GZ; Muudstone,, mottled red arid: OTeCM ois. 3)6,inncys cre Bioi0 of 4) aja 2% soi eed ais oe 9.6
Gio Mudstone brown. Sam yc. sot :2 grcc1t-5.c.cte 3:34) / Si aieye seein ole olelnjayaioleiee «2 96.8
60. Mudstone, red-brown and, brown, Sandy «5.56.1 siesinne 5 jn 0stenss0 4's 11.0
59. Sandstone, gray-green, coarse, conglomeratic ...............seeeeeeee 12.0
BOar MUGSLONE, (DYOWN, SANE Ya 273). y5.5:6,/01 5 cigs, <2 2 a. score as]olaye Minlerera sioimele ahead Ate 2. 4 6.0
57. Sandstone, gray-green, coatse, conglomeratic « . .....-- << 6.0000 e ss « 12.0
50. Mudstone, red-brown and brown, sandy ..... 2.2. s<e.seeesnemces- ae 424.0
D5» Mudstone, brown and red-brown; sandy «. < see 2/0. sain + oasis te Has oor 129.0
54. Mudstone, red-brown and brown, coarse tan sandstone lenses .......... 301.1
oa WIMCStONE,... PTAY-PECEM (2), dials) jos «ie¥o), 75.0% epaveleiala s spais a) ake 6(049 ate ofenarclarsy 626 9.0
52. Mudstone, red-brown and brown, lenses of tan sandstone ............. 95.0
51. Sandstone, massive, yellow to tan, conglomeratic, poorly cemented .... 68.0
50. Mudstone, red and brown, sandy; bone scrap .............0.eeee eens 40.0
BE GOMER COL 2 sce lea, Sicilas wt echt cohen, CRvak ors ohe PRA CoE SEES PS cE Tea ee 108.0
48: Mudstone, tan, brown and red-brown, sandy ........-.006.0¢es8-4004" 37.0
a1 SAUUSONE, (ail COAESG,; CONPIOMETAUMC -s.c)sj. 5.001414 ies sve so wee ea cine = 26 7.6
Bee VE RTEUS LORE se FEC LOWINE tagcat 5 olenaiaalach e 7s ain cre Gusbank ataua4at Thebes = orarkaieers vee es $25
MO THOSTOME:: CAMs SULEY! : co/- he. Mcuhets ay din hataahe hid hia silelahs, Sin epee k etiote oes 9.5
FE MMGSLONE, TEG-BLOWI Ha tra ais-\ tone ett c Re aa DOMe hows 6) ape elem anata ale." 35.0
43. Mudstone, brown and yellow, sandy, sandstone lenses ................. Zone
Ae MMAStOne,. STEEN: AGS ark. DEOWE s 205) ai«00)5)0.0)<4yorae eysjeimias sis ais Hh aielh oie oe 14.3
Ae SANGUStONE., tAl> tO) DEOWD: COALS ts ats; crave a1sevaia a hr omiheaicras wis. as ce eae 9.0
AO VEUIGSLONG: TEC DEOWID: (5.3.4 avarevs a/ zie cickars eioials, © badd eat SELES ds ae 7.0
39: Sandstone, tan to brown, coarse conglomeratic .........000.060e-ee00s 6.0
Sear MCIOSEOT CAT ECD LO WIN ra hi 6f oic, o)aheick rahe eriaas Siege iss eS car eames ie 30.3
SU SAMUSLONE «COATSE) CAI AT ROSIC 1% 5 aici craseranc a/c erel otebs: crease oss <A creeneiln wigiel ae 6.5
SOs Mtcstone; PTO Wy SAO YS co 00<, 6 'ie cheno sn ayers) oS ickewis eursciolereuetsya, 5 a,0-0) wis ei sVe)> we 19.0
35; Mudstone, ereen and red, some layers!Sandy) 3.15, j<ts0.c.c4< + anis acts sos 4 30.0
pe MUO S CG Ies SECO DEO WAL troyer 55 sransieke: <seforcie fur nani cel ita oral ere Seas Gabe ards ae 16.0
Jo HAanOstone,; tan. COMPIOMETALIC, sATKOSIG. /e, <j-1,0.< ose ate a ls oh sien anes siere sos 22.0
$22 MEMOSLOME, /DEOWI, SAUGY? 5 «cfr. s. oad oe) e)n icy aamcatsin ha: + eles s/epuin ois So n913, 0h 15.0
al OAnGseCOne ntti, COMPIOMEFALIC 2 oo, vm e/ie cons 2c 3 fold Rie 4a cs aes oa S495 6.3
SU SN GStOME s DRO WI SAMO) a eucinte so oi eieges capa he, oieas a chap sasha eie cha asta Stes oo 4.56 35.3
29. SARMSEONE PLCC ALKOSIC, CORES! 2 cols oo ors =cj0eo ya ein mcd a8 0m Gage eee s+ 8.8
De MAIS EOE. REC ME OWNENINS octets Ser | obey ales Aarne ey ete Src, 6 cle ciao paved, ouaaran, eis 45.7
27. Mudstone, brown; sandy, some beds sanGien. . 6... 5.<0 50060 were nne soe 90.0
26; Sandstone, tan, coarse, Conglomieratic, arkGSiC.. 5... sec. wee sees’ 720
Bie WEES GONE LEU LOW IM etee fy tiaras a el auseer a are isthe eRe ec Sweet & muaibia Ms ole 19.0
Dae SANUSUGIIE a CAld COANS Cataract aie eid/e/o-ore aie nisl winta.a waeaiciets Miwa ® ahduaia. eas che a suey 3.0

OA PPIVELIGSLOMES LEG“ DLO WAL Mee Petar nee ietevstancicle onsal EI SEa: 6 CRETE sTG, 5 acta sate Gras asayaeatene 7.5

76

FOSSIL MAMMALIA OF THE HUERFANO FORMATION

Poison Canyon-Muddy Creek Section (continued)

22>, Mudstone; brows, tsand ya.5.5csaieeess ciety ts, hcl os ae ee eR ere 39.5
Al. sSandsione) tau, CONPIOMELr Atl Cwar ily, a Sf ue Soave oe ee RENE lee ee 59.0
20; Miudstone,; brown; Sand yyy. 2b Based vrei p cals 3 <i essa aie Moe hee Mee 5.0
19: “Sandstone COATSe stall, ALKOSIC? viuioseys niles ous tas teas oe ee OE ee 13.0
1S a Murdstomme; Fed brOW Mes Aries oa terse le oneusions sos! 1G) sore RL tee Ee Hoe Stk ee 42.0
l7. Sandstone, brown, coarse, poorly indurated .....524-¢..06025 sete eeee 7.0
NG; Mudstone ibrowi; SanGy) a: issac cise eyse ¢ aves ae ee Reels on aeree eee eae 4.3
152 Sandstone, tan coarse vanKOSiG <aesiom oe sess 4c tess eee ee ee Dal,
14. Conglomerate, yellow to tan, boulders of gneiss, schist, granite up to 0.9 14.8
13 OMS fOlle HEC TOW cs 3 55 /stiae cous oicuere so need a ic vtaie Gan ohio oe 74.0
12 AMudstone brown, sandy ccc ces Ce eeie ste neeek 26 Oe Cee Coe eer 11.8
Le Mudstone:red-Browmts hee ecto e aronus ceca Geren Ose OO 6 oes Ce 69.0
NOSCOVERCOE, ee ele escheat eae aerate ES Eae ERO Le Ee 220.0
OVS MUAStONe; DOW SANGY) ceva arte Mees cosines erie ee Rene ce te conor 24.0
35 Sandstone: tan. COatse saLKOSIC 30s cnet ao os Sale ee ene Be od eee 1.3
7 aMudstone, brownnsanGy tty cp ese ors ce eres a oye ol Corea ee 3.8
GreMirdstonesoreen: Sandy 6 scr ose ne oe Pate neo Coe ere eee 1.8
5. Mudstone, brown, sandy, with large concretions ...................-- 28.0
A SANUSCONE SOLECM SUC mente ae ema oc eles ee ntere eine chee ose ot oe Pre 2.4.
SAM stone Drown, GANG Ye. ee srrecs gp cols issr gete come le pone ten oa ere 14.3
2M Miuldstone, “hed-DrOWN 5. eo Pere ean cee ieee hee ee ee ee 5.1
I Mardstone browns sandy ene ctor. te, eters cate os ct ener cite e ees ere 16.0

Motalsmeasuredsthickness! sete eee eee een 2,735 feet

Poison Canyon formation:
Sandstone, yellow-cross-laminated, arkosic conglomeratic; contact with overlying Huer-
fano formation structurally conformable.

SECTION 6. BLACK MOUNTAIN

Base of section in Sec. 35, T25S, R71W and continues into Sec. 25, T25S, R71W.

Covered

Huerfano formation (in part): Thickness
feet
45. Mudstone, dark gray-green, weathers white, plastic, sandy ............ 4.0
44 Mudstone, red- rows SANG yin cc wets ieres ojos ear secns ere ecient te = ore eerste 11.4
43. Conglomerate, brownish-pink, arkosic, micaceous .................+-- 13.9
AD PNEUGStOME, FEC \ainmieroletecs tots clakee sars wien siete ce velba soles sie cle eae 0.5
Alle Sandstone, pink, Silty; AV KOSIG). cia.< s,<1cvcles !ovsie"s « Gussere sa avs1s ec, erento ieee U7
40F Mrudstone; red-browmly sandy, iss .<rie\<.2re crersyeyevekes ais oe oie <) sje cic sel rer 58.0
SOs, SAMGStOMe, INK, AT KOSIG, SI tyicy. <1) o sy) oleiers se eres Susie ats see 2.0
SSE MIUdStONne eed -DTOW Me SANG, tacs)ecsne cis: roles Sra;srbiee = he erences fers eae Sane 34.2

37. Mudstone, red-brown; 1-foot thick sandstone bed at 51.3 feet; unit be-
COMES SANGIEL LOWALGS TOP“ ierskyeie-sks,ctaises oie «oitenps susie oe ieee eee I 85.5
a0). @onclomerate, brownish) Otay, SANGy, \. ris: cass om oo eee ioe mene 5.0

35. Mudstone, red-brown; beds of brown sandy mudstone with green
SEMINSELS, MUCH LOL MIE COVEREO. ca: 21. afevets oo isin ee rncrhes Cee 256.3

. Sandstone, conglomeratic, arkosic, with thin lenses of silty sandstone ... 34.2
MIMIUIAStON Ee snEG- DOW me cisions Sis oekeke eee nie nan er ee OE eter 13.3

APPENDIX 77
Black Mountain Section (continued)
32. Mudstone and claystone, yellow and gray, pebbly, plastic ............. 7.8
31. Sandstone, white, silty, arkosic, conglomeratic; laterally grades into
WellOWiCOUBIOMENALC << rarecis a= clciela = wie siele soko eho ie) tien sieiers wes eleleie late craic 25.8
SOsm Mudstones red-prow ly SAMGy: peal atte) ce lors ic opeteti hel aiala| at eVelepetes= clavere ==: la Wiel
29. Mudstone, gray, plastic, sandy .........--2222.2 seer ee cree eee e ee eees 5.0
Oe Me MMESEONE LEC TOWED cite serh ote Oren cae corey eisyeiene fe aretinyaiersies ois: te.e.6 chun sles 64.2
27. Sandstone, pink, silty, arkosic, conglomeratic; lenses of red mudstone . 15.5
Huerfano formation?
26. Sandstone, yellow-brown (limonite color), poorly indurated ........... 76.6
25. Mudstone, yellow-brown to gray, fissile, plastic ..............--++---- 21.8
24. Sandstone, yellow to white, conglomeratic ............2.eeeeeesee sees 5.0
23. Clay and sandy clay, yellow to green, plastic, sticky (?bentonite) ....... 134
22. Sandstone, light gray, coarse arkosic, poorly indurated ............... 5.0
21. Mudstone, blue-gray (gun-metal color), bed of grey mudstone at 90 feet . 117.8
20. Sandstone, dark brown to gray, conglomeratic, arkosic, dark cement .... 1)
19), Mudstone; red-brown, sandy, fissile). 17-027. e's clan ter ehels) isle eleie eset oie 19.0
18: Sandstone; brown and yellow, silty, arkosic) 22.22.22... .----- 22+ - 5.8
17. Mudstone, alternating 1 foot thick layers of red and grey ............ ed
16. Sandstone, white, silty, arkosic, conglomeratic, micaceous, coarse, forms
a bold white outcrop with prominent knobs .............-..-+-++++--- 19.6
15. Sandstone, yellow-brown, conglomeratic, “limonite” cement; with piso-
WEIG) pLIMAOMECE | LAV ET o).7craVo iete ctreveh ope Total kek eeetP eno sda ate a) ehcley Patel easiot = 1.0
14. Mudstone, blue-grey (gun-metal color) ..........-20- eee ee cree ee eeeee 13
13. Mudstone, red-brown and yellow, sandy ..............2sceseeeeeeees 2.5
12. Sandstone, gray to tan, coarse, arkosic, conglomeratic; laterally grades
OPO AIVETR ROIS UNS 6 oe nig bon doobeanooUndooo Gor po doo Soho abc emn 18.0
Dies Mudstone, red andioteen,sissilemerr att.net at rte he meh) ve -yare ol aero 8.6
10. Mudstone, red, green and gray, sandy, stringers of “limonite” ......... 1229
9. Sandstone, yellow to tan to gray, arkosic, micaceous, poorly indurated .. 23.0
8. Mudstone, red and green, with stringers of “limonite,” grades laterally
IMO, oray Stley SATMSLOME! elevator rela iclodsiehe atelele evelela ayarttets ehh alee eer t sic rel 16.0
7. Sandstone, tan to brown, conglomeratic, arkosic, weathers easily ........ 9.3
6. Mudstone, red, yellow and gray, micaceous, sandy, arkosic ............ 9.8
Poison Canyon formation?
be Sanastone:: yellow «Silty; sIMIGACCOUS ve). .}-1etalets le feis etelar-eele alate eee 2 1.7
4. Sandstone, yellow, silty, arkosic, coarse, cross-laminated ..............- 1.0
5 (GEN). (oe h NOE RTs) amonn on hone nue Nooo OonS es doms Manes cicdnc cb Ode 5.0
2. Sandstone, light green to tan, silty, laterally grades into brown sandstone
Vine) WER Cie OS ogg oap mab SeoocUCoo Cone DobOnodddp ues od od os amaaee er 21.0
1. Sandstone, yellow-brown, conglomeratic, coarse, arkosic, “‘limonite”’
Noaules pweatmersuligine yellowiaierttericherae ck treet erarehs -telcteneneteretetci 22.0
Total nieasured) thickmess)-). -s31301-/. 4-% < 1175 feet
Poison Canyon formation

78

FOSSIL MAMMALIA OF THE HUERFANO FORMATION

SECTION 7. BLACK MOUNTAIN

Base of section Sec. 36 IT25S. R71W and continues to Sec. 25, T25S, R71W.
Farisita formation:

Conglomerate, yellow, sandy; boulders up to 3 feet in diameter, boulders of highly
weathered schist, arkose; Channels into Huerfano formation; angular unconformity.

Huerfano formation (in part): Thickness
feet
30. Sandstone, red and white, coarse, silty; grades into red and white sandy
MUdsStone MEAT COP Mises Assos se aeene bcs ee eae eee 3.0
29. ‘Conglomerate; sandy: 22 sls. 82 Ri0 esis. Se adh ee Aa Se eek ee SH
28. .Mudstone;-red ;and: green, o2i0..dce Sects ctl. cc. Oo eee ee eee nae 57
27. Sandstone, tan to yellow, massive, conglomeratic, boulders of biotite
schist, lower 3 feet laminated, upper part cross-laminated. A prominent
Clif formiensdigi heey ce Matted 2G ike twee eG Se Beet 6 Meee 20.1
26. Sandstone; brown; silty, conglomeratic ji5 sc disse. feels... hig ence ee 64.7
25. Sandstone; ereen to brown coarse, avkOsiG).0)-5,.)0 ei oes ere ee ee 5.7
24. Sandstone, brown, silty; top of first sandstone bed at 17.1 feet; some green
silty lenses;vdark 0:5 footisandstone bediat:28-5afeeti 2s . jcc see 74.1
23. Mudstone; eray-ereen; sandy aveathers white ia: san nce «ee eee ee 29:9
22. Mudstone, red-brown, sandy, upper few feet mottled red and green. May
be same bed as unit 19 in section 4 and unit 62 in section5 ........... 14.4
21 Sandstone,. pink arkosic,. conglomeratic: ..;, « 2/-.tbiies aoe mis eae 7.0
20. Mudstone, red-brown, some pink sandstone lenses and gray-green silty
SANASEONE MEMSES. io Lie dias cae, aPevee rhe aoe ria lay le ladata she ie rece nets eit ee eee 79.8
19 sMardstone) for ay-OTEeW yey ie: pital hats clea s aco ae Ohta ete ln cheater 20
18. Mudstone, red, silty. Tooth of Didymictis vanclevei at 39.9 feet ........ 71.4
17. Mudstone, red and green, sandy, weathers olive green ................ 5.0
16... Mudstonevbrown,; Sandy iota iia ecleks. ie cete ofa tele. lela are octet eicie ena eter ae ee 79.8
15. Sandstone, yellow to brown, conglomeratic. Boulders derived from Sangre
de Cristo formation; boulders up to 1.3 feet in diameter. Grades laterally
IMO) PreeN-Wihite/ SANGStONES) es wie vscjnnlaie an el stele clot 2 erie ade eee oF
14. Mudstone, red-brown, sandy, with green nodules .................... Ly)
13. Mudstone, red-brown and green, sandy; weathers red-brown and grades
laterally into pink arkosic Sandstone:.... <<. «< «s12- niae nee ee S15
12. Mudstone, red-brown, sandy, some green-grey sandstone lenses ........ 51.3
11. Conglomerate, boulders of granite, schist, and arkose ................. 19.1
10. Mudstone;, brown,: sandy, pebbly: 2.0.2 .cGee<cu a= sheen ade 4 eeiaee a7)
9. Sandstone, red to light gray, boulder conglomerate at top ............. 17.1
8. Mudstone)erey-ereeny oi jeisine is ioe aioe Sieicaeseleie mice Cornhole ae er te 13.2
7. Mudstone, red-brown, sandy with lenses of green silty sandstone ....... 15.3
6.,Sandstone, white; poorly mdurated, pebbly {-.2<:to cr « ccie teres ole ie iar iL hey
5. Mudstone; brown) sandy (3)... sicctone ote cae o eieche ese ese caus ce eras 6.4
4. Sandstone, yellow to tan, silty, conglomeratic lenses; lenses of red silty
Sandstone give outcrop\a pink: colon joc <i). «2s usin 2 one 3.5
3; Mudstone, ‘red with ereemtstrineers eiej eloneis ore oi-lcieler= ore\s «ole cioiecelone ctenere 19
2, Conglomerate mp inkset aac oF | rsorelee eeiemaieieke «lossless eye evee ie eee 7.0
1. Mudstone, red to purple, stringers of green calcareous siltstone ........ 215
otalsmeasured: thickness |, 3 /s.ci<.sici steer ere 694 feet

Covered

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Abbreviations, 28

Absarokius noctivagus nocerai, 33
Abstract, 1

Acknowledgments, 3
Anaptomorphidae, 33

Antiacodon pygmaeus huerfanensis, 70
Apatemyidae, 36

Apatemys, 36

Artiodactyla, 68

Bathyopsis sp. cf. B. fissidens, 60
Bibliography, 79

Brontotheriidae, 63

Bunophorus, 68

Bunophorus sp. cf. B. macropternus, 69

Carnivora, 46

Cenozoic System, 5
Condylarthra, 53

Coryphodon sp., 60
Coryphodontidae, 60

Cuchara formation, 7ff
Cynodontomys knightensis, 39
Cynodontomys scottianus, 39

Devil’s Hole formation, 16
Diacodexinae, 68

Diacodexis chacensis, 69
Diacodexis sp. cf. D. secans, 70
Dichobunidae, 68

Didelphidae, 29

Didymictis altidens, 48
Didymictis sp. cf. D. protenus, 47
Didymictis vancleveae, 48
Dinocerata, 60

Edentata, 44

Eocene Series, 6
Eotitanops, 65
Eotitanops borealis, 66
Eotitanops minimus, 67
Equidae, 61
Erinaceidae, 29
Esthonychidae, 43
Esthonychinae, 43
Esthonyx acutidens, 43

Facies Changes, 7

Farisita formation, 6ff

Faunal Levels, Huerfano and Farisita
Formations, 14

Faunal lists, 13ff

Fossil Localities, 22

Geography, 4
Geologic History, 20

INDEX

Geology, 2
Geomorphology, 19

Helaletes sp. cf. H. nanus, 67
Helaletidae, 67

?Heptodon, 67
Homacodontinae, 70
Huerfanius, 35

Huerfanius rutherfurdi, 35
Huerfano formation, 6f£
Hyaenodontidae, 47
Hyrachyidae, 67

Hyrachyus modestus, 67
Hyracotherium craspedotum, 61
Hyracotherium vasacciense, 62
Hyopsodontidae, 54
Hyopsodus, 54

Hyopsodus paulus, 55
Hyopsodus walcottianus, 55
Hyopsodus wortmani, 55

Insectivora, 29
Introduction, 2

Lambdotheriinae, 63
Lambdotherium popoagicum, 63
Leptictidae, 31

Leptotomus costilloi, 45
Leptotomus grandis, 45
Leptotomus huerfanensis, 45
Leptotomus parvus, 45

Loveina zephyri, 32

Mammalia, 29ff
Marsupialia, 29
Mesonychidae, 46
Mesonyx obtusidens, 46
Metacheiromyidae, 44
Metacheiromys, 44
Miacidae, 47

Miacinae, 51

Miacis sp. cf. M. parvivorus, 51
Microparamyinae, 45
Microparamys, 45
Microsyopidae, 38
Microsyops lundeliusi, 41

Notharctidae, 31

Notharctus nunienus, 31
Nyctitheriidae, 31

Nyctitherium sp. cf. N. velox, 31

Omomyidae, 34

Oddectes herpestoides, 52
?Oddectes, 52

Oxyaena sp. cf. O. lupina, 46
Oxyaenidae, 46

Palaeanodonta, 44

Palaeictops bicuspis, 31
Palaeosyopsinae, 64

Palaeosyops fontinalis, 64
Paleocene Series, 5

Paleontology, 22

Pantodonta, 60

Paramyidae, 45

Paramyinae, 45

Paramys copei copei Loomis, 45
Paramys excavatus gardneri, 45
Paramys huerfanensis, 45
Patriofelis sp. cf. P. ulta Leidy, 47
?Patriofelis, 47

?Peratherium sp., 29
Perissodactyla, 61

Phenacolemur jepseni simpsoni, 36
Phenacolemuridae, 36
Phenacodontidae, 53

Phenacodus vortmani, 53
?Pliocene Series, 16

Poison Canyon formation, 5
Primates, 31

Primates (incertae sedis) or Insectivora, 36

Reithroparamyinae, 45
Reithroparamys huerfanensis, 45
Rodentia, 45

INDEX

Scenopagus, 29
Scenopagus edenensis, 31
Scenopagus priscus, 29
Sciuravidae, 46
Shoshonius cooperi, 33
Sinopa sp. cf. S. strenua, 47
Stratigraphic Sections, 72
Structural Geology, 17
Stylinodon, 44
Stylinodontidae, 44

Taeniodonta, 44

Talpavus sp. cf. T. nitidus, 29
Taxonomy, 27ff

Terminology lower Cenozoic Rocks, 9
Thisbemys nini, 45

Tillodontia, 43

Trogosinae, 43

Trogosus grangeri, 43

Uintacyon sp. cf. U. asodes, 52
Uintatheriidae, 60

Viverravinae, 47
Viverravus gracilis, 49
Viverravus sicarius, 50
Vulpavus asius, 53

85

PEARE 1

Figure 1. Talpavus sp. cf. T. nitidus, AMNH 55226, fragment of left jaw with P;-M,
from locality VIII. x10.

Figure 2. Palaeictops bicuspis, AMNH 55271, at left M, from locality VIII. x10. Uninten-
tionally mounted in reverse.

Figure 3. Scenopagus priscus, AMNH 55156, fragment of left jaw with P,M, from
locality III. x10.

Figures 4, 5. ?>Metacheiromys sp., AMNH 18666, right astragalus from 1 mile north of
Gardner Butte, Farisita formation, ventral and dorsal views. x 2.

Figure 6. Bathyopsis fissidens, AMNH 17438, a left P, from locality III. x2.

Figure 7. Peratherium sp., AMNH field 1952-328, fragment of left jaw with M, from
locality If.

Figure 8. Coryphodon sp., AMNH 56543, a left P, from locality II. x0.8.

Figure 9. Palaeosyops fontinalis, YPM 16463, right M, from locality 5 of R. C. Hills. x2.

86

PEALE It

All figures stereopairs
Figure 1. Absarokius noctivagus nocerai, new subspecies, Type, AMNH 55215, fragment
of left jaw with P.-M, from locality H. x 4.8.
Figure 2. Loveina zephyri, AMNH 17554, fragment of left jaw with P,-M, from locality
Wie aeee
Figure 3. Nyctitherium sp. cf. N. velox. AMNH 55151, fragment of left jaw with M,,
from locality III. x 10.

87

PLATE III

All figures stereopairs

Figure 1. Huerfanius rutherfurdi, new genus, new species, type, AMNH 55216, fragment
of left jaw with P,-M, from locality II. x 4.8.

Figure 2. Phenacolemur jepseni simpsoni, new subspecies, type, AMNH 2680, fragment
of right jaw with P,-M, from the lower faunal zone, probably locality VI. x 4.8.

Figure 3. Shoshonius coopert, AMNH 55153, fragment of right jaw with M,, from
locality II. x 4.8.

Figure 4. Scenopagus edenensis, AMNH 17483, fragment of right jaw with P,-M, from
locality III. «4.8.

Figure 5. Scenopagus edenensis, type, AMNH 55685, right M,.,, from Morrow Creek
Member of Green River formation. 4.8. Unintentionally mounted in reverse.

88

PLATE IV

Figure 1. Cynodontomys scottianus, YPM 16468, fragment of right jaw with P,-M, from
locality IV. X1.6.

Figure 2. Cynodontomys knightensis, AMNH 55225, fragment of right jaw with I, P,-M,;
from locality II. x 1.6.

Figure 3. Hyracotherium craspedotum, AMNH 17513, fragment of left jaw with M,,
from locality VI. x 3.0.

Figure 4. Hyracotherium vasacciense ?venticolum, YPM 16436, fragment of right maxilla
with DP** from locality IV. x 3.0.

Figure 5. Hyracotherium vasacciense vasacciense, YPM 16481, fragment of left maxilla
with P*-M? from locality II. x 3.0.

Figure 6. Microsyops lundeliusi, YPM 16482, fragment of mandible with right P,-M,
from locality II. x 1.6.

Figure 7. Hyracotherium vasacciense vasacciense, YPM 16455, fragment of right maxilla
with M** from locality VI. x 3.

89

PIEARE, Vi

Figure 1. Stylinodon sp, YPM 14616, canine tooth from “South of Hausero’s Ranch.”
x 0.8.

Figure 2. Vulpavus asius, AMNH 56508, fragment of right jaw with M, from locality II.
><EG:

Figure 3. Viverravus gracilis, YPM 16467, fragment of left jaw with M,_, from locality IV.
SQIEGs

Figure 4. Uintacyon sp. cf. U. asodes, AMNH 17434, fragment of right jaw with P,-M,
from locality VI. x 1.6.

Figure 5. ?>Miacis sp. AMNH 56544, fragment of left jaw with M, from locality II. x 1.6.

Figures 6, 7. Oxyaena sp. cf. O. lupina, AMNH 55298 from locality VI; fig. 6 right M’,
fig. 7 right M.. x0.8.

Figure 8. Esthonyx acutidens, AMNH 17531, fragment of left jaw with P,-M, from locality
Vix 0:8:

Figure 9. ?Oddectes sp.. AMNH 2681, fragment of left jaw with P,-M, from lower faunal
zone, probably locality VI. x 1.6.

Figure 10. Miacis parvivorus, AMNH 17435, fragment of left maxilla with M? from
locality II. x 1.6.

Figure 11. Oddectes herpestoides, AMNH 56504, fragment of left maxilla with parts of
P®-M? from locality III. x 1.6.

Figure 12. Viverravus sicarius, AMNH 56511, fragment of right maxilla with parts of
P?-M* from locality II. x 1.6.

90

PAGES VI

Figure 1. Sinopa sp. cf. S. strenua, AMNH 17421, right jaw with M,, from locality II.
x 0.8.

Figure 2. Patriofelis ulta, AMNH 17017 (Type of P. compressa), left jaw with C, P.-M,
from locality III. 0.8.

Figure 3. Mesonyx obtusidens, AMNH 55272, fragment of right maxilla with P*M? from
locality II. x0.8.

Figure 4. Mesonyx obtusidens, AMNH 17423, fragment of left jaw with parts of P,-M,
from locality III. x0.8.

Figure 5. Sinopa sp. cf. S. strenua, AMNH 17421, fragment of left maxilla with M*? from

locality II. x0.8.

91

PLATE VII

Figures 1, 7. Didymictis ?protenus, YPM 16458, fragment of right jaw with M,. from
locality VIII, occlusal and buccal views. x 0.8.

Figures 2, 4. Didymictis vancleveae, type, AMNH 17424, fragment of left jaw with P,-M,
from locality I, occlusal and buccal views. x 0.8.

Figures 3, 5. Didymictis altidens, AMNH 2677, right M,_. from the lower faunal zone,
probably locality VI, occlusal and buccal views. x 0.8.

Figure 6. Didymictis vancleveae, new species, AMNH 17030, fragment of skull with left
P*-M? and right M** from locality I, Palatal view. x 0.8.

92

PLATE VIII

Figure 1. Palaeosyops fontinalis, YPM 16450, fragment of left maxilla with C-M?® from
locality II. x0.8.

Figure 2. Trogosus grangert, YPM 16449, fragment of right jaw with I, P,-M, from
locality II. x0.8.

Figure 3. Notharctus nunienus, AMNH 55224, fragment of right jaw with P,-M, from
locality VI. x 1.6.

93

PEATE 1X

Figure 1. Palaeosyops fontinalis, YPM 16451, fragment of left jaw with DP, and part of
DP, from “South of Hausero’s Ranch.” 1.5.

Figure 2. Eotitanops borealis, AMNH 17441, right M, from locality VII. x 1.5.

Figure 3. Palaeosyops fontinalis, YPM 16451, fragment of left maxilla with DP** and
part of M’* from “South of Hausero’s Ranch.” 1.5.

Figure 4. Lambdotherium popoagicum, YPM 16466, fragment of right maxilla with M**
from locality IV. x 1.5.

Figure 5. Helaletes nanus, type, YPM 11807, fragment of right jaw with P,-M, from the
Bridger formation. 2.0.

Figure 6. Hyrachyus modestus, AMNH 55261, fragment of left jaw with DP,.,, M, from
locality II. x 2.0.

Figure 7. Eotitanops minimus, type, AMNH 17439, left P,-M, from locality II. 2.0.

Figure 8. Helaletes sp. cf. H. nanus, YPM 16457, fragment of right jaw with parts of
P,-M, from locality 5 of R. C. Hills.

94

READE XxX

Figures 1-4 are stereopairs

Figure 1. Antiacodon pygmaeus huerfanensis, new subspecies, AMNH 55202, fragment
of left jaw with M,_, from locality II. x 1.6.

Figure 2. Antiacodon pygmaeus huerfanensis, new subspecies, type, AMNH 17490, frag-
ment of right jaw with P,-M, from locality II. x 1.6.

Figure 3. Diacodexis sp. cf. D. secans, AMNH 17560, fragment of right jaw with P,-M,
from Farisita formation, 1 mile north of Gardner Butte. x 1.6.

Figure 4. Diacodexis sp. cf. D. chacensis, AMNH 17552, fragment of left jaw with P,-M,
from locality VI. x 1.6.

Figure 5. Hyopsodus wortmani, YPM 14612, fragment of left jaw with M,., from locality
eS uG:

Figure 6. Phenacodus vortmant, AMNH 55230, fragment of right jaw with P,-M, from
locality IX. x0.8.

Figure 7. Hyopsodus walcottianus, YPM 16446, fragment of left jaw with M,, from
locality IV. x 1.6.

Figure 8. Bunophorus macropternus, YPM 16475, fragment of right jaw with P,-M, from
locality II. 0.8.

Figure 9. Hyopsodus paulus, YPM 16435, fragment of right jaw with M, from locality III.
LG:

Figure 10. Bunophorus macropternus, YPM 16472, fragment of left maxilla with M*™
from locality II. x 0.8.

Figure 11. Bunophorus sp. cf. B. macropternus, AMNH 17561, fragment of left jaw with
M.., from Farisita formation, east side of Williams Creek, 5 miles north of Gardner
Butte. <0.8.

95

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