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FIELDIANA: GEOLOGY

A Continuation of the

GEOLOGICAL SERIES

of

FIELD MUSEUM OF NATURAL HISTORY

VOLUME 15

FIELD MUSEUM OF NATURAL HISTORY
CHICAGO, U.S.A.

TABLE OF CONTENTS

PAGE

1. The Non-Therapsid Reptiles of the Lufeng Basin, Yunnan, China. By

David Jay Simmons 1

2. The Mammalian Genera Arctoryctes and Cryptoryctes from the Oligo-

cene and Miocene of North America. By Charles A. Reed and
William D. Turnbull 95

3. Catalog of the Collection of Meteorites in Chicago Natural History

Museum. By Henry Horback and Edward J. Olsen 167

NOV 10 1965

LIBRAKY

THE NON-THERAPSID REPTILES

OF THE LUFENG BASIN, YUNNAN, CHINA

DAVID JAY SIMMONS

FIELDIANA: GEOLOGY

VOLUME 15, NUMBER 1

Published by

CHICAGO NATURAL HISTORY MUSEUM

APRIL 29, 1965

GEOLOGY LIBRARY

THE NON-THERAPSID REPTILES

OF THE LUFENG BASIN, YUNNAN, CHINA

DAVID JAY SIMMONS

Department of Palaeozoology University of Chicago

FIELDIANA: GEOLOGY

VOLUME 15, NUMBER 1

Published by

CHICAGO NATURAL HISTORY MUSEUM

APRIL 29, 1965

Edited by Edward G. Nash

Library of Congress Catalog Card Number: 65-19776

PRINTED IN THE UNITED STATES OF AMERICA
BY CHICAGO NATURAL HISTORY MUSEUM PRESS

CONTENTS

PAGE

Introduction 5

Geology of the Lufeng Basin 6

Preservation of Bone 11

Systematic Consideration 13

Order Thecodonta

Suborder Pseudosuchia

Dibothrosuchus elaphros gen. et sp. nov 13

Strigosuchus licinus gen. et sp. nov 31

Platyognathus hsui Young 34

Pseudosuchian 47

Order Crocodilia

Suborder Protosuchia

Microchampsa scutata Young 49

Order Saurischia

Infraorder Coelurosauria

Lukousaurus yini Young 54

Remains referrable to the Podokesauridae 55

Suborder Prosauropoda

Gyposaurus sinensis Young 60

Lugengosaurus hueni Young 61

Lufengosaurus magni Young 62

Yunnanosaurus sp. Young 63

Infraorder Carnosauria

Sinosaurus triassicus Young 64

Order Ornithischia

Suborder Ornithopoda

Tatisaurus oehleri sp. nov 65

Stratigraphic and Paleoecologic Considerations 73

zoogeographical and paleogeographic considerations 79

References 89

The Nori'Therapsid Reptiles
of the Lufeng Basin, Yunnan, China

INTRODUCTION

The geological investigations of Bien (1941) some twenty years
ago demonstrated that the sediments of the Lufeng Basin, Yunnan,
China, held a richly varied vertebrate fauna. We are indebted to
C. C. Young for our detailed knowledge of the fossil materials. The
early taxonomic work progressed so rapidly that by 1940, the prin-
cipal members of the assemblage were segregated and described
briefly in several short preliminary notes (Young, 1939a, 1940b).
Seven papers treating the individuals in detail were published in as
many years (1941-1948), and in 1951 the fauna was assessed in mono-
graphic fashion.

The collection to be described was made in 1948 and 1949 by an
expedition of the Fu Jen Catholic University of Peking led by Fr. E.
Oehler, S.V.D. A re-examination of the fauna was deemed justifi-
able on several counts. First, the field work conducted by Young
continued sporadically for two seasons during the early war years;
lack of funds, transportation and equipment provided such difficult
circumstances that the collections were largely cursory and unsys-
tematically procured. Second, new outcrops from which fossils might
be obtained were certain to have been exposed in the years inter-
vening between the early and late 1940's. Young's sample is domi-
nated by large saurischians but the scanty and very imperfect remains
of smaller forms were reported. The fragment of a jaw symphysis
tentatively diagnosed as a small pseudosuchian was of particular
interest.

The fossils were lent from the S.V.D. Catholic Universities in
1957 by Fr. H. W. Rigney, S.V.D. The collection is known as the
Fossil Collection of the S.V.D. Catholic University of Peking and will
bear the provisional designation of CUP in the following report.

I am indebted to Dr. E. C. Olson through whose efforts the ma-
terials became available for study, and under whose guidance the

6 FIELDIANA: GEOLOGY, VOLUME 15

work was completed. I also wish to thank Dr. C. C. Young of the
Institute of Vertebrate Paleontology, Peking; Dr. C. C. Mook and
Dr. B. Brown of the American Museum of Natural History; Dr.
R. Zangerl of Chicago Natural History Museum; Dr. A. S. Romer
and Dr. B. Patterson of Harvard University, for their useful com-
ments. Dr. Young kindly provided supplementary drawings used
in the taxonomic determinations of many specimens. The bibli-
ographic aid provided by Mrs. Rachel Nichols of the American
Museum is gratefully acknowledged. The drawings were prepared
by Mrs. Julia Child.

GEOLOGY OF THE LUFENG BASIN

The geology of the Lufeng Basin was described in a paper by
Bien (1941) ; he arranged the list of vertebrate fossils from Young's
publication (1939a) in stratigraphic sequence. The stratigraphy of
the Basin was again reviewed generally by Young in his summary
paper (1951), but the annotated list of fossils was incomplete rela-
tive to the newly determined materials.

Lufeng is situated about 60 km. northwest of Kunming, the capi-
tal city of Yunnan Province. The tectonic history of Yunnan shows
that the Lufeng sediments were deposited in a structural basin formed
by the subsidence of the Central Yunnan Swell (Central Yunnan
Block) which had oscillated throughout the Paleozoic and had last
been revived in the Upper Permian. The structure is clearly recog-
nizable since late middle Sinian time; Misch (1945) states that the
structure underwent strong subsidence in the Triassic due to addi-
tional sedimentation. Chang (1947) constructed a paleogeographic
map (fig. 1) based upon the distribution of marine fossils which de-
lineated the margins of the raised Swell and demonstrated that the
Lufeng region was the site of terrestrial sedimentation. The uplift
of the Swell in Permian times apparently served as a barrier to the
transgressing Triassic sea that entered Yunnan from the south along
the Sino-Burmese geosyncline so that it diverged into east and west
waterways which continued in a northerly direction. During the
Triassic, then, the basin received only sediments of continental origin
typical of red bed development and flood plain environments. Inter-
fingering of marine and continental deposits occurs along the borders
of the Swell.

In Lufeng, the Lufeng Series has an aggregate thickness of about
1000 meters divided into a Lower Series of alternating beds of dull
purplish to dark red clays, siltstones, shales and sandstones, and into

SIMMONS: NON-THERAPSID REPTILES 7

an Upper (Shihmen) Series of greenish-yellow banded bed sandy
shales passing to variegated and wine red beds toward the top. The
wine red beds contain calcareous and evaporitic matter. A thick
green sandstone divides the red beds of the fossiliferous Lower Lufeng
Series. The entire column is capped by a sandstone and rests on a
basal breccia overlying the Sinian metamorphic rocks.

PRELIMINARY

MAP of YUNNAN

I I Probable Distribution of Land ) during
ESS! Probable Distribution of Sea ) t[me '°\

Fig. 1. A paleogeographic map of Yunnan Province showing the relative
distribution of land and sea during Triassic time (redrawn from Chang, 1947).

The Lufeng Series in toto is conformable with the Ipinglang Coal
Series below and with the Shihmen sandstone above (Misch, 1945).
Bien (1941) regarded the Shihmen as disconformable with the Lufeng
Series in Lufeng, but Misch held that the sandstone is "one horizon
in the upper part of the Upper Red Beds" of Yunnan and not a sep-
arable unit. The apparent local discordance indicates that deposition
of the Upper Lufeng Series was interrupted prior to the introduction
of sand. The Shihmen sandstone is current cross-bedded and passes
from a basal lenticular pebble to massive boulder conglomerate with
shaley intercalations toward the top. The Upper Lufeng Series is
also more highly variegated than most of the "Red Beds of Yun-

8 FIELDIANA: GEOLOGY, VOLUME 15

nan" and the calcareous clays and sandstones (with limestone bands)
are apparently of a finer texture in Lufeng.

The thick Lower Lufeng Series is characterized by saurian re-
mains. The thinner Upper Series contains fish {Hybodus, Lepidotus),
an indeterminate chelonian, fresh-water ostracods and minute pe-
lecypods and gastropods. The abrupt shift in the pattern of sedi-
mentation and faunas perhaps indicates that conditions favored the
establishment of shallow water environments, small lakes or pools
fed by streams bearing dissolved calcium salts that produced at times
the strongly indurated limestone bands of the upper-middle part.
The algal deposition of carbonate and evaporitic matter is also con-
ceivable. The fossil content and high degree of variegation is attrib-
utable to either a facies change, and /or to a change in the source area,
or to the inclusion of organic materials resulting in the partial re-
duction of iron. The second of these is indicated by the apparent
regularity of the bedding and by the reported absence of plant remains
to serve as reducing agents. The fauna indicates a facies shift; the
beds pass upward conformably to unfossiliferous strata of the same
general description as the bone-bearing beds of the Lower Lufeng
Series.

Bien (1941) assigned an Upper Triassic age to the whole of the
Lower Lufeng Series where saurian remains are found and called the
Shihmen Jura-Cretaceous. Misch correlated the very thick Upper
Red Beds of Yunnan, of which the Lufeng beds were considered a
part, to the red beds of the neighboring province of Szechuan and
suggested that they comprised "much of the Jurassic if they do not
even in some parts extend beyond it." Chang (1947) notes that de-
finitive Rhaetic beds have not yet been discovered in Lufeng. Misch
categorized the Lufeng sediments as T4, purple marly shale (from a
section at Taoyuan, about 8 km. north of Kunming). Since beds of
this description are only characteristic of the Upper Lufeng Series,
the idealized traverse is less than satisfactory. The more massive
Lower Lufeng Series, perhaps equal to T4 (purple sandy shale inter-
bedded with thin bedded sandstone) or T6 (red shale), should have
been included with the middle upper Triassic Noric Beds which ap-
parently embrace the Ipinglang Coal Series. Young's taxonomic
studies on the saurian elements indicate that the Lower Lufeng Series
had to have been deposited not earlier than Noric or post-Noric time.

The stratigraphic column and a map of the Lufeng Basin (figs.
2, 3) showing the leading collecting localities, have been redrawn from
Bien (1941). The vertebrate remains have been gleaned from four

SIMMONS: NON-THERAPSID REPTILES

~

fl

LITHOLOGY

NATURE

of
CONTACTS

AGE

SHIHMEN

.....

a

z
uJt/}

-"S '

a.
a.
zs

SJ

C9

Z

3

*

o

wo*

Capping Escarpment Sandstone

DISC ON

POSTLIAS

SERIES '

1-"-

•0*

Wine Red Beds

FOHMITY

«

tK>*

Variegated Beds

Greenish ■ Yellow Banded Beds

L _« _« _ »_»

140*

Dark Red Beds

fOKMlfT

UNCOMFOK

GO

<

OE
r-

ae

UJ

Q.
O-

Massive Green Sandstone

10*

" Dull Purplish Beds

LUFENG J

. Tati

I . . *

£-_T"- -Z Z

550*

Dull Purplish Beds

/ Tactions

-

Dull Purplish Beds

Basal Brecia

no

META-

MORPHIC-^

SERIES

iǤ

Metamorphic Series

MITY

PRE-
MBRIAN

Fig. 2. Stratigraphic section of the Lufeng Series showing the principal
collecting localities, Tachung, Hei Koa Peng and Ta Ti. (redrawn and modified
from Young, 1951).

rather narrow horizons, Fossiliferous Beds 1-4, ordered stratigraph-
ically from the lowest to the highest levels. The saurian elements
are known from the first and second zones traversing the Basin in a
north-northwest direction. The third and fourth zones are less ex-
tensively developed and are concentrated in the variegated beds of
the Upper Series; these have been correlated across to the sediments
of the nearby Anning Basin by the common occurrence of Hybodus.

Stratigraphic Section of the Lufeng Basin
Top (Young, 1951)

Upper Lufeng Series
8. Wine Red Beds (30 meters)

Alternating bright wine red clays, shales and sandstones with occasional
purplish earthy limestone. Rock salt, brine and gypsum occurs at
Yuanyungching, North of Ipinglang.

7. Variegated Beds (120 meters)

Upper two-thirds — Limey beds of purple, mauve, greenish and pink

sediments.

Lower one-third — Purplish limey beds with honeycomb weathering.

Lowest — Greenish mottled limey beds with fresh water unioids and

ostracods, Hybodus, Lepidotus and an indeterminate Chelonian.

10

FIELDIANA: GEOLOGY, VOLUME 15

6. Green-yellow banded beds (70 meters)

Dark red shales and ripple marked siltstones at the base passing upwards
to regular greenish yellow shale bands.

5. Red Sandstone (5-10 meters)

DlSCONFORMITY

Lower Lufeng Series

4. Dark Red Beds (150 meters)

Alternating beds of clays, shale, siltstone and sandstone with two sub-
ordinate layers of dull purplish elements. Fossils occur 70M above
Bed No. 3.

3. Massive Green Sandstone (20 meters)

Sediments contain occasional angular fragments of rocks, a breccia at
Yaochan. Quartzite and quartz derived from Sinian rocks.

2. Dull Purplish Beds (550 meters)

Alternating clays, shales, silstones and sandstone. Green sandstone
bands occur near the base. Calcareous nodular concretions are com-
mon as knobs or tubular masses. The beds are penetrated by calcite

Tachung-Shawan
Area

QUATERNARY

| Qal | ALLUVIUM.

Puo- pleistocene

1 I NP I I GRAVEL.SANDS&CLAY

JURA- CRETACEOUS

DULL PURPLISH-
BROWN CROSS BEDDED
SANDSTONES.

?Jk's.

UPPER -TRIASSIC

WINE-RED BEDS.
VARIEGATED BEDS.
GREENISH YELLOW
BANDED BEDS.

| DARKREDBEDS.

fiuT

MASSIVE GREEN
SANDSTONE.

I I DULL PURPLISH

r H BEDS.

I 1 BASAL BRECCIA.

SINIAN

| H | SUBMETAMORPHIC ROCK.
GEOLOGIC BOUNDARY

NORMAL FAULT. EXPOSED
& CONCEALED WITH
AMOUNT OF DIP

Fig. 3. Map of the Lufeng Basin showing the distribution of the fossiliferous
horizons and principle collecting localities (redrawn and slightly modified from
Young, 1951).

SIMMONS: NON-THERAPSID REPTLIES 11

streaks, veins or mottlings. Fossils occur 300M below Bed 3 and 200M
above Bed 1.

1. Breccia (5-20 meters)

Phyllite derived from the underlying rocks. Yaochan sediments con-
tain a quartzite and quartz brecchia.

PRESERVATION OF BONE

With few exceptions, the bones occur as weathered -out nodular
materials invested by a heavy scale of matrix and scattered about
on the surface of the ground. The rocks are so heavily indurated
with iron compounds that quarrying was difficult and articulated
skeletons were obtainable in only a few instances. Some remains
are suggestive of coprolitic material.

The field notes did not define the precise area of each collecting
site or the relative concentration and association of bone in every
case. Many individual fragments bearing the same field number were
either referred to several genera, or these contained specimens of the
same species but of different ontogenetic development. The proper
identification of other disarticulated but otherwise complete bones
was difficult because of the unavailability of comparative materials
and the morphologic similarity of the known Lufeng prosauropods
and carnosaur. For these reasons, a number of specimens could not
be treated effectively and were not considered in this paper.

Table 1 lists the fauna recognized by Young and also that newly
determined by this study. It will be noted that Oehler's collection
sampled most of the previously recognized non-Therapsids (?para-
suchian) and yielded many heretofore unrecognized forms. The new
finds are principally pseudosuchians and coelurosaurs. Their dis-
covery in effect, fulfills Young's first charge to future collectors (1951,
p. 92) that "special attention should be paid to the less known forms
such as parasuchians, pseudosuchians, possibly protosuchians. ..."

Table 1.— FAUNAL LIST OF THE NON-THERAPSIDS OF THE
LOWER LUFENG SERIES

Young (1951) New Material

thecodonts
Pseudosuchia

Platyognathus hsui Young: Platyognathus hsui Young:

anterior part of the jaw symphysis. a nearly complete skeleton.

CUP 2083

12

FIELDIANA: GEOLOGY, VOLUME 15

Young (1951)

Parasuchia

Pachysuchus imperfectus Young:
jaws.

Protosuchia

Microchampsa scutata Young:
vertebrae and dorsal armor.

New Material

Strigosuchus licinus:
jaw. CUP 2082

Dibothrosuchus elaphros:
a nearly complete skeleton.
CUP 2081

?Pseudosuchian:

a fragment of an ilium and femur.
CUP 2084

Microchampsa scutata Young:
vertebrae and dorsal armor.
CUP 2085, 2086

SAUROPODS

Coelurosaurs

Lukousaurus yini Young:

anterior half of a skull and jaws;
several limb fragments.

Carnosaurs

Sinosaurus triassicus Young:
a nearly complete skeleton.

Prosauropods

Lufengosaurus hueni Young:

several nearly complete skeletons.

Lufengosaurus magnus Young:
jaws and postcranial elements.

Yunnanosaurus huangi Young:
several nearly complete skeletons.

Yunnanosaurus robustus Young:
a nearly complete skeleton.

Gyposaurus sinensis Young:

many nearly complete skeletons.

ORNITHISCHIA

Lukousaurus yini Young:

anterior half of a skull and jaws.
CUP 2092

?Coelurosaur:

distal end of a femur and metacar-
pals. CUP 2089

?Coelurosaur:

distal end of a femur. CUP 2091

?Coelurosaur:

metatarsals. CUP 2090

Sinosaurus triassicus Young:

jaws, teeth and postcranial elements.
CUP 2097

Lufengosaurus hueni Young:
jaws and postcranial bones.

Lufengosaurus magnus Young:
jaws and postcranial elements.

Yunnanosaurus huangi Young:

a juvenile skull and postcranial ele-
ments.

Yunnanosaurus robustus Young:
postcranial elements.

Gyposaurus sinensis Young:

skull and jaw fragments and post-
cranial elements.

Tatisaurus oehleri:
a left jaw. CUP 2088

SIMMONS: NON-THERAPSID REPTILES 13

SYSTEMATIC CONSIDERATION OF THE
NON-THERAPSID REPTILES OF THE LUFENG FAUNA

Order Thecodonta

Suborder Pseudosuchia

Family Ornithosuchidae

Genus Dibothrosuchus, gen. nov.

Diagnosis.- — Skull elongate and extensively excavated by a large
triangular preorbital fenestra, a round orbit and a long infratemporal
vacuity; roofing bones depressed below the superior margin of the
orbit. Lower jaw slender, possessing a long narrow lateral fenestra.
Teeth laterally compressed, finely denticulated and somewhat re-
curved.

Neck short, cervical vertebrae not elongate; their centra sharply
compressed and keeled, and the anterior zygapophyses very steep.
The dorsal vertebrae less sharply compressed backward. Three sa-
cral vertebrae possessing broadly triangular ribs. The presacral series
show costal articulations oriented in an upward and backward direc-
tion. The first seven caudals are in natural connection with the
sacrum and are not especially elongate.

The appendicular skeleton, consisting of the forelimb and several
metacarpals, is slender and the bones are thin-walled and hollow.

Dibothrosuchus elaphros, sp. nov.

Holotype. — A partially complete skull and jaws, a series of articu-
lated vertebrae from the cervical, dorsal, sacral and caudal regions
of the column, and a fragment of the forelimb and hand. The bones
are of a reddish color encrusted with a thick greenish matrix. Cata-
log no. CUP 2081.

Horizon and locality. — Ta Ti, Dark Red Beds, Lower Lufeng
Series.

Diagnosis. — Same as for genus.

DESCRIPTION

Skull (fig. 4,A): The skull is lightly built and broadly fenes-
trated; the roofing elements are thin and crushed, and the paired
bones overlap. The ventral surface bears grooves interpreted as im-
pressions of the nasal tracts and cortical regions of the brain; the

14 FIELDIANA: GEOLOGY, VOLUME 15

nasal, prefrontal, and frontal bones must be represented in part but
sutural contacts are obliterated. The supraorbital contours of the
frontals and prefrontals form elevated ridges which pass forward and
become confluent with the nasals above the preorbital fenestra. The
median suture is slightly depressed and the frontal is plicated by an
additional pair of furrows mediad to the supraorbital ridges. The
supraorbital eminences project downward to sheath the dorsal orbits
externally so that the eye muscles reside in deep pockets bordered in-
ternally by the ventrolateral furrows delimiting the brain structures.

Premaxilla (fig. 4,B2): The extreme tip of the snout is lacking
and the relationship of the premaxilla to the external nares and maxil-
lary is uncertain. The dentition indicates that the bone is present
but probably exclusive of its suture with the nasal. The nasal tracts
are seen on the median side by a concavity bounded from below by a
palatine fragment; the external nares, then, lay laterally on the snout
at the same level as or slightly lower than the antorbital fenestra.

Maxilla (fig. 4,B2): The maxilla projects dorsally about the
anterior corner of the triangular preorbital fenestra and terminates
posteriorly under the anterior orbit. The bone is gradually replaced
by the jugal and its inferior border is down turned.

Jugal (fig. 4,B2): The jugal is a triradiate bone. It replaces
the maxilla anteriorly and forms the two ascending bars delimiting
the orbit from the antorbital and infraorbital fenestrae. The bone
projects posteriorly and somewhat outwardly to bound the infra-
temporal opening from below and to contact the quadra to jugal ele-
ment. The inferior surface is flat.

Quadrate (fig. 4,B2): The quadrate has been displaced during
preservation, and lies horizontally above the surangular-angular com-
plex of the jaw. It is a triangularly concave bone which bears a
gently curved, broad articular facet, and a distinct vertical anterior
supporting ridge on the lateral side. The inner surface is rugose and
probably fragmented.

Pterygoid (fig. 4,B2): An irregularly shaped flat element, per-
haps the quadrate process of the pterygoid, lies in front of and touches
the quadrate. The straighter anterior part has a finished border and
may represent the incipient flange of the lateral process.

Quadratojugal: A problematic quadratojugal fragment lies above
the surangular-angular complex of the jaw and contacts the quadrate
and pterygoid. Its features are quite indistinct.

The skull is lightly built on the ornithosuchian pattern. The or-
bital contours are similar to Ornithosuchus and Hesperosuchus agilis

I 1 = 10 mm.

Fig. 4. Dibolhrosuchus'elaphros (gen. et sp. nov.). A, Fragment of the skull
roofing bones— dorsal (1) and ventral (2) views. B, Left lower (1) and upper (2)
jaws. (CUP 2081).

15

16

FIELDIANA: GEOLOGY, VOLUME 15

Table 2.— MEASUREMENTS OF DIBOTHROSUCHUS ELAPHROS

(in mm.)

Skull

Length of the skull "cap"

Preserved length along the inferior margin

Ventral length of the preorbital fenestra

Maximum breadth (anteroposterior) of the orbit.

Ventral length of the infratemporal fenestra

Length of the maxilla

Jaw

Preserved length

Height: broken anterior end

20 mm. back of symphysis

anterior margin of the lateral fenestra .

constriction posterior to the fenestra . .

Length of the mandibular fenestra

Length of the tooth row

left

157.0
11.2
10.2
20.0
14.3
29.0

Maxillary Teeth

Fragment of the largest robust tooth

basal breadth

length (lacking tip)

Basal breadth of the crown at the symphysis .
Length of the crown at the jaw symphysis. . .

Right Side

1

2

3

4

5

6 (replacement ?)
7

9.
10.

Mandibular Teeth
Length of the tooth at the symphysis (lacks the crown)

83.0
128.0
38.5
28.5
23.0
73.0

right
101.0

34.6

left

right

5.0

5.0

7.3

2.5

10.0

length

breadth

7.8

3.4

7.0

3.1

7.0

3.2

7.0

3.0

6.8

3.0

3.0

5.2

2.8

2.9

1.9

4.1

2.0

3.6

1.9

length

breadth

7.0

2.3

Colbert (1952) and the ventral skull of the latter features nearly
identical endocranial impressions. The position of the external nares
high on the skull, either dorsally in Cerritosaurus binsfeldi Price
(1946) or above the anterior angle of the preorbital fenestra in Salto-
posuchus connectens and S. longiceps Huene (1921), excludes these
forms from direct comparison. The preorbital fenestra in Dibothro-
suchus is neither aetosaurid-like as in Erpetosuchus granti Newton
(1894), nor crescent-shaped as in Prestosuchus chiniquensis Huene
(1936, drawing by Price, 1946), nor as tiny as that of Cerritosaurus.
Broadly oval orbits are known for Saltoposuchus connectens, Sclero-

SIMMONS: NON-THERAPSID REPTILES 17

mochlus taylori (Huene, 1914-15) and Hesperosuchus, but the supra-
orbital borders are "wulstig erholt" or padded in the latter two
forms, and elevated above the roofing bones in Ornithosuchus and
Hesperosuchus.

The infratemporal region of the skull of Hesperosuchus was not
preserved, but the associated fenestra lies slightly below and back of
the orbit in Dibothrosuchus. Conversely, the orbit overlaps the in-
teroanterior angle of the fenestra in Scleromochlus, or lies high above
the fenestra in Prestosuchus, due to the depression of the inferior
skull contours.

The quadrate bones of Hesperosuchus and of the present form are
very similar although the articular surface is broader and the sup-
porting ridge is better developed and more anteriorly located in Dibo-
throsuchus. The skulls of each in toto are equal in length to nine to
ten dorsal vertebrae.

Maxillary Dentition (fig. 4,B2) : The left maxilla holds 12 imper-
fectly preserved thecodont teeth which become successively smaller
posteriorly. The stoutest and largest lies 10.0 mm. in front of the
preorbital and is succeeded by a gap accommodating two teeth. A
less robust tooth lies below the anterior corner of the preorbital, fol-
lowed by nine to ten teeth with alveolae for three to four others.
The complete maxillary series numbers 16 to 18 teeth; the anterior-
most slope backward but the others are erect. The teeth are broad
laterally compressed, slightly recurved with sharp and finely den-
ticulated (16/1.0 mm.) posterior edges.

The right maxilla (fig. 5,A) holds well-preserved teeth which
are laterally compressed but slightly convex, pointed and equipped
with sharp trenchant edges. The crowns of two slender premaxillary
teeth are embedded in the matrix of the symphyseal fragment.

The left dentary (fig. 4,B1) holds the roots of 10-11 teeth of
uniform size which are weaker than the maxillary series. The fourth
root opposing the robust maxillary tooth is also the largest. The
complement of the right jaw is masked by the opposed maxillary
series.

The development of canine-like teeth in the front of the maxilla
is common among Pseudosuchia. The individual teeth compare
more favorably with those of the coelurosaur Halticosaurus orbito-
angulatus Huene (1932) than with the lanceolate type in Hespero-
suchus, but the overall pattern — a needle-like premaxillary tooth
passing to a more robust tooth posteriorly — is hesperosuchid.

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SIMMONS: NON-THERAPSID REPTILES 19

VERTEBRAL COLUMN AND RIBS

Cervical Series (Table 3): Seven vertebrae were found with the
skull. The anterior two are isolated. A fragmented series of four
vertebrae is presumably from the more posterior region of the neck.
A single, and the last cervical, articulates with the dorsal column.

Centra (figs. 5,B,C,): The centra are of moderate length, are
strongly compressed, ventrally furrowed, and have flat articular sur-
faces. The anteriormost develop a prominent longitudinal ventral
ridge which is less manifest in the last. The vertebrae are separated
at the neurocentral suture by relatively wide spaces which indicate
a regional specialization and functional involvement with the passage
of the spinal nerves to the forelimb.

Par apophyses: The parapophyses lie on the anterior ventrolateral
margin of the first centra, but they migrate upward to the neuro-
central suture (fourth vertebra present) to form the base of the ante-
rior supporting lamella of the transverse process. The parapophyses
undergo a concomitant outward rotation posteriorly and they are
triangular in cross section.

Transverse Processes: The transverse processes of the isolated ver-
tebrae are flat and broad structures which project downward over
the neurocentral suture and parapophyses. They lie higher upon the
neural arch of the second -fourth vertebrae of the articulated series,
and are supported by lamellae which converge from the margins of
the suture; these are stouter structures and rotate upward and out-
ward posteriorly in the series. The processes lie just back of the
parapophyses in the first articulated vertebrae, over the parapophy-
ses in the fourth, and behind in the last cervical.

Zygapophyses: The anterior zygapophyses are high on the isolated
centra; they project forward beyond the margin of the centra, but
at somewhat a lower angle than those of the articulated column.
Concomitant with the rotation and upward migration of the dia-
pophyses posteriorly, they become progressively lower and little more
than medial extensions of the dorsal surface of the diapophyses.
Their facets are oblique and inwardly directed anteriorly but more
outwardly diposed posteriorly.

The posterior zygapophyses are continuous with the diapophyses.
In the articulated series, they diverge sharply and extend beyond the
limits of the centra at successively lower levels. Since the fourth
articulated centrum is also the shortest, the adjustment in zygapo-
physial height might limit the amplitude of lateral motion of the neck.

20 FIELDIANA: GEOLOGY, VOLUME 15

Neural Spines: Although these are all broken off at their bases,
they are all apparently erect or slightly anteriorly directed. Their
cross sections are roughly triangular, sharp in front and broader in
back, i.e., about 2.0 mm. and 4.0 mm. respectively.

Ribs: An isolated rib (Table 3; fig. 5,B1) embedded in a rock
fragment shows that the anterior ribs are plow-shaped in typical
archosaur fashion. The rib has a ventrolateral longitudinal groove
formed by an expansive inferior surface.

The more posterior cervical ribs become greatly elongate and
slender. A capitular fragment is associated with the second verte-
bra of the articulated series in hemapophysis fashion. The heads of
two nearly complete ribs lie between the second and third and the
third and fourth centra and their shafts are fused to the anterior dor-
sals. During preservation, the column was broken and the posterior
cervicals lay at an acute angle to an articulated fragment of the an-
terior dorsal column. Measurements of the distances between the
tuberculum and capitulum (7.0-8.0 mm.) show that these ribs were
associated with the second and third articulated cervical centra.

Summary: The cervical column tends to become slightly shorter
backwards. The anterior zygapophyses are high and forwardly pro-
jecting in front but become shorter and more erect backwards. The
parapophyses migrate upward to the neurocentral junction. Ante-
riorly, the transverse processes are directed downward; posteriorly,
these become stouter and rotate upward, outward, and, in the last
cervical, somewhat forward. The neural spines are missing but must
have been erect or slightly anteriorly directed.

Dorsal Series (Table 4; figs. 5,D,E) : The dorsal columb is near
ly completely represented by eleven vertebrae in two articulated
series, each of which contains fragments of a single centrum. Since
these fragments do not fit together, it is likely that there was a single
intervening dorsal to bring the number in the column to fourteen.
The reconstructed series may be divided into two segments such that
in one, the first nine dorsals, the parapophyses and diapophyses are
separate. Costal union probably occurred in the tenth vertebra since
the processes are co- joined from the twelfth to the fourteenth.

Centra: The centra are weakly constricted and are distinguished
from the cervical series by their smooth, round, unfurrowed surfaces.

While the costal articulations are poorly preserved on the left side
and are masked by the associated cervical ribs on the right, it is cer-
tain that the migration of the parapophyses from the centra to the
neural arch was completed in the last cervical vertebra.

I 4=10 mm.

I 1* 10 mm.

Fig. 5. Dibothrosuchus elaphros (gen. et sp. nov.). A, maxilla and dentary
fragment. B, cervical rib (1) and vertebra (2). C, A series of four posterior
cervical vertebrae viewed from the right side. D, A fragment of the dorsal verte-
bral column viewed from the right side including the last cervical vertebra and
two cervical ribs. E, An articulated series of posterior presacral, sacral, and an-
terior caudal vertebrae viewed obliquely from below. The sacral ribs and hema-
pophyses are shown. (CUP 2081).

21

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22

SIMMONS: NON-THERAPSID REPTILES 23

With the exception of the last or fourteenth dorsal, the costal
articulations and the posterior zygapophyses of each vertebra are
connected by a bony lamella directed upward and backward. The
lamella of the fourteenth is relatively parallel to the long axis of the
column. The relation of the parapophyses to the anterior zyga-
pophyses is somewhat variable throughout.

Parapophyses: The bony lamella essentially passes through the
midplane of the parapophysis. The processes are rounded (4.0 mm.
in diameter) with concave facets for the capitula of the ribs and they
extend outward some 8.0 mm. In the first six dorsals, the para-
pophyses lie just back of the anterior margin of the centra and under
the posterior half of the anterior zygapophyses. In the seventh and
eighth they migrate slightly backward. In the ninth dorsal it lies
under the zygapophysis.

The costal articulations fuse rather abruptly at the level of the
tenth or eleventh vertebra; the distance between the parapophyses
and diapophyses does not appear to decrease gradually in the latter
part of the column, i.e., 1-9 (?10).

Transverse Processes: The lateral projection and basal breadth of
the processes are progressively reduced from the first-ninth verte-
brae. They are supported by two rather vertical lamellae on the
second dorsal. The processes are flattened above from the twelfth-
fourteenth dorsal.

Zygapophyses: In the first six dorsals, the anterior zygapophyses
are low as in the posterior cervicals, but become progressively higher
from the seventh-thirteenth. Early, their facets are oblique, but
they rotate outwardly in the last half of the series. The posterior
zygapophyses are longer than the anterior processes and project be-
yond the end of the centra. The articulation between the thirteenth
and fourteenth dorsals is nearly horizontal. Such an arrangement
would tend to reduce the vertical motion of the posterior presacrals.

Neural Spines: The neural spines are relatively long, low and
broad. They project forward only slightly, but are more generally
erect from the eleventh -fourteenth dorsal. Only a few are com-
pletely preserved.

Ribs: Several proximal fragments of broad flat ribs were fused
during preservation to the neural spines of the thirteenth and four-
teenth dorsal vertebrae.

Summary: There is a general tendency for the vertebrae to in-
crease in length throughout the dorsal column although the sixth

24 FIELDIANA: GEOLOGY, VOLUME 15

dorsal is the longest. The costal articulations become fused toward
the sacrum and the zygapophysial articulations become more hori-
zontal to restrict the vertical motion of the spine. Several broad rib
fragments are associated with the last two presacral vertebrae, but
it is questionable whether these can be considered to belong to this
specimen.

Sacral Series (Table 5; fig. 5,E): The sacrum is composed of
three vertebrae with broadly rounded ventral surfaces. The first
two are articulated but the third has been transversely broken at its
mid-length. The total length of the articulated sacrum is 56.3 mm.
(1st, 18 mm.; 2nd, 14.5 mm.; 3rd, 13.8 mm.) along their ventral
lengths. The successive vertebrae decrease in length; the neural
complex of the second and third are fused. The first and third centra
are more strongly compressed than the second which is compara-
tively massive.

None of the neural spines has been preserved save that of the
first which is supported by high lamellae most probably continuous
with the posterior zygapophyses.

The anterior zygapophyses lies at the level of the sacral ribs on
the first vertebra but are raised high above the neurocentral suture
in the second and third. The zygapophyses of the first vertebra ap-
pear to be partially fused to the posterior zygapophyses of the last
presacral. The neural articulations of the second and third sacrals
also seem to be fused.

The posterior zygapophyses of the first and second sacrals are
elevated high above the neurocentral junction and are continuous
with the lamellae supporting the neural spines. They originate at
the posterior border of the sacral ribs.

Ribs (fig. 5,E) : The first sacral lacks ribs. These, however, are
represented by a scar at the anterior margin of the neurocentral
suture (height, 11.3 mm.; breadth, 8.0 mm.).

The second left sacral rib lies on the posterior half of the vertebra.
It is dorsoventrally flat and irregularly triangular. The anterior
border extends outward and slightly backward for half its length,
and turns forward distally; the posterior border is straight and pro-
longed backward. The facet receiving the ilium is expansive and
lies at the anterior corner. Distally, the rib becomes rather flat but
the facet receiving the ilium of the pelvis is expansive at the anterior-
most corner.

The third sacral bears a fragmented narrow transverse process
opposing the posterior border of the second rib.

SIMMONS: NON-THERAPSID REPTILES

25

Table 5.— MEASUREMENTS OF THE SACRAL SERIES OF
DIBOTHROSUCHUS ELAPHROS (in mm.)

Vertebral

No. *V.L.

I 18.0

II 14.5

III 13.8

I

II

III

L.AB.

14.2

20.5

A.H.
14.9
11.0
13.0

L.PB.
19.0

A.B.
13.0
13.1
13.6

Vertebra

M.B.

8.3

13.5

10.0

D.B.

21.7

Rib
Pr.B.
13.3

Single Rib
?20.8 ?13.3

Ht.
Az.+C.

22.0
?21.0
?19.0

D.F.
10.0

12.1

*V.L.- Ventral length L.AB.

A.H.: Anterior height L.PB.:

A.B.: Anterior breadth D.B.:

M.B.: Median breadth Pr.B..

Ht. Az.+C. Height, ant. zygapophysis + centrum D.F.

Ht. Ns.+C: Height, neural spine + centrum B.F.:

Ht.

Ns.+C.
28.6

B.F.
12.3

13.8

Length, ant. border
Length, post, border
Dorsal breadth
Proximal breadth
Dorsal facet
Breadth of facet

A fragment of a triangular rib similar to that of the second sacral
is associated with these remains. Its articular facet for the ilium is
considerably larger.

Caudal Series (Table 6; fig. 5,E): The postsacral vertebrae are
only partially represented. The first six caudals form an articu-
lated series with the sacrals. The more distal vertebrae occur as
multiple fragments.

Centra: The first six caudals are quite uniform. The centra are
squarely constructed and compressed with broadly rounded and fur-
rowed ventral surfaces; haemapophyses are associated with each.
The smaller distal centra are similar in form ar.d presumably amphy-
coelous. Except for one very distal element, the articulated frag-
ments are transversely broken at the mid-part of the terminal centra.

Neural Spines: The neural spines, while incompletely preserved
are clearly directed anteriorly.

Transverse Processes: The processes lie at the center of the ver-
tebrae and project somewhat outward and downward, on the first
caudal. They gradually rotate upward and backward in the second -
fifth to juxtapose the posterior zygapophyses. A lamella, similar to
that noted for the dorsal series, unites the bases of the transverse
processes and the posterior zygapophyses in the fourth -sixth caudals

26

FIELDIANA: GEOLOGY, VOLUME 15

and, in the last, the diapophysis lies under the zygapophysis. The
terminal vertebrae lack diapophyses entirely.

Zygapophyses: The anterior zygapophyses become progressively
lower and more oblique posteriorly, but project at a low angle beyond
the margin of the preceding centrum. From the fourth vertebra
posteriorly, the anterior zygapophyses form a costal-neural "articular
clump" with the posterior zygapophyses and transverse process of
each antecedent vertebra. The posterior zygapophyses are short
and widely divergent.

Table 6.— MEASUREMENTS OF THE CAUDAL SERIES OF
DIBOTHROSUCHUS ELAPHROS (in mm.)

Position

L.

in Series

*V.L.

A.H.

A.B.

M.B.

Az-Pz

L.AC.

L.Hen

Anterior Caudal Series

1

13.3

14.6

8.7

18.5

12.7

2

12.5

11.6

8.0

17.8

12.5

3

10.0

10.6

7.3

17.2

11.3

4

10.0

10.9

7.0

17.0

10.2

?18!6

5

12.0

9.7

7.4

17.0

9.6

?21.4

6

12.5

9.0

18.0

8.7

Posterior Caudal Fragments

1

11.0

10.2

8.4

5.5

15.3

8.0

2

12.3

9.1

8.1

6.2

13.0

7.3

3

10.0

12.6

9.0

6.9

17.7

?8.2

4

10.6

5.5

17.7

7.4

5

10.5

8.2

16.6

Posterior Caudal Fragments

1

?9.0

7.2

6.0

7.5

13.5

2

10.0

7.5

6.0

7.7

15.0

3

10.0

7.5

5.7

3.7

?12.0

*V.L.: Ventral length
A.H.: Anterior height
A.B.: Anterior breadth
M.B.: Median breadth

L.Az-Pz.: Length, tip ant. zygapophysis-tip post, zy-
gapophysis
L.AC: Length, articular 'clump'
L.Haem.: Length, hemapophy sis

Hemapophyses: Chevron bones are associated with all but the
terminal centra; the rami are delicate and fuse distally. These are
best preserved between the fourth and fifth, and fifth and sixth
vertebrae.

The anterior cervical column of Dibothrosuchus is best compared
to those of Hesperosuchus and Parringtonia gracilis Huene (1939a),
although these vary somewhat proportionately, and their centra are
more compressed and narrowly rounded below. The anterior pre-

SIMMONS: NON-THERAPSID REPTILES 27

sacrals of Parringtonia (Huene, 1939a, fig. 5) compare well to the
seventh -eighth dorsals of the present form where the neural arch
bears costal articulations connected by a common ascending lamella,
and erect anterior zygapophyses. The anterior projection of the
zygapophysial articulations of the imperfectly preserved dorsal col-
umn in Hesperosuchus is of the dibothrosuchid-type; the parapophy-
ses and diapophyses are similarly arranged in Stagonosuchus nyassicus
Huene (1939b) but lack the common lamella. The rather horizontal
orientation and length of the posterior zygapophyses of the posterior
presacrals is similar to Parringtonia and Hesperosuchus, but the poorly
preserved neural spines lack terminal expansions for the articulation
of the dorsal armor in the former (Huene, 1939b, figs. 8, 10) and in
Stagonosuchus (Ibid, fig. 11). The presacral column cannot be com-
pared further to other ornithosuchia such as Erpetosuchus (which has
weak costal articulations) which differ markedly also in their skull
patterns.

The sacral and caudal vertebrae are flatter and more broadly con-
structed than those of Hesperosuchus, and the latter do not bear
ventral longitudinal ridges evidenced in Parringtonia.

Table 7.— MEASUREMENTS OF THE GIRDLE AND FORELIMBS OF
DIBOTHROSUCHUS ELAPHROS (in mm.)

CORACOID , .. . . .

Length of: left n&ht

base of glenoid fossa to posterior crest 29 . 6

dorsal crest 24 . 6

articular facet for scapula 14 .0

Breadth of articular facet for scapula 9.0

Length of free finished border of coracoid-dorsal 10.6

Breadth of glenoid region 11.0

Depth of glenoid region 9.6

Humerus

Length of head to posterior tuberosity (maximum) 26.4 25.0

Dorsoventral breadth at crest 11.7 10 .2

Breadth (anteroposterior) above crest 16.3 15.0

Breadth, neck just above condyles (lateromedial) 12.0

Thickness, neck just above condyles (anteroposterior) 8.2

Breadth of condyles (maximum lateromedial) 18.3

Thickness, lateral condyle 7.6

Thickness, medial condyle 7.2

Length, intermediate protuberance 11.5 11.0

Length of humerus (allowing 6 mm. for sectioned ends) :

proximal element 48.3 40 . 0

distal element 58 . 0 ....

Estimated total length 116.3

5 i 1 = 10 mm.

10 1 | = i0mm

28

SIMMONS: NON-THERAPSID REPTILES 29

PECTORAL GIRDLE

(Table 7, Fig. 6,A)

The pectoral girdle is known by a left proximal fragment of the
coracoid. The bone must have been loosely connected to the scapula
since the superior border is finished except for a roughly triangular
area in back of the glenoid region, and it rotates inward posteriad
(effect of pressure?) . The posterior surface is roughened to indicate a
cartilaginous cap. The ventral border is finished. The lateral surface
is concave and bears an extensive fossa for the M . supracoracoideus.

The glenoid fossa formed by the scapula and coracoid is flared
laterally and bears a lateral tubercle which probably represents an
incipient acromion for the triceps muscle. The glenoid is set off below
by a sharp notch and a marked fossa; the bone is narrow and may
have been distally elongate.

The inner surface is concave and perforated by a foramen (supra-
coracoid) which enters at a superior post-glenoid depression and
emerges at the level of the acromion in the forward wall of the supra-
scapular fossa.

APPENDICULAR SKELETON

(Table 7)

Fragments of the forelimb were segregated from a number of in-
determinate limb bones associated with the skull and vertebrae on
the basis of their common histologic structure and hesperosuchid-like
configuration.

Humerus (fig. 6,B): The humerus is long, slender and proxi-
mally expansive; the shaft is bent medially. The head is rounded
and positioned at the anterior inferior angle. A large, rather flat,
semilunar internal tuberculum lies just posteriad to the head and
projects over the crest to the dorsal side. More posteriorly and at
approximately right angles, the dorsal crest emanates from the ven-
tromediad wall as a strong ridge and passes distally to the neck of
the bone. The ridge is acute above the apex which is swollen and
roughened for muscle attachment.

Fig. 6. Dibothrosuchus elaphros (gen. et sp. nov.). A, Coracoid, viewed
from the medial (1), glenoid (2), and lateral (3) surfaces. B, Humerus, left
(1-5) and right (6-10) proximal fragments viewed from the medial (1, 6), dorsal
(2, 7), ventral (3, 8), and articular (5 ,10) surfaces. (CUP 2081)

30 FIELDIANA: GEOLOGY, VOLUME 15

The proximal end of the humerus is dorsoventrally convexocon-
cave and the deltopectoral crest is set off from the dorsal surface by
a narrow sulcus. The ventral surface becomes flatter distally.

The distal segment of the left humerus (fig. 7,A) curves laterad
to give the bone an overall sigmoid configuration. The condyles are
subequal in size; the anterior, or radial, is the longer, rather triangu-
lar in cross section, and its articular surface is delimited from above
by a Y-system of ridges. The posterior ulnar condyle is broad and
its articular surface is ventrally diposed. A transverse ridge con-
nects the condyles on the dorsal surface of the bone. The trochlea
is marked by a shallow intermediate depression.

Ulna (fig. 7,B) : The ulna is known from a dorsoventrally com-
pressed, moderately expansive proximal fragment which evidences
a prominent olecranon process; the medial surface is irregular and
asymmetrical.

The surface articulating with the humerus is divided by a mod-
erately elevated ridge occupying the trochlea and is plateaued. The
depression receiving the lateral condyle is the broader and deeper of
the two but the arrangement would probably not restrict the rotation
of the forearm to any great degree since the elements were undoubt-
ably capped by cartilage.

Radius (fig. 7,B): Only the head of the radius is represented.
It is broad and shows a semilunar depression for the articulation with
the humerus. Its shaft is slender and dorsoventrally flattened.

The girdle of the present form is distinguished from other ornitho-
suchians in that (1) the coracoid and scapula were apparently loosely
associated, (2) the glenoid is strongly rotated outward and (3) the
subglenoid fossa is acute rather than broad. The glenoid fossa here
has a more open face, but lacks both development in breadth and an
accessory lateral process (?acromion) for the triceps muscle.

The pseudosuchian humerus is generally characterized by broadly
expansive ends (Stagonosuchus and Erpetosuchus) , but the slender-
ness of the shaft, position and development of the deltopectoral crest,
and condylar inequality in the present form is closest to Hespero-
suchus. The coelurosaur Halticosaurus longotarsus Huene (1921,
pi. IV, fig. 7) also shows rather similar condylar proportions.

The proximal part of the ulna is constructed like that of Hespero-
suchus, and the olecranon and dorsal oval depression are equally well
developed. The sigmoid notch is, however, less strongly platformed
and the humerus-ulnar articulation is simpler in Hesperosuchus. The

SIMMONS: NON-THERAPSID REPTILES 31

peculiar nature of the joint would facilitate a fast running habit,
allowing for a strong fore-aft motion with perhaps little rotation of
the elements. The animal was probably quadrupedal since the
humerus is elongate, and Romer (1956, p. 373) notes that the olec-
ranon (origin of the triceps muscle), little developed in dinosaurs,
appears in secondarily quadrupedal forms; its presence is presumably
associated with a secondary return to a more flexed position of the
forearm.

The osteology of the skull and appendicular skeleton indicates a
hesperosuchid-like animal, but the form is slightly larger. The dif-
ferences in the jaw, skull and vertebral column are conspicuous (the
latter approaching Parringtonia most closely). The limb structure
is perhaps more highly specialized for a cursorial way of life.

Order Thecodonta

Suborder Pseudosuchia

Family Ornithosuchidae

Genus Strigosuchus, gen. nov.

Diagnosis. — Jaw slender; lower margin straight but sharply up-
turned at the symphysis. A flat splenial element sheaths the inner
wall. The jaw bears only one preserved tooth.

Strigosuchus licinus, sp. nov.

Holotype. — A fragment of a left mandible, slender and upturned
at the symphysis. Catalog number CUP 2082.

Horizon and locality. — Ta Ti, from the Dark Red Beds of the
Lower Lufeng Series.

Diagnosis. — Same as for genus.

DESCRIPTION

Jaw (Table 8; fig. 7,C): The mandible is slender and upturned
at the snout. Its outer wall is convex although flattened anteriorly;
the inner or medial wall is flat in front becoming more concave pos-
teriorly below the alveolar border. The preservation of the material
was accompanied by distortion and checkering of the bone, but the
sutures are clearly marked. The outer wall of the dentary has been
broken away to expose the internal architecture of the jaw, and the
articular bones are incomplete.

"10mm. /L^g^Oi

Fig. 7. Dibothrosuchus elaphros (gen. et sp. nov.). A, Left humerus, distal
fragment viewed from the ventral (1), lateral (2), and articular (3) sides. B, Ulna
and radius, proximal fragments in articular (1), medial (2), and lateral (3) aspect
(CUP 2081).

Strigosuchus licinus (gen .et sp. nov.). C, Jaw in lateral view. (CUP 2082).

Sinosaurus triassicus Young. D, Jaw fragment posterior to the symphysis.
(CUP 2097).

Coelurosaur (CUP 2090). E, Fused metatarsals in dorsal view.

32

SIMMONS: NON-THERAPSID REPTILES 33

Table 8.— MEASUREMENTS OF THE JAW OF
STRIGOSUCHUS LICINUS

mm.
Superior border from broken tip to end of fragment, i.e., lateral

fenestration 49.6

Inferior border from broken tip to posterior fracture of angular .... 47.2

Anterior height of jaw at broken tip 7.0

Height of dentary just posterior to preserved tooth 8.3

Height of jaw at posterior fracture 12 .0

Basal length of tooth root 2.7

Height of preserved portion of tooth minus crown 2.7

Anteroposterior length of second preserved alveolus 2.5

The jaw appeared upon initial examination identical to Chasmato-
saurus yuani Young (1936). Closer inspection revealed that the sur-
face of the posterior outer fracture was in part finished — evidence
that, unlike proterosuchians, the jaw was fenestrated. The man-
dibles of Hesperosuchus and Dibothrosuchus are similarly formed, and
the symphysis in each bears the greatest concentration of foramina.
Further comparison is rather limited for reasons given below.

In the present specimen, a flat spenial bone covers the inner sur-
face of the jaw at the symphysis and contacts the dentary along the
inferior margin of the ramus. The posterior portion has been dis-
placed upward and outward by compression during preservation; it
encroaches upon the dentigerous border to effect the postmortem loss
of the teeth. Forward of the jaw articulation, the splenial wraps
about the angular bone.

The meckelian groove passing forward on the inside of the jaw
from an oblique nubbin (7.0 mm. long) of the angular bone is limited
by a long dorsal prearticular element which pinches out anteriad and
disappears below the symphyseal portion of the splenial.

The damage to the dentigerous border incurred by the displace-
ment of the splenial does not allow us a precise knowledge of the
dental complement. It is, however, likely that the jaw held 14 to 15
teeth. The single root of a large compressed, somewhat recurved
tooth which is most chasmatosaurid-like, lies toward the end of the
tooth row and its anteroposterior breadth is equal to the length of
the first and second alveolae at the symphysis. Only the first four
alveolae are sufficiently well-preserved to indicate the size of the
teeth, but it is not known whether these were enlarged like those of
Ornithosuchus and Pedeticosaurus leviseuri van Hoepen (1915; Haugh-
ton, 1924). The teeth of Hesperosuchus are contrastingly lanceolate,
and the jaw is three times as large as that of Strigosuchus.

34 FIELDIANA: GEOLOGY, VOLUME 15

Irrespective of the general chasmatosaurid configuration of the
jaw and teeth, the presence of a lateral mandibular fenestra indicates
that the present form should be referred to the ornithosuchian pseu-
dosuchians. The specimen is regarded as a new form for which the
name Strigosuchus licinus (gen. et sp. nov.) is proposed.

Order Thecodonta
Suborder Pseudosuchia
Family Platyognathidae (fam. nov.)

Platyognathus hsui Young (1944)

Platyognathus hsui was named by Young (1944) from a jaw frag-
ment, and was assigned to the pseudosuchia. Since then, its ultimate
position in the scheme of classification has been speculative at best
in view of its fragmentary nature. Young failed to relate it with the
well-known primitive South African forms, and stated that it might
represent an entirely new family. Huene (private communication;
Young, 1951) suggested Platyognathus as a forerunner of the Orni-
thischia since, following the contours of the jaw, the snout was inter-
preted to be expansive. Romer, earlier (1955), concurred with
Young's tentative assignment, but later (1956) referred it to the
Notochampsidae (Protosuchidae) . Pivateau (1956) suggested a re-
lationship to the pseudosuchian Stagonolepidae.

The type specimen, No. V71, Cenozoic Research Laboratory,
National Geologic Survey of China, consisted of the anterior part
of a pair of jaws bearing alveolae for 11 and 12 teeth in the left and
right sides respectively. The preserved dentition was restricted to
a single damaged canine-like tooth on the right side.

Additional Material. — The newly available material includes a
partially complete jaw and skull, and armored postcranial elements.
All but the sacrum of the vertebral column is represented in part,
and the pectoral girdle is complete on both sides. The appendicular
skeleton is not represented. Catalog No. CUP 2083.

Horizon and Locality. — Ta Ti, Dark Red Beds, Lower Lufeng
Series.

Diagnosis.- — Skull V-shaped, low, flat and terminally expansive
at the snout; external nares unpaired; symphyseal teeth anteriorly
directed, polygonal in cross section. Lumbar and caudal regions of
the body completely invested in armor; vertebrae procoelous.

SIMMONS: NON-THERAPSID REPTILES 35

DESCRIPTION

Skull (Table 9; figs. 8,A1-3,D): The skull is complete from the
snout to the antorbital fenestra. The dentition is completely repre-
sented. Skull low, broad and triangular; snout short, obtuse and
laterally expansive; external nares terminal and confluent. The bone
is extensively pitted with canals for vascular and nervous elements.

Premaxilla: The premaxilla is expansive and forms the entire lat-
eral wall of the snout and the ventral border of the external nares.
The superior margin projects posteriorly about 1.0 cm. between the
nasal bones and the anterior portion of the maxilla. There is no evi-
dence of an internasal septum and the nares appear to be confluent;
had the septum been cartilaginous, however, it would not have been
preserved.

The bone bears four teeth; the first two are anteriorly directed,
polygonal, in cross section and subequal in size, the second is the
smallest. The third and fourth teeth are recurved. The suture with
the maxilla is edentulous where the bone may either have been
broken, or was in fact emarginated.

Nasals: The nasal bones are broad and flat, forming the dorsal
roof of the skull and external nares. Their median suture is slightly
depressed. The bones terminate abruptly at the snout, and it is
probable that they projected a short way anteriad. The bones bear
many fracture lines due to compression.

Maxillary: While the preservation is generally good, it is difficult
to distinguish cracks from sutures. The outer wall is convex,
bounded anteriorly and /or dorsally by the posterior tip of the pre-
maxilla and by the nasals. The contact with the premaxilla involves
the edentulous region which accommodates a canine-like tooth of the
mandible; the skull is constricted at this level. The bone extends
about the rounded anterior angle of the antorbital fenestra. Seven-
teen to 18 finely denticulated (9-10/1.0 mm.) and recurved teeth,
the anterior seven of which are largest, lies on this bone.

The bone reveals little about the conformation of the orbit. The
remnant of the antorbital fenestra lies relatively high on the skull
oriented more or less dorsally due to the convexity of the bone, and
it is probable that the orbits were similarly placed. The inferior
border of the maxilla is flared medially to form the lateral walls of
the choanae. The internal and external borders of the tooth row are
equal in height.

Fig. 8. Platyognathus hsui Young. A, Skull and jaws from the right side(l),
ventral (2), and dorsal (3) surfaces; (CUP 2083). B, Articulated posterior cervical
vertebrae and scutes viewed from the dorsal surface (1), right lateral side showing
the scapula (2), and coracoid (3) drawn from the unillustrated ventral surface
(CUP 2083). C, Anterior caudal vertebrae viewed from the left side (CUP 2083).

D, Jaw fragment showing the inner surface of the orbital region (CUP 2104).

E, Posterior cervical vertebrae and scute complex viewed from the right side
(CUP 2105).

36

SIMMONS: NON-THERAPSID REPTILES 37

The suborbital region is shown in a maxillary fragment of another
specimen of comparable size (CUP 2104) ; the wall was depressed be-
low the orbit where the bone is particularly thin and not very likely
to have been preserved intact. The disposition of the bone might
indicate a more forwardly oriented orbit, but it is impossible to say
if it was directed more outward or more upward as in the case of later
crocodilians. Internally, a deep fossa which may have held a lacry-
mal gland is formed by an upward extension of the palate. This
feature indicates that the antorbital and orbital openings were closely
juxtaposed.

Jugal: The jugal replaces the maxilla at the end of the tooth row,
and it is probable that it limits the orbit from below.

Palatal Complex (figs. 8,A3,D): The palate is poorly preserved
and largely obscured by the long symphysis. The bones have been
exposed in cross section at the level of the antorbital fenestra where
the skull and jaws have been transversely fractured.

Vomers: The vomers are median-paired, delicate bones (height,
5-6 mm.; thickness, 1-1.5 mm.) which lie just forward of the end of
the symphysis and pass upward to divide the choanae. Above, the
structure flares to form the palate proper (breadth, 14-15 mm.).

Palate: The palate extends posteriorly and contacts the inner wall
of the maxilla. If the terminal epipyterygoid element is included, it
is as long as the tooth row; the posterior 14 mm. are free and project
downward across the tooth row. As noted above, the palate forms a
deep fossa (length, 13.8 mm.; depth, 3.7 mm.) below the orbit
(fig. 8,D) . The mid-line structures are broken away behin the antor-
bital fenestra and it is impossible to say whether there was any
pterygoid participation. Nevertheless, the development of the vomer
has effected at least the rudiments of a secondary palate which can
best be described as mesosuchian.

Ectopterygoid: This is a small, narrow element best preserved on
the right side. The medial surface is entire and finished, indicating
that the associated pterygoid vacuities may have been large.

The snouts of Pseudosuchia are, as a rule, tapered and acute, and
bear expanded premaxillae. The primitive crocodilian Protosuchus
shows comparable expansions and a slight emargination of the suture
with the maxilla marking an edentulous or diastemic area. All proto-
suchians, however — with the exception of Pedeticosaurus which has
been interpreted as a highly specialized pseudosuchian — lack ant-
orbital fenestrae and the external nares open dorsally. The common
suture of the nasal bones, nevertheless, is depressed.

38 FIELDIANA: GEOLOGY, VOLUME 15

Table 9.— MEASUREMENTS OF THE SKULL AND JAWS OF
PLATYOGNATHUS HSUI (in mm.)

left right
Skull

Length: from the external nares to the antorbital opening 35.7

dorsal margin of the premaxilla 21.0 20.0

ventral margin of the maxilla 45.0 50.0

Breadth: at the snout 15.0

of the external nares 7.0

premaxilla (maximum) 18 .0

of the nasal bones: anterior, posterior 8.0, 14.0

of the premaxilla-maxillary junction 16.0

Height of the maxilla at the antorbital fenestra 12.4 12.2

Jaw
Length of the symphysis 30 . 5

Breadth: of the symphysis (maximum) 16.0

of the submaxillary constriction 13.0

Length of the rami (preserved length) 57.3 81 .4

Height of jaw at posterior end of maxilla 14 .0

Jaw Fragments

CUP 2083 CUP 2104
left right

Preserved length 34 .0 47 . 5

Height of maxilla: anterior, posterior 8.7, 3.0 6.0, ... .

Height of mandible: anterior, posterior 9.0, 11.0 9.0, 14.0

The prolonged posterior extension of the palate is indicative of a
sphenosuchid heritage; the choanae are abbreviated but lie on the
anterior part of the skull like Erpetosuchus, and the formation of
the primitive secondary palate (mesosuchian?) is apparently at the
same level of development as that of Protosuchus. If the dorsal
placement of the nares is a reliable feature, Protosuchus was prob-
ably more aquatic than Platyognathus.

Jaws (fig. 8,A2) : The shape of the mandible is particularly diag-
nostic for Platyognathus. The jaw is blunt. Posteriorly, the sym-
physis gradually expands and then constricts so that the prepre-
maxilla overlaps the zone of increasing breadth and the diastemic
area lies over the expansion. The snout is slightly broader than the
jaw. The symphysis is long and deep. The rami are tightly co-os-
sified and exhibit the shallow troughs noted by Young to either side
of the dorsal mid-line. In the present example, the grooves appear
at the level of the fifth maxillary tooth where the left and right rami
diverge sharply at an angle of about 45°. The ventral surface of the
symphysis is flattened and depressed just forward of the constriction

SIMMONS: NON-THERAPSID REPTILES 39

by a shallow transverse groove. Young described a similar groove
for the type which lay further forward and masked the individuality
of the rami; here, the rami are distinctive throughout.

The dentition is largely obscured by the close apposition of the
skull. The jaw lacks a diastema and probably holds some 23-24
teeth which increase in size backwards in the series. The first two
project anteriorly and are polygonal in cross section like the maxil-
lary pattern. In contrast to the type, the others are more erect but
still caniniform, while the more posterior are slightly recurved. The
ventral surface bears round impressions of two sets of large roots,
8.8 mm. and 13.5 mm. from the tip respectively which may be the
bases of the third and fourth teeth.

Surangular and Angular: The bones diverge posteriorly and pinch
out the dentary at the level of the orbit. The jaw becomes deeper
and appears to contain a small lateral fenestra (CUP 2104). The
angular displaces the splenial ventromedially which forms the lateral
wall of a meckelian fossa.

Splenial: The bone sheaths a medial wall of the dentary and their
common suture is well marked. Young misinterpreted the meckelian
groove as the point of insertion of a cartilaginous splenial and stated
that the bone does not enter into the symphysis. It is here clearly
seen to participate in the symphysis if only by a ventral tongue, and
its anteriormost limit lies where the lateromedial dimensions of the
diverging rami narrow abruptly.

The mandibles are unlike those of any of the pseudosuchia or
protosuchia. The disposition of the splenial is sphenosuchid-like,
but the relationship of the dentary and splenial is unknown in Proto-
suchus; this is, however, crocodilian in character, particularly in the
longer-snouted forms. The symphysis of Erpetosuchus is elongate
but proportionately shorter relative to the length of the head.

Teeth, Upper Jaw: The premaxilla holds four subequal teeth. The
first and second teeth point forward while the third and fourth are
gently compressed, sharply pointed and distinctly recurved. The
second is needle-like and the smallest. Young described the teeth
of the type as octangular in cross-section, but since their geometry
in fact varies with the level considered, it might be more precise to
describe them as irregularly polygonal. Hence, distal to the tip, the
teeth are rather hexagonal in cross-section and only the bases are
octagonal.

The post-diastemic teeth are immediately less robust and become
progressively smaller backward and more sharply compressed. The

40 FIELDIANA: GEOLOGY, VOLUME 15

last three-four may be newly erupted. Fine denticulations (9-
10/1.0 mm.) appear on both cutting edges.

Teeth, Lower Jaw: The maxillae mask all but the most anterior
teeth, but these are patterned after the upper series. The first two
teeth are uniformly small, anteriorly projecting, and are followed by
larger and more erect teeth. Posteriorly, the teeth are smaller but
indistinct.

No pseudosuchian known to the author has been described with
polygonal teeth. Moreover, the dental pattern of Protosuchus, where
the reduction of the maxillary series is nearly immediate, and of
Pediticosaurus are dissimilar to the present form.

VERTEBRAE

The vertebrae occur as disarticulated and multiple fragments of
at least two animals. The cervicals and thoracics bear dorsal and
ventral armor plates; the sacrals are missing; the caudals are com-
pletely sheathed in armor.

Cervical Vertebrae (Table 10; fig. 8,B,E): Two articulated series
of vertebrae, comprising five cervicals (CUP 2105) and five cer-
vicals plus three dorsals, respectively, are known, but they cannot
be derived from the same animal since the combined vertebral count
would be characteristic of saurischians rather than thecodonts. The
latter series is believed to belong with CUP 2083.

Centra short, moderately high, platycoelous-slightly amphicoe-
lous, increasing in length only slightly posteriorly in the series. Ven-
tral surfaces smooth but furrowed. Parapophyses lie anteromediad
on the first centrum but move slightly back on the following verte-
brae; the trend is accomplished by the typical thecodont rotation of
the costal facet outward and upward toward the neurocentral suture.

The neural complex is directed craniad in all but the first verte-
bra where it is erect. The arches are very high and the spines are
terminally expanded to receive the dorsal armor. The transverse
processes are stout becoming progressively more obtuse relative to
the spine posteriorly. The zygapophyses although poorly preserved,
were presumably delicate, high anteriorly becoming more oblique
posteriorly.

Dorsal vertebrae: The first three dorsal are in articulation with the
cervical series of CUP 2083; only the third is adequately exposed.
An armored fragment from the mid-dorsal column shows three addi-
tional centra.

SIMMONS: NON-THERAPSID REPTILES

41

Table 10.— MEASUREMENTS OF THE VERTEBRAL COLUMN,
PLATYOGNATHUS HSUI (in mm.)

Position

Ventra

Maximum

Height of

in Series

Length

1 Breadth1

Cervical Series
CUP 2105

Neural Complex

1

10.0

12.0

2

6io

10.0

3

6.4

11.0

4

6.0

?13.3

5

6.5

?13.0

6

6.4

?13.0

7

9^5

Cervical Series
CUP 2083

1

6.0

9.3

10.0

2

6.9

8.4

3

7.8

4

10.2

5

9.2

6

7

Dorsal Series
CUP 2083

1

8.0

7.8

2

8.5

7.8

3

9.0

7.8

4

5

6

?10.6

1

Caudal Series
CUP 2083

?ll!4

1

?10.0

4.0

W 4.0

Armorless Caudals

CUP 2083

1

6.0

7.0

9.0

2

6.6

j

11.0

3

5.9

7.0

11.0

1 Centrum

Anterior centra are gently procoelous, compressed, and bear ven-
tral longitudinal ridges which are lost posteriorly as they become
deeply furrowed. These are less squat than the cervicals but not
immediately more elongate.

In the third vertebra (CUP 2083) the parapophyses have com-
pleted their dorsal migration and lie just below the diapophysis.

42 FIELDIANA: GEOLOGY, VOLUME 15

Posteriorly, the parapophyses lie on or just above the neurocentral
suture and subsequently appear to 'fuse' with the diapophyses form-
ing narrow facets for single-headed ribs.

The neural apparatus is high and directed craniad; the spine is
elongate, flat, and terminally expansive like the cervicals. The zyga-
pophyses are widely oblique to insure the maximum of lateral motion
— a feature of distinct advantage to an aquatic animal.

Caudal Vertebrae (Table 10; fig. 8,C): Anteriormost caudals are
completely sheathed in armor. The posterior vertebrae are ex-
posed to permit description.

Centra procoelous, compressed, and anteriorly more elongate than
the cervicals which they resemble in other respects. Ventral surfaces
smooth, rounded, less deeply furrowed than the dorsals, and bear
facets for hemapophyses. The caudal ribs articulate on the neuro-
central suture, and above, the zygapophyses show widely oblique
facets. The neural spines are low, co-ossified, and form a continuous
ridge for the dorsal armor.

Ribs (fig. 8,E) : The cervical ribs are plow shaped, approximately
11.0 mm. long and overlapping. The forward projection is longer.

The anterior dorsal ribs are double-headed, acutely bent, and
terminate on the sternum. The proximal and vertebral segments
appear to be broken at their mid-lengths. The sternal segment bears
a ventrolateral triangular flange at the level of the fracture which
may have supported some lateral armor plates. The ribs of the mid-
dorsal region are long, broadly arched, split sagitally and are appar-
ently single-headed.

The pattern of the vertebral column is protosuchid. The pro-
gressive migration of the parapophyses toward the neural arch is
essentially completed at the same level by Erpetosuchus (eighth -
ninth presacral), Protosuchus (twelfth presacral) and by the present
form (?ninth -tenth presacral). The ninth presacral of Erpetosuchus
figured by Newton (1894) resembles the cervical of Platyognathus,
but the protosuchid type is uniformly amphicoelous. The procoelous
centra of Platyognathus is a much more advanced feature of croco-
dilian evolution.

PECTORAL GIRDLE

The bones are nearly complete bilaterally, and lie on the cervical
series (CUP 2083) . The dorsal blades of the scapulae are damaged
in part. The left carocoid is complete, but the right retains only a
proximal fragment.

SIMMONS: NON-THERAPSID REPTILES 43

Scapula (fig. 8,B2): The bone is elongate and the dorsal and
ventral blades are broadly expanded. The glenoid region is rotated
slightly outward and bears a strong acromion tuberosity above.
The dorsal portion tapers gradually to form a strong inferomedial
constriction; the expansion of the ventral blade is immediate there-
after and the anterior portion is prolonged.

Coracoid (fig. 8,B3): The coracoid is elongate, expanded proxi-
mally, and suturally united to the scapula where it participates in
the glenoid. The dorsal surface is concave and pierced by an antero-
medial foramen.

Table 11.— MEASUREMENTS OF SCAPULA AND SCAPULOCORACOID
OF PLATYOGNATHUS HSUI (in mm.)

left right
Scapula

Preserved maximum length. ... 38.3 ?33.3

Level of:

dorsal blade

inferomedial constriction

sutural union of scapula

and scapulocoracoid

acromion

Scapulocoracoid

Length of scapulocoracoid 21. 1 ....

Dorsal blade (maximum)

Medial constriction

Ventral blade

Sternum: A thin and unsegmented bowed plate of bone lying to
the left of the ventral cervical scutes (21.5 mm. long) is interpreted
as the sternum.

The features of the pectoral girdle are those of primitive proto-
crocodilians and of two relatively advanced suborders of the Croco-
dilia. The scapula is reminiscent of Broom's reconstruction of the
ventral blade of Sphenosuchus and of that of Notochampsa Broom
(1904, Haughton, 1924), while the coracoid is modeled upon that of
the eosuchian Alligator redrawn by Colbert and Mook (1951). The
ratio, coracoid length /scapular length, is 0.52 for Protosuchus, circa
0.96 for Alligator, and 0.60(?) for Platyognathus; the latter figure
should probably be lower since the dorsal blade of the scapula is in-
complete and would then approximate that for Protosuchus although
the configuration of the coracoid is quite different.

Breadth

Thickness

left right

left right

21.4 ?23.3

... 1.0

.... 6.2

... 3.0

8.2

... 6.0

15.6 16.6

15.0 13.2

7.0 ...

5.1

... 5.1

.... 11.1

44 FIELDIANA: GEOLOGY, VOLUME 15

SCUTES

The postcranial skeleton is variably sheathed with ornamented
scutes. Dorsal armor occurs uniformly on all regions of the body
as a double row of transverse scutes. The postsacral region bears
smaller and more numerous unpaired lateral scutes which form a
transverse series with the ventral armor, paralleling the dorsal series
in distribution. Rounded pits and a pattern of radial rugosities orna-
ment the dorsal series; the lateral and ventral plates are randomly
pitted.

Dorsal Series (figs. 8,B,E; 9, A) : The plates form a broadly rectan-
gular overlapping series corresponding in number and position to the
underlying vertebrae. These are broader than long, the ratios (length/
breadth) being 0.63, 0.51 and 0.73 for the cervical, dorsal, and ante-
rior caudal regions respectively. The width of the plates, then, in-
creases posteriorly and the ratio may approach unity in the last
postsacral plates. The lateral margins are slightly rounded, and each
scute bears a lateral longitudinal keel becoming more prominent
toward the posterior margin. The outermost surfaces are depressed
below this axis.

Lateral Series: The lateral plates form a tightly overlapping series
which is apparently restricted to the caudal region, and are keeled
in like-fashion to the dorsals. The length /breadth ratio increases
posteriorly, i.e., 0.58-0.75 in the anterior caudal and posterior caudal
regions. A single pair of convex scutes (fig. 8,E) oriented obliquely
and outward to the dorsal series is associated with an anterior ver-
tebra of cervical series (CUP 2105) ; these contact the cervical ribs of
the centrum immediately in front and may indiacte that the entire
neck was armored.

Ventral Series: The ventral scutes are paired and distributed like
the dorsals although only the right series has been preserved in cer-
vical series (CUP 2083). The fragment of the dorsal vertebrae
(fig. 9,B) is covered ventrally by eight paired rows of four scutes
each, but there are only two scutes in each transverse row in the
caudal region. The plates lack lateral keels, are irregularly quadrate
and suturally united but overlap somewhat in the posteriormost
caudal region. The length /breadth ratio is rather uniform in all
regions of the body, i.e., cervical, 1.0; dorsal, 0.75; caudal, 1.0.

The configuration of the scutes in Platyognathus is similar to Pro-
tosuchus although the ventral deflection of the border lateral to the
keel is less acute and the ornamentations are dissimilar. The cer-
vical scutes in Erpetosuchus differ in that they are longer than broad,

I 1 = 10 mm

Fig. 9. Platyognathus hsui Young. A, Presacral vertebrae and scutes viewed
from above (CUP 2083). P>, Ventral aspect of presacral scutes (CUP 2083).

Microchampas scutata Young. C, Vertebrae and ribs viewed obliquely from
below (1) and the ventral scutes (2); (CUP 2085). D, Hand with claws, metacar-
pals and phalanges (CUP 2086).

45

46 FIELDIANA: GEOLOGY, VOLUME 15

but the dorsal transverse series is similarly ornamented. The ven-
tral scutes are apparently developed here more extensively than in
Protosuchus where armor is preserved only from the lumbar region
posteriorly. In toto, the armor pattern is somewhat reminiscent of
aetosaurus-like pseudosuchians.

CHARACTERS INDICATING A THECODONT HERITAGE

The short skull and elements about the terminal confluent nares
are patterned after Sphenosuchus. The armor images the rather
specialized pseudosuchians although Sphenosuchus is itself without
armor. Antorbital fenestrae are almost exclusively limited to the
thecodonts although the exceptional protosuchian Pedeticosaurus
presents a similar structure. The centra of the vertebrae lack hema-
pophyses.

CHARACTERS INDICATING A CROCODILIAN AFFINITY

A flat snout, an edentulous and emarginated premaxillary-maxil-
lary suture, dorsally oriented orbits, a primitive 'mesosuchian' palate
and ventro-lateral choanae are characters to be found in primitive
crocodilian groups. Confluent external nares are common to many
mesosuchians and eosuchians.

The symphysis of the mandible is elongate and includes the
splenial.

Eosuchian-like procoelous vertebrae compose the presacral ver-
tebral column. The parapophyses migrate upward onto the neural
arch and fuse with the diapophyses to form wide lateral processes.

The coracoid is elongate and intermediate in length between the
protosuchian and crocodilian pattern with respect to the scapula.

The features of the skull make it valid to assume that Platyog-
nathus was most probably derived from a sphenosuchid-like pseudo-
suchian. The line of descent of the crocodiles was evidently very
plastic, and in three areas of the world, i.e., North America (Proto-
suchus), South Africa (Sphenosuchus) and China, the pseudosuchia
and protosuchia were developing along a quite definite crocodilian
plan. F. von Huene (1925a) and Broom (1927) have outlined sev-
eral schemes depicting the steps in the development of the crocodiles
from a generalized sphenosuchid-like ancestor. Broom's scheme ap-
pears to be the more reasonable interpretation, since he removes
rather specialized forms such as Pedeticosaurus, Aetosaurus and Erpe-
tosuchus from the line of direct descent toward Notochampsa (Erythro-

SIMMONS: NON-THERAPSID REPTILES 47

champsa) ; in accordance, therefore, Platyognathus may be interpreted
to have been independently developed in the same fashion as Pedeti-
cosaurus which, as Colbert and Mook point out, is so different from
other South African protosuchians that it had better be considered
a pseudosuchian.

The suite of characters which define Platyognathus bespeak a taxo-
nomic position intermediate between the Pseudosuchia and Proto-
suchia. If, however, the greater emphasis is placed upon the more
conservative features of the skull rather than upon the progressive
nature of the postcranial skeleton, and these are considered to be
specialized responses to an aquatic habitat, Platyognathus will prop-
erly be seen to be a pseudosuchian.

It is recommended that the present form be placed in a new fam-
ily of pseudosuchia, the Platyognathidae (fam. nov.) which has the
following characters: Skull: triangular with a short, broad snout;
confluent terminal nares; orbit upwardly placed; a small antorbital
fenestra; a secondary palate of a mesosuchian type; a long symphy-
sis. Vertebrae: dorsal and caudal series procoelous. Pectoral Girdle:
coracoid very elongate. Armor: scutes broader than long.

Order Thecodonta

Suborder Pseudosuchia

Family Incerta sedis

Holotype. — A fragment of the right ilium and proximal end of the
femur. Catalog No. CUP 2084.

Horizon and Locality. — Ta Ti, Dark Red Beds, Lower Lufeng
Series.

description (Table 12, Fig. 10,Al-2)

Ilium: The crest is straight, narrow, and prolonged anteriorly; the
bone is fractured just back of the ischial process but if a posterior
extension were also developed, it would most probably have been
modest. The roof of the acetabulum is expansive anteriorly to pro-
vide a broad, deep, articular surface for the head of the femur.

The lateral surface bears an oblique ridge which passes antero-
ventrally to the acute and somewhat upturned border of the supra-
acetabular buttress. The buttress is strongly developed anteriorly,
but gradually merges with the bone above the ischial process. The
ischial process limits the acetabulum posteriorly (fig. 10, A), projects
downward and outward, and bears a demilunar facet.

48 FIELDIANA: GEOLOGY, VOLUME 15

Table 12.— MEASUREMENTS OF THE PSEUDOSUCHIAN, CUP 2084

(in mm.)
Ilium

Length of the crest 37.0

Height of the crest above the mid-acetabulum 13 .0

Height of the ilium at the ischial process 30.7

Breadth of the acetabulum, from the tip of the ischial process

to the lip of the supra-acetabular buttress 20.0

Height of the acetabulum above the obturator 15.0

Facet of the ischial process: length, breadth 11.0, 6.0

Femur

Head: proximal dorso ventral breadth 14 .0

Anterior-posterior breadth of the proximal articular suface 22.3

Breadth of the proximal articular surface behind the head 10.6

Neck: anteroposterior, dorsoventral 11.0, 12.0

Ridge systems: proximal breadth of the posterior, ventral 11.4, 12.0

The medial surface features a pair of broad crescentic depressions
above the ischial and pubic processes. These are separated by about
7.0 mm. above the obturator which is open and presents a finished
surface.

Femur (fig. 10,A3-5) : The femur was displaced during preserva-
tion, and made contact with the posterior part of the iliac crest. The
head is large and divided by a slight dorsal constriction 17-18 mm.
backward, appearing then biconvex; the proximal anterior surface is
gently concave. A pair of ridges, the posterior ridge and the prox-
imal anterior branch of the ventral ridge are separated by a strong
intertrochanteric fossa, and pass diagonally downward and anteriad
across the ventral surface of the shaft. The bone is hollow and thin-
walled.

The taxonomic position of the fragments is indefinite. The con-
figuration of the ilium does not approach that of either the Protero-
suchia or of the ornithosuchian pseudosuchians where the primitive
triradiate pelvis is a solid plate-like structure having a continuous
ventral symphysis. The obturator in the present form is acute and
finished indicating that the space was not filled with cartilage. The
overall proportions of the ilium of the stagonolepid Typothorax
meadei Sawin (1947) are comparable to the present form, and the
bone shows a prominent supra-acetabular buttress, an incipient sub-
acetabular foramen and downturned ischial processes. The develop-
ment of the proximal biconvexity and of the ridge systems in the
femur is intermediate between Typothorax and Episcoposaurus hor-
ridus Cope (Huene, 1915), although the incompleteness of the remains
limits comparison. A more definitive analysis of the relationships of

SIMMONS: NON-THERAPSID REPTILES 49

CUP 2084 to the stagonolepid group might be possible if the distal
shaft were known for, in these, the proximal and distal condyles are
perpendicular to each other.

It is probable that the remains are not those of the poorly known
parasuchian Pachysuchus imperfectus Young (1951). Even though
the ilia of other phytosaurs are low and prolonged anteriorly, the
pubo-ischiatic suture is incompletely ossified and filled with cartilage.
The nature of the femur affords a more likely comparison to the
stagonolepid group.

Order Crocodilia

Suborder Protosuchia

Microchampsa scutata Young (1951)

Microchampsa scutata Young (1951)

Holotype. — An articulated fragment of eleven vertebrae and ribs
covered by three longitudinal rows of dermal armor.

Horizon and Locality. — Dark Red Beds, Lower Lufeng Series,
Huangchiatien, Lufeng, Yunnan.

Diagnosis (Young, 1951, p. 31). — "Thecodontia with a single row
of dorsal scutes closely arranged on each row of the lateral scutes.
Presence of ventral scutes doubtful but probable. Dorsal vertebrae
short and stout, becoming slightly elongated and constricted poste-
riorly. Ribs are double headed, only slightly curved. Size very
small, being about one-half that of Erythrochampsa longipes Br."

DESCRIPTION

The dorsals are amphiplatyan, stout and short (1.1-2.0 mm.)
anteriad becoming slightly longer and constricted posteriad (2.1-
3.0 mm.). The parapophyses are small and become indistinct by
the fifth centrum. Four of the seven ribs exposed on the left side
had distinct capitula and tubercula which tended to lie closer to-
gether backward along the column. The last centrum was cited as
a lumbar. The ribs are short and only slightly curved.

The dermal scutes become shorter posteriorly and correspond in
number to the vertebrae. A single median dorsal row, which lacks
pittings and other ornamental rugosities, is similarly constructed and
adjoins broader unpaired rows of dorsolateral scutes at almost right
angles. The fragment measures about 21.0 mm. long, 11.0 mm. high,
and 7.0 mm. broad at the middle part.

50 FIELDIANA: GEOLOGY, VOLUME 15

ADDITIONAL MATERIAL

Material. — A fragment of seven consecutive vertebrae and five
ribs with dermal armor, Catalog No. CUP 2085. Bones and claws
of the hand, Catalog No. CUP 2086.

Horizon and Locality. — Ta Ti, Dark Red Beds, Lower Lufeng
Series, Lufeng, Yunnan.

Amended Diagnosis: An armored reptile. Three rows of scale-like
dorsal scutes — a single median dorsal row adjoining unpaired bilat-
eral series. Ventral scutes present. Thoracic vertebrae short, be-
coming elongate and sharply compressed posteriorly; anteriormost
ribs doubly headed, free and slightly curved, becoming fused to the
lateral armor in the lumbar region and articulating with broad trans-
verse processes.

DESCRIPTION

Vertebrae and Scutes, CUP 2085 (fig. 9,Cl-2): The fragment ap-
pears to be from the lumbar region and is twice as large as the type,
V87 (length, 39.0-40.0 mm.; height, 17.0-18.0 mm.; breadth, 18.0
mm. at midlength). Ventral armor plates arch over the left side of
the vertebral column and cover the median dorsal and left lateral
scutes.

The specimen must have turned 180° during preservation. The
right side was denuded of protective armor and covered with an in-
durated, whitish waxy material of a color and texture approximating
that of the underlying bone which was difficult to prepare — perhaps
due to the surface solubility under pressure tending to fuse and there-
by obscure the boundaries of the elements. The better preserved
features of the left side were rather easily prepared from a soft red-
dish matrix.

Lumbar Vertebrae, CUP 2085 (Table 13) : The column is arched.
The centra are amphiplatyan, ventrally furrowed and deeply incised
posteriorly in the series. The costal articulations of the right side are
fused, broad, dorsoventrally convexoconcave and lie on the neural
arch.

The neural spines are broad, flat and terminally expanded to ac-
commodate the median dorsal row of scutes. Measurements of the
height (Table 13) are only approximate due to crushing. The zyga-
pophyseal articulations are obscured by the crowding of the vertebrae
along the curvature of the column, but they are probably rather flat
as in other proto-crocodilians.

SIMMONS: NON-THERAPSID REPTILES

51

Table 13.— MEASUREMENTS OF MICROCHAMPSA SCUTATA

(in mm.)

Specimen
No.

CUP 2085

Specimen
No.

CUP 2087

Position
in Series

1
2
3
4
5
6
7

Position
in Series

1-2
2-3
3-4

Lumbar Vertebra

Ventral
Length

3.7

3.5

4.2

4.8
?4.2
?4.5

*A.H.

5.0
5.9
5.5
5.6
5.6
5.6

Right Side
L.Tp. B.Tp. H.

4.0
4.0
4.6
4.6
4.0
?3.6

5.5
5.2
5.0
5.5
6.4
5.1

17.0
16.7
16.0
16.7

?15.0
?

H.Ns.

6!6
6.0

?4.7
5.5

?4.2

Caudal Vertebra

Distance between the tips
of the Transverse Processes

?2.0
2.5

* Anterior height
Transverse process length
Transverse process breadth
Height of the vertebra
Height of the neural spine

Caudal Vertebrae, CUP 2087: The fragment consists of the neural
arches and scutes of five vertebrae. The transverse processes are
short and narrow, and contact the edges of the median dorsal scutes.
The posterior zygapophyses are rather obliquely oriented (fourth
vertebra) .

Ribs, CUP 2085: The dorsal ribs of the type were double headed
and free. The proximal shafts of the lumbar ribs apparently fuse to
the anterior margin of the lateral scutes, and the heads persist as
linear exostoses converging to form the shaft 2-3 mm. from the outer
border of the armor; the tubercular relief is the higher. The features
are best seen in the third and fourth ribs in the series. The shafts
clearly extended beyond the end of the scutes but become structurally
weaker posteriorly.

Ventral Armor, CUP 2085 (Table 14) : Young's speculation that
Microchampsa had ventral armor is confirmed. Four transverse rows
of four scutes each overlap the mid-dorsal and lateral series, but are
only unilaterally represented. The plates which would have con-
tacted the midline are broken while the outermost plates have been
displaced and overlap slightly. These are rather squarely fashioned
(6.0 mm.2), but the lateral borders of the outermost plates are rounded

52 FIELDIANA: GEOLOGY, VOLUME 15

anteriorly and finished, indicating that the armor ended at this point
and did not extend over the sides of the body.

Dorsal Armor, CUP 2087 (Table 14) : Four scutes from the mid-
dorsal and right lateral series are exposed on a caudal fragment.
The laterals contact the under surface of the dorsals at an oblique
angle, and are broader anteriorly than posteriorly in the thoracic
column; in the caudal region, the dorsals are the broader (dorsals,
6.2 mm.; laterals, 3.0-4.0 mm.) and become shorter and more closely
fitting posteriorly. The dermal armor is simply pitted and has orna-
mental rugosities.

Table 14.— MEASUREMENTS OF

THE DERMAL ARMOR OF

MICROCHAMPSA SCUT AT A (in mm.)

Position

Mid-Dorsal

Lateral Series

Specimen Along
No. Column

Series
L.1 B.2

left
L. B.

right
L. B.

CUP 2087 1

?2.0

?5.4

2.9 3.3

2

2.2

5.6

2.7 5.4

3

2.5

6.1

2.0 3.5

4

2.4

1.3

XL.= Anteroposterior length
2B.=Lateromedial breadth

APPENDICULAR SKELETON

Hand, CUP 2085 (fig. 9,D) : The association of the specimen with
the vertebral fragment and its small size figure importantly in the
tentative assignment of the complex to Microchampsa. The fragment
consists of two gently curving claws subequal in length, sharply
tipped and grooved to receive the horn, and rather elongate, slender
phalanges of equal length which have large condyles — probably the
third and fourth or the fourth and fifth digits.

The absence of skull materials limits the definition of Micro-
champsa since the dermal armor pattern is most atypical with respect
to the stem reptiles. The rectangular scutes are of a protosuchid
type, but the dorsal plates of the Notochampsidae are paired and
there is no indication that the microchampsid pattern originated by
the simple fusion of plates to either side of the midline — absence of
lateral keels. Moreover, the dorsal armor in Notochampsa istedana
(Haughton, 1924) gradually becomes quadrangular posteriorly while
the rectangular configuration in Microchampsa is retained in the
caudal region and it is to be expected that the obscured lumbars were
similarly fashioned. The pattern approaches most nearly the poste-

SIMMONS: NON-THERAPSID REPTLIES 53

rior caudal scutes of Protosuchus and Pedeticosaurus which are quad-
rate or become even slightly longer than broad ; the number of plates
in each transverse ventral row also decrease toward the sacrum.
Supernumerary ventral plates relative to the dorsals, however, dis-
tinguish other protosuchians (2:1) from Microchampsa (1:1) although
the caudal regions are similarly encased in dermal armor; the devel-
opment, while not as great as that of the more specialized pseudo-
suchians such as Aetosaurus, surpasses that of the more conservative
thecodont group.

The vertebral structure is most crocodilian; the centra resemble
Protosuchus and related forms. The expansive spines are particu-
larly like those of Pedeticosaurus and there is a tendency for the
fusion and establishment of the costal articulations on broad, flat,
transverse processes in the lumbar region of the body. The proto-
suchian rib pattern is virtually unknown, however, the doubly flanged
shafts of the thoracic ribs of Protosuchus are not found in either
Microchampsa or in modern crocodilia where only anterior flanges
persist. It is possible, nonetheless, that the lumbar ribs and scutes
of Microchampsa were flanged and free in young animals, i.e., in the
type, but became fused during ontogeny.

The available structures are insufficient to establish the system-
atic position with any certainty, but the most reasonable assignment
appears to be to the Protosuchia, recognizing that it apparently rep-
resents a new type of primitive crocodilian.

Order Saurischia

Suborder Theropoda

Infraorder Coelurosauria

Family Podokesauridae

Lukousaurus yini Young (1948b, 1951)

Original Diagnosis.- — "Skull rather small. Nasal opening small
and anteriorly situated. Preorbital opening triangular and high.
Orbits well rounded. Muzzle looks slender. Lower jaw slender with
the lower margin straight. Premaxilla bears five teeth and maxilla
about ten teeth. All the teeth are sharply compressed and pointed
backward. Posterior side with fine and short serrations."

Lukousaurus is the only carnosaur known from eastern Asia and
the only small saurischian of the Lufeng assemblage. The original

54 FEILDIANA: GEOLOGY, VOLUME 15

diagnosis of the genus was based on materials from the Dark Red
Beds at Huangchiatien — the anterior part of a skull and jaws (V23),
a tooth (V263) and the proximal part of a right humerus (V261).
Recently (Young, 1951), three additional fragments from the Dull
Purplish Beds at Shawan (V77) were referred to this genus, the distal
part of a right humerus and an upper middle part of a co-ossified
tibia and fibula.

The present collection includes an additional and similarly pre-
served skull fragment with a more complete jaw than the type (V23) .

Additional Material. — An anterior fragment of a skull and jaws
with teeth. Catalog No. CUP 2092.

Horizon and Locality. Hei Koa Peng, Dark Red Beds, Lower
Lufeng Series.

Diagnosis. — Same as for the Type V23 (Young, 1948b).

description (Table 15)

The skull is badly damaged. A fragment of the left premaxilla
lies at the snout while the nasal bones are displaced to the right side.
Posteriorly the roofing bones are limited to a small fragment of a sus-
pect prefrontal. The left wall shows the anterior angle of the pre-
orbital fenestra; the position of the external nares is only indicated
since the borders are crushed and the orbits are ill-defined. The
outer wall of the left maxilla is broken away.

A short anterior fragment of the left jaw bears the roots of two
teeth. The right mandible is transversely fractured and crushed pos-
teriorly, but indicates the presence of a small, high, lateral fenestra;
its internal architecture is exposed medially by the loss of the splenial
which is intact only at the symphysis. The prearticular is seen to
project anteriorly. The surangular-angular contact is indistinct due
to the checkering of the bone. The angular is a large element which
overlaps the smaller superior surangular and wraps about the infe-
rior surface of the jaw.

The tips of the second -fifth teeth of the left maxilla are imbedded
in the matrix of the lower jaw; the fifth is completely exposed
(11.0 mm.). The sixth and seventh exist as hemi-root fragments
adhering to the inner wall of the maxilla. Roots of the eighth and
ninth, with perhaps the crowns of their replacement teeth, are simi-
larly contained while two large, badly checkered fragments — (?) lowers
— lie above them. A series of four small teeth (terminals) occur just
forward of the orbit.

SIMMONS: NON-THERAPSID REPTILES 55

On the right side, a single premaxillary tooth (?fifth) lies internal
to the space marking the suture with the maxilla, and is followed by
the first maxillary tooth with its replacement. The first-third max-
illary teeth lack crowns and the root of the second lies at the alveolar
margin. The sixth-eighth and ?twelfth teeth become progressively
smaller. As noted by Young, the jaw could not have supported more
than 12 teeth.

The tight apposition of the right maxilla masks the mandibular
dentition. The short fragment of the left mandible exhibits the roots
of three teeth mediad to the fourth maxillary tooth.

Table 15.— MEASUREMENTS OF THE SKULL AND JAWS OF
LUKOUSAURUS YINI (in mm.)

left right

Preserved length of the skull: upper 29.0 51 .6

lower 56.0 51.6

Preserved length of the jaw 63 .0 19 .4

Anterior height of the skull (excluding nasals) 10.6 13.0

Posterior height of the skull fragment 17.0 17.0

Length of the tooth row 37.0 56.6

Preserved length of the premaxilla 8.0

Remains Referrable to the Podokesauridae
Catalog No. CUP 2089

Material. — An articulated fragment of a left femur, tibia and
fibula with isolated fragments of metacarpals and phalanges.

The bones were associated with the skeleton of Dibothrosuchus,
but are quite distinct from other known pseudosuchia. Moreover,
on the basis of the proportions of the appendicular skeleton among
the Ornithosuchidae, where the acquisition of bipedalism parallels
the reduction of the forelimb relative to the more massive hindlimb,
the femur is as slender and equally as long as the humerus of Dibo-
throsuchus. The histologic structure of these bones is similar and
at apparently the same level of maturation, but morphologically
identical fine structure is common among unrelated groups during
their ontogeny.

description (Fig. 10,B1^4; table 16)

Femur: The shaft is long and curved; the dorsal and ventral sur-
faces are normally angular in places, perhaps indicating the origins
and insertions of the extensor and adductor muscles. The distal con-

56 FIELDIANA: GEOLOGY, VOLUME 15

dylar area is triangularly expansive and bent backward; the corre-
spondingly formed intercondylar fossa is very deep and broad for the
insertion of an apparently powerful M. quadriceps to extend the
thigh, while the popliteal space is smooth, shallow and longitudinally
cleft. The surface of the lateral condyle is smooth; the medial con-
dyle is bifurcated. The bone is hollow and thin- walled.

The rectangular articular surface and straight, slender shaft com-
pare favorably to Coelophysis longicollis Cope (1887; Huene, 1906,
1915). The shortness of the condyles approaches the condition in
Podokesaurus holyokensis Talbot (1911) but their ventral disposition
is here less prominent. Small condyles are also reported for Haltico-
saurus longotarsus Huene (1932), but this bone was not figured.

Tibia: The proximal articular surface is roughly triangular and
divided by a shallow groove. The convex, dorsal, extensor surface
bears a triangularly broad and low cnemial crest for the insertion of
the extensor muscle below the anterior femoral condyle. The shaft
is broad anteroposteriorly and moderately concave ventrally.

Table 16.— MEASUREMENTS OF THE APPENDICULAR SKELETON
OF CUP 2089 (in mm.)
Femur

Preserved distal length (lateral, medial) 55.6, 56.4

Maximum condylar breadth (lateromedial) 21 .0

Maximum breadth above the condyles (lateromedial) 15.0

Maximum breadth at the most proximal end (lateromedial, antero-
posterior) 7.4, 8.3

Depth of condyles (anteroposterior) :

anterior condyle (fibula) 13 .3

posterior condyle (tibial) ?16 . 7

Depth above the condyles (anteroposterior) :

anterior condyles (fibula) 13.0

posterior condyles (tibial) 9.0

Depth of the intercondylar fossa (lateral border, medial border) 6.6, 5.4

Proximal-distal height of the posterior condyle 10.0

Tibia

Preserved proximodistal length (medial, lateral) 33.7, 31.6

Breadth of the proximal articular surface 18 .7

Maximum depth 13.0

Distal width (lateromedial) 8.0

Distal thickness (anteroposterior) 6.0

Fibula

Preserved proximodistal length (medial) 30.0

Proximal breadth (lateromedial) 14 .0

Proximal depth (anteroposterior) 5.0

Breadth of the neck (lateromedial) 8.0

Depth of the neck 6.0

SIMMONS: NON-THERAPSID REPTILES 57

Tibias of Triassic coelurosaurs are poorly known. A straight,
narrow shaft is reported for Dolichosuchus cristatus Huene (1932)
and Podokesaurus; the first is twice as large as the present form and
develops a strong pair of dorsal ridges (cnemial crest), but their mid-
length cross sectional areas are comparable. While the tibia of Co-
elophysis has a small head, its shaft bears a low, lateral tuberosity.

Fibula: The fibula is very slender, subcircular in cross section and
the head is sharply set-off from the shaft by a constriction.

Fibulae of coelurosaurs, while little known and poorly preserved,
are commonly thin, and may be straight (Podokesaurus) or curved
(Saltopus elginensis Huene, 1910). The expansion of the head is a
distinctive feature, but weak in Coelophysis.

Hand (metacarpals and phalanges): The metacarpals are long
and slender. The elements of the proximal and distal fragments are
straight, round in cross section, and widely spaced although the con-
dyles are contiguous. The phalanges are known from a small joint
fragment.

The hands of coelurosaurs are incompletely known as well. The
bones of Procompsognathus (Huene, 1921) are a third smaller, lie
closer together and are more heavily constructed. The apparent
large size of the hand in the present specimen may be similar to Podo-
kesaurus; the elongation and slenderness of the metacarpals and the
reduced size of the phalanges (?claws) may have been of advantage
to a form purportedly adapted for grasping like that of Coelophysis.

Catalog No. CUP 2090
Material.- — The proximal fragments of two cojoined metatarsals.

The bones were associated with the remains of Dibothrosuchus,
but in view of their slenderness, a like-assignment is unwarranted.
Moreover, these were not modeled upon the Hesperosuchid-type.

Horizon and Locality. — Ta Ti, Dark Red Beds, Lower Lufeng
Series.

DESCRIPTION

The fragments are entirely fused (fig. 7,E). The free condylar
border of the larger bone (length, 42.4 mm.) is sharp. The breadth
of the proximal and distal ends of the cojoined elements is 16.4 mm.
and 11.0 mm., respectively.

Metatarsals are rarely preserved in coelurosaurs. Avipes dill-
stedtianus Huene (1932) is known solely from these bones which are

I 1= 10 mm

| (« 10mm.

58

SIMMONS: NON-THERAPSID REPTILES 59

proximally fused for at least half their length and bear acute con-
crescent edges, but it is not known if they similarly diverged distally
in the present example. Fusion of bones is doubtful in Podokesaurus
and Saltopus, but entirely lacking in Procompsognathus and Hallopus.

Catalog No. CUP 2091

Material. — The distal end of a right femur.

Horizon and Locality. — Ta Ti, Dark Red Beds, Lower Lufeng
Series.

DESCRIPTION

The shaft is rather triangular in cross section above the distal
condyles and is preserved for a short distance (fig. 10,C). The
condyles are subequal and strongly rotated to the ventral side; the
lateral articular process for the fibula is upturned at its apex and is
the longer and more massive; the shorter medial condyle for the tibia
is down turned. The narrow superior crest of the lateral condyle is
continued as a ridge on the shaft while the bone is broadly rounded
above the median condyle. The ventral intercondylar space is tri-
angular and sharply depressed, but viewed from below it appears
narrow and shallow. The dorsal and inferior surfaces of the frag-
ment are relatively flat and smooth and lie at right angles.

The fragment appears closer in nearly every respect to the simi-
larly preserved Walgettosuchus woodwardi Huene (1932) from the
lower Cretaceous, New South Wales, Australia, than to any of the
carnosaurs or prosauropods I know of where condylar inequality is
less marked and the intercondylar sulcus is deeper, i.e., Gresslyo-
saurus ingens, Plateosaurus gracilis, P. plieningeri Huene (1932).

The proportions of Gresslyosaurus ingens are similar to the pres-
ent form, but in toto, these forms are more massive.

Conclusions.— The hind limb (CUP 2089), femur (CUP 2091) and
foot bones (CUP 2090) rather clearly demonstrate coelurosaurian
affinities, and particularly to the common upper Triassic family, the
Podokesauridae. Generic identity has not been accorded these speci-

FiG. 10. Pseudosuchian (CUP 2084). A, Ilium, medial (1) and lateral (2)
sides. Femur, proximal fragment viewed from the ventral (3), dorsal (4) and
articular surfaces (5).

Coelurosaur (CUP 2089). B, Femur, distal fragment articulating with prox-
imal fragments of the tibia and fibula (1, 2). 3, phalanges. 4, metacarpals.

Coelurosaur (CUP 2091). C, Femur, distal condyles viewed from the medial
(1), ventral (2), and articular (3) surfaces.

60 FIELDIANA: GEOLOGY, VOLUME 15

mens since it is felt that additional finds might be of more satisfac-
tory diagnostic value. It is hoped that future collections from the
Lufeng Basin will disclose more complete forms with which these
fragments can be associated.

Table 17.— MEASUREMENTS OF THE FEMUR OF CUP 2091

(in mm.)

Lateromedial breadth at the condylar surfaces 21 .0

Transverse cross section length at the break 13. 7

Sagittal cross sectional length at the break 12 .4

Sagittal thickness of the lateral condyle 23.4

Transverse thickness of the lateral condyle 8.2

Sagittal thickness of the medial condyle 15.0

Maximum separation between the condyles 12.0

Lateral length of the fragment 34 . 3

Medial length of the fragment 33 .4

Suborder Prosauropoda
Gyposaurus sinensis Young (1941a, 1948a, 1951)

Original Diagnosis. — "Small Prosauropoda, about the size of Gy-
posaurus capensis. Teeth of general Thecodontosaurus-type with
anterior and posterior coarse serrations. Vertebrae number prob-
ably: neck 10, dorsal 15, sacrum 3, and tail ?. Anterior limb ex-
tremely short, scapula vigorously bending at the base of the shaft.
Pelvic girdle rather slender with the ilium high. Both hand and foot
with distinct lateral reduction."

The collection made by Young represents about 14 individuals
of which the majority are unquestionably identified. V45 and V46
from Huangchiatien were perhaps considered immature individuals
of Lukousaurus or Gyposaurus since they demonstrated some ana-
tomical differences from known comparative materials.

Remains Referred to G. sinensis Young

Element

Third-fourth cervical vertebral centrum.

Neural apparatus, anterior dorsal vertebra.

Cojoined mandible and maxillary.

Scapula, distal end.

Maxillary fragment, left.

Mandibular symphysis and ramus including

teeth; a premaxillary fragment with teeth;

cojoined upper and lower jaw fragment with

teeth.

Catalog

Locality

No. CUP

Unknown

2021

Hei Koa Peng

2027

Hei Koa Peng

2028

Hei Koa Peng

2029

Hei Koa Peng

2026

TaTi

2006

SIMMONS: NON-THERAPSID REPTLIES

61

TaTi

2007

TaTi

2008

TaTi

2009

TaTi

2010

TaTi

2011

TaTi

2012

TaTi

2013

TaTi

2014

TaTi

2015

TaTi

2016

TaTi

2017

TaTi

2018

TaTi

2019

2020

TaTi

and

2023

TaTi

2024

TaTi

2025

Neural spine of a cervical vertebra.
Fourth metatarsal.
Left ulna and radius, proximal end
Vertebral centra, sacrals I and II.
Left pubis, proximal end.
Right humerus, distal end.
Left femur, distal end of a juvenile.
Right radius, proximal end.
Right pubis, distal end.
?Pubis, distal end of a juvenile.
Fourth metatarsal, proximal end.
Right ulna, proximal end.
Left ulna, proximal end.

Neural apparatus, cervical vertebra.
Vertebral centra, sacral ?I.

Left fibula, proximal end.
Right fibula, distal end.

Lufengosaurus hueni Young (1941b, 1947b, 1951)

Original Diagnosis. — "From large to gigantic size Plateosauridae,
Prosauropoda. Skull small. Teeth with short crown and long,
strong root. They are weakly spatulated and with coarse anterior
and posterior serrations. Vertebrae number: neck 10, dorsal 14?;
sacrum 3, and caudal 45 or more. Pectoral girdle with well-ossified
sternum. Pubes weakly constructed. Tibia comparatively short.
Mt. Ill is rather long. Anterior limbs are very short. Hand and
foot with the first claw are especially strong."

Locality

Yang Tsao Ti
(Loc. No. 3)
Hei Koa Peng
Hei Koa Peng
Hei Koa Peng

Hei Koa Peng

Hei Koa Peng

Hei Koa Peng
Hei Koa Peng
Hei Koa Peng
TaTi
TaTi
TaTi

Remains Referred to L. hueni Young

Catalog

No. CUP Element

2071

2062
2063
2064

2065
2066
2067
2068
2069
2070
2059
2060
2061

Claw

Claw, proximal end.
Claw, proximal end.
Right and left maxillary fragments, with the

?premaxilla.
Tibia and Tibiale, distal end.

Haemal arches.

Basisphenoid.

Right anterior maxillary fragment with teeth.

Right mandibular ramus with teeth.

Jaw fragment with teeth, left.

Tibia and tibiale, distal end.

Neural apparatus, dorsal vertebra.

62

FIELDIANA: GEOLOGY, VOLUME 15
Lufengosaurus magnus Young (1947b, 1951)

Original Diagnosis. — "Size one third larger than L. hueni, Ver-
tebrae robust, Centrum large and short. Scapula strongly ben ted.
Humerus-radius extremely short and massive. Hand short. Pelvic
girdle massive, ilium long, Ischium comparatively weakly built.
Pubis long and slender with thickened distal end. Tibia relatively
long as compared with the femur. Mt. Ill one half of the length
of the tibia. Both the hand and the foot are built in the same way
as in the case of L. hueni. Anterior leg is much shorter as compared
with the whole posterior leg."

Remains Referred to L. magnus Young

Element

Jaw fragment with teeth.
Jaw fragment with teeth.
Left fibula, proximal end.
Jaw fragment with teeth.
Proximal end of right ulna.
Crown of tooth.
Neural spine, caudal vertebra.
Jaw fragment.

Catalog

Locality

No. CUP

Unknown

2052

Unknown

2053

Hei Koa Peng

2054

Hei Koa Peng

2055

Hei Koa Peng

2107

TaTi

2056

TaTi

2057

TaTi

2058

Remains Referrable to Lufengosaurus sp.

Locality

No. CUP

Element

Yang Tsao Ti

2072

Haemal arch.

Hei Koa Peng

2073

Tibiale.

Hei Koa Peng

2074

Jaw fragment with teeth.

Hei Koa Peng

2075

Jaw fragment lacking teeth.

Hei Koa Peng

2076

Premaxillary fragment, right

TaTi

2077

Premaxilla, right.

TaTi

2078

Haemal arch.

TaTi

2079

Centrum, caudal vertebra.

TaTi

2080

Two metatarsals.

Yunnanosaurus sp. Young (1942, 1951)

Original Diagnosis. — "From the middle to rather large sized Pro-
sauropoda with the skull proportionately rather long, more than 3.5
the length of the anterior caudal vertebrae, ca. 4. Nasal opening
small, anterior orbital opening rather large. Orbit rounded and rep-

SIMMONS: NON-THERAPSID REPTILES 63

resents the largest opening of the skull. Upper temporal opening is
bean-shaped and can be seen mostly from the lateral aspect of the
skull. Lower jaw slender with small dental foramen. Teeth with
long pointed crown, distinctly spatulated in primitive Sauropod fash-
ion. Serrations are poorly developed. Vertebrae robust. Scapula
is strongly bending above the proximal expansion. Sternum is ossi-
fied and elongated. Humerus robust and shorter than the scapula.
Hand with strong lateral reduction. Ilium small with the iliac border
low. Ischium slender. Pubis rather thin. Femur and tibia massive,
the latter is only somewhat shorter than the former. Fibula rather
straight. Foot similarly built as that of Gyposaurus."

Remains Referrable to Y. huangi Young (Young, 1942, 1951)

Element

Six or seventh cervical vertebra.

First metacarpal, left.

left femur, proximal end.

Left fibula, proximal end.

Left femur, distal end.

Third and fifth metacarpals.

Right fibula, proximal end.

Distal ends of two fibulae.

Two centra, caudal vertebrae.

Skull and jaws, nearly complete, juvenile.

Maxillary and mandibular fragments.

Remains Referrable to Y. robustus Young (1951)

Catalog

Locality

No. CUP

Unknown

2039

Hei Koa Peng

2030

Hei Koa Peng

2031

Hei Koa Peng

2032

TaTi

2033

TaTi

2034

TaTi

2035

TaTi

2101

TaTi

2036

TaTi

2037

TaTi

2038

Catalog

Locality

No. CUP

Element

Unknown

2040

?18th caudal vertebral centrum.

TaTi

2041

Two dorsal vertebrae (seven and eight?)

TaTi

2042

Left maxillary.

TaTi

2043

Right maxillary.

TaTi

2102

Ilium.

Hei Koa Peng

2046

Vertebral centrum.

Hei Koa Peng

2047

Tooth fragments.

Hei Koa Peng

2048

Claw fragment.

Hei Koa Peng

2049
2044 j

Centrum, sixth or seventh dorsal vertebra.

Hei Koa Peng

and |
2045

Caudal vertebrae (2).

64 FIELDIANA: GEOLOGY, VOLUME 15

Remains Referrable to Yunnanosaurus sp.

Hei Koa Peng

2050

Tooth fragment.

TaTi

2099

Ilium fragment.

TaTi

2100

Ilium fragment.

Unknown

2051

Two teeth.

Infraorder Carnosauria

Family Teratosauridae

Sinosaurus triassicus Young (1948b, 1951)

Original Diagnosis. — "Carnosauria of gigantic size, Maxilla high.
Teeth with long massive root, compressed sharply pointed and curv-
ing backwards. Both the anterior and posterior edges are marked
by fine serrations."

A number of articulated neck, dorsal, sacral and caudal vertebrae
strongly built but comparatively slender to Lufengosaurus magnus;
part of the anterior and posterior limbs massively constructed but
the proportions of the appendicular skeleton are similar to Yunnano-
saurus sp. Hand short and broad.

Additional Remains Referred to Sinosaurus triassicus Young

Catalog No. CUP 2097
Material. — A fragment of the anterior part of the jaws with teeth ;
two isolated teeth.

Horizon and Locality. — Ta Ti, Dark Red Beds, Lower Lufeng
Series.

DESCRIPTION

The rami have been transversely fractured behind the symphysis
and disoriented during preservation (fig. 7,D). The alveolar bor-
der is acute and forms a narrow ledge above a rather thick but flat,
lateral wall. The right jaw fragment is the shorter.

The splenial sheaths the inner surface of the jaw at the symphysis
and the dentigerous border, and limits the meckelian groove which
passes forward below and internal to it.

The left jaw holds eight-nine teeth which lack crowns. The right,
in addition, possesses two large and recurved, narrowly compressed
broad teeth which are finely denticulated on their back edges. The
isolated teeth are flattened with longitudinal median depressions
(ref. V35, V48- Young, 1948b).

SIMMONS: NON-THERAPSID REPTILES 65

The referral of the jaw and teeth to S. triassicus is problematical
since similar materials are unknown for the type. The teeth vary
from known specimens in their greater compression and lack of ser-
rations on the anterior trenchant edges.

Remains Referrable to S. triassicus

Catalog

Locality

No. CUP

Element

Unknown

2095

?Centrum; ?third dorsal vertebra.

Unknown

2096

Tooth fragments (3).

Hei Koa Peng

2001

Teeth (24).

Hei Koa Peng

2002

Teeth (2).

Hei Koa Peng

2003

?Centrum; ?third dorsal.

TaTi

2004

Teeth (4).

TaTi

2005

Teeth (3).

TaTi

2098

Centra; one cervical, two dorsals.

Order Ornithischia

Suborder Ornithopoda

Infraorder Hypsilophodontidae

Diagnosis. — An ornithischian of small size. Mandible low ante-
riorly, slender and tapered; anterior ventral border bends medially
toward the symphysis; jaw higher and more convex posteriorly.
Teeth thecodont, overlapping, relatively simple and increasing in
size from front to rear. Dentary-predentary junction edentulous.

Tatisaurus oehleri sp. nov.

Holotype. — A fragment of a left mandible with teeth. Catalog
No. CUP 2088.

Horizon and Locality. — Ta Ti (Locality No. 8) from the Dark Red
Beds of the Lower Lufeng Series.

Diagnosis. — Same as for genus.

DESCRIPTION (fig. 11,A,B,C)

The ramus is low anteriorly, of slender proportions and broken in
front and in back of the tooth row. Viewed from above, it is slightly
sigmoid; from below, the inferior border is acute and bends antero-
medially toward the symphysis. All sutural contacts have been
obliterated by the extensive checkering of the bone.

l = IOmm.

Fig. 11. Tatisaurus oehleri (gen. et ep. nov.). Jaw viewed from the lateral
(A), medial (B) and dorsal (C) surfaces in association with the head of a rib (B).
(CUP 2088).

66

SIMMONS: NON-THERAPSID REPTILES 67

The jaw is biconvex, but the early oblique displacement of the
dental series from the midline exaggerates the lateral curvature,
while the alveolar border follows the conformation of the median
wall, i.e., moderately S-shaped and laterally concave. The outer wall
is weakly constricted at the level of the eighth-ninth teeth below
which the curvature of the bone becomes sharper. Posteriorly, the
curvature is greatly exaggerated and effects a plateau or shelf lateral
to the teeth. The apex of curvature appears as a well-defined but
low ridge which then becomes confluent with the shelf. The greatest
breadth of the "shelf" is about 7.0 mm. and it perhaps indicates the
life-presence of a cheek pouch.

The dentary becomes progressively deeper posteriad, but the
superior and inferior borders are parallel from the eighth or ninth-
thirteenth teeth. The profile of the superior border is sharply ele-
vated behind the tooth row but it is doubtful that it terminated in a
coronoid process since the lateral ridge (definitive in all ornithischia
possessing the element) is reduced and disappears at the cheek pouch.
It is not known whether the postcoronoidal region is as short as in
the more advanced ornithischia.

It is difficult to distinguish the tiny foramina for nervous and /or
vascular elements which are scattered over the extensively fractured
and pitted outer surface. Foramina oppose the fifth and twelfth-
fourteenth teeth, and with the exception of the first, penetrate the
bone at right angles. A group of at least five foramina lies above the
"ridge" at the lateral constriction and the fifth is the largest.

The splenial sheaths the inner wall, but its sutural union with the
more posterior jaw elements, if present, cannot be discerned. It
covers the anteriormost limit of the large meckelian fenestra and
groove which extends to the predentary.

Like the saurischian dinosaurs, the dentigerous border is higher
externally, but has a sigmoid configuration. The dentary holds 18
thecodont teeth which become larger posteriorly and are arranged in
a uniformly overlapping series. Anteriorly, the dentary-predentary
junction is edentulous. The functional teeth are worn and lack
crowns. Unworn replacement teeth (five) lie on the inner surface.

The dentition exhibits a slight degree of heterodonty. The roots
are generally subcircular or slightly constricted lateromedially, but
may manifest an inner swelling suggestive of a triangular cross sec-
tion. The crown-root junction of the smaller anterior teeth is vari-
ably constricted or expansive.

68 FIELDIANA: GEOLOGY, VOLUME 15

The crowns of the functional teeth are low, rather symetrically
triangular with gently curved or evenly bevelled, smooth polished
surfaces. The trenchant edges of the replacement teeth are coarsely
denticulated, but unlike most ornithischians, the lateromedial sur-
faces are not fluted. The anterior edge is the steeper; the apical
denticle is pointed slightly backward and bordered by three-four
marginal denticles (some with accessory cusps) . An anterior replace-
ment tooth appears adenticulate, perhaps due to incipient wear since
the mature teeth are small. The crown-root junctions are frequently
swollen, probably in response to wear but none of the replacement
teeth have definitive cingula.

Table 18.— MEASUREMENTS OF THE JAW OF
TATISAURUS OEHLERI (in mm.)

height breadth
Estimated length of the jaw (postcoronoid= one- third

total length) 78 .6

Length of the alveolar border 52 . 4

Anterior end of the dentary 4.0 3.6

Level of: 8th-9th tooth 13.0 12.4

constricted lateral wall 8.1

13th tooth 13.4 12.5

18th tooth ?18.6 11.4

?coronoid process ?15.6 ....

Maximum breadth of the cheek pouch (lateromedial) 14 .4

Discussion and Relationships.- — Since Tatisaurus is the temporal
equivalent of the earliest known ornithischian derived from upper
Triassic Rhaetic Beds in South Africa, it is considered that the rela-
tionships of the form can be drawn to the best advantage by a sys-
tematic survey of the groups which appear to be related to it.

HYPSILOPHODONTIDAE

The fragmentary Geranosaurus atavus Broom (1908; Haughton,
1924) from the Stormberg Series is the earliest representative, but
differs importantly from Tatisaurus in details of size and large, chisel-
like teeth. The jaws of Hypsilophodon foxii Huxley (1870; Hulke
1882; Nopsca, 1905) and Thescelosaurus edmontonensis Sternberg
(1940) are fashioned like Tatisaurus but taper forward only slightly
and decrease markedly in height at the dentary-predentary contact.
The coronoid process, indistinct in Tatisaurus is prominent in T. ed-
montonensis and blunt in H. foxii. While their tooth structures are
dissimilar, they are arranged in an overlapping series which arches
inward, but the pattern is reversed from the fifth-eighth tooth in

SIMMONS: NON-THERAPSID REPTILES 69

H. foxii. Similar to the progressive Nodosaurids, however, a splenial
element occludes much of the meckelian groove.

IGUANODONTIDAE

The jaw construction, while hypsilophodontid (spout-like preden-
tary-dentary contact and a short symphysis) shows a more prominent
coronoid process and a flatter symphysis than Tatisaurus. The
meckelian groove passes forward to approximately the same level,
but an obtuse prominent ridge marks the outer surface of the jaw
of Iguanodon foxii Owen (1874) which is correspondingly thickest
where it is penetrated by a series of five foramina. The overlapping
tooth row of Iguanodon is nevertheless not sigmoid but simply curved
to effect the lateral concavity and the teeth are elaborately flutted.

ANKYLOSAURIA

The diagnostic features of Tatisaurus were initially interpreted
as ankylosaurian. These forms, however, are strictly upper Creta-
ceous and of relatively larger proportions. The recognized Chinese
ornithosuchians are Ornithopoda (Young, 1944) and include no anky-
losaurs. The Asian ankylosaurs (from Mongolia) are all referrable
to the Nodosauridae.1

NODOSAURIDAE

Unlike Tatisaurus, the jaws of nodosaurs are generally massive
and invested in dermal bone which obscures the elements. Those of
Edmontonia rugosidens Gilmore (Russell, 1940) and E. longiceps are
more or less rectangular. Except for Pinacosaurus grangeri Gilmore
(1933) where the dermal bone is reduced, a splenial element covers
the meckelian groove (as in the Hypsilophodontiae) and the dentiger-
ous border lies at the posterior two-thirds of the dentary after its

1 Since this paper went to press, Crompton and Charig (1962, Nature, 196,
pp. 1074-1077) have published a preliminary description of a newly discovered
ornithischian, Heterodontosaurus tucki, from the transitional beds of the Upper
Triassic Cave Sandstones, South Africa. Compared with Tatisaurus, the jaw of
H. tucki has a well-defined coronoid process and the dentition includes an anterior
recurved caniniform tooth. While the general morphology of the cheek teeth
(concave crowns) is quite different from that of Tatisaurus, the teeth in both speci-
mens importantly lack cingula. Heterodontosaurus appears to be more closely
related to the Hypsilophodontidae than Tatisaurus, but both seem to show inter-
esting similarities to Upper Cretaceous forms. This further indicates that the
main radiation of Ornithischia probably occurred prior to the Upper Triassic
(Huene, 1948).

70 FIELDIANA: GEOLOGY, VOLUME 15

maximum depth has been attained. The slenderest jaws obtain in
the Canadian Dyoplosaurus acutosquameous Parks (1924) and in Ana-
dontosaurus lambei Sternberg (1928b), however, commensurate with
the ornithopods, the decrease in height at the predentary-dentary
contact is precipitous rather than gradual. Considerable intergroup
variability exists both with respect to (1) the inferior border of the
mandible — keeled (Edmontonia longiceps Sternberg, 1928a), acute
(Panoplosaurus mirus Lambe, 1919) or flanged (Europlocephalus tutus
Lambe Gilmore, 1923)— and (2) the predentary relationships-
forms a yoke between the rami (P. mirus), merely caps the symphy-
sis (Edmontonia spp., Paleoscincus sp.), or makes a minimal ingression
between the cojoined rami (P. grangeri). The inward curvature of
the dentary anteriorly is as strong in the cited forms as in Tatisaurus,
but the incompleteness of preservation vitiates comparison. The
coronoid element and postero-lateral ridge when present are pro-
nounced in all but Ankylosaurus magniventris Brown (1908) and
Panoplosaurus, while these features are only suggested in Tarisaurus.
The dentigerous border of nodosaurs is rather simply curved and
not sigmoid, but the displacement from the midline may be so ex-
treme (E. longiceps) that it overhangs the infero-internal border at
its midlength. While the number of teeth may vary from 11 (E.
rugosidens) to 17-21 (E. tutus), they occupy a space roughly com-
parable to that of the plateaued ninth -eighteenth teeth of Tatisaurus.
The teeth are grossly similar in outline, but they are elaborately
fluted as in the ornithopods and bear more or less well-developed
median ridges; those of P. grangeri alone lack the features of foldings
and definitive cingula which are conspicuous in its Asian relative
P. ninghsiensis Young (1935) .

ACANTHOPHOLIDAE

Tatisaurus is favorably compared to this group which shows a
sigmoid alveolar border; this feature, while not exclusively ankylo-
saurian, occurs in the more massive stegosaurs and ceratopsians
(Microceratops gobiensis Bohlin, 1953), but it delimits the present
form from the groups already considered. Two European genera
have been selected for comparison, Acanthopholis horridus Huxley
(1867), Struthiosaurus transylvanicus Seeley (1881) and S. austria-
cus Nopsca (1929). The nature of the teeth and jaw fragments of
Hylaeosaurus Owen (1872) preclude any affinity to Tatisaurus.

Acanthopholis horridus shows a sigmoid alveolar border and the
absence of an outer ridge, i.e., no coronoid process, irrespective of

SIMMONS: NON-THERAPSID REPTILES 71

the folded enamel surfaces of its teeth (Nopsca, 1923) . To my knowl-
edge, the mandible has never been figured and the original description
was largely based on post-cranial materials.

Drawings of the fragments of the mandibular rami and teeth of
Struthiosaurus sp. show that the alveolar border is sigmoid but that
it approaches the extreme mediad displacement observed for the
nodosaur Edmontonia. Accordingly, the internal wall of the man-
dible is concave in height while that of Tatisaurus is moderately con-
vex, but in length, the convexity of the jaws is quite comparable.
The meckelian groove is considerably larger in Struthiosaurus, but
it terminates anteriorly at approximately the same level. S. austri-
acus apparently has a weak predentary element forming a yoke be-
tween the rami, but the preservation of Tatisaurus does not permit
comparison on this point. While Struthiosaurus lacks a coronoid ele-
ment, the lateral side of the jaw is convex and sharply ridged. The
morphology of Tatisaurus is, then, somewhat intermediate between
it and Acanthopholis— the ridge is low and restricted largely to the
midlength of the ramus. A series of four large foramina occupy an
essentially similar position on the outer wall of Struthiosaurus and
might have resulted from the coalescence of several smaller perfora-
tions. The jaw of S. trannsylvanicus is less tapered than Tatisaurus.

Similarities in dental architecture, including patterns of wear
(Nopsca, 1929, fig. 5) form the greatest point of comparison. The
teeth of S. austriacus are graded from small to large anteroposteriorly.
In early use, the functional teeth first lose their denticulations, and
additional impairment produces a low median ridge and reduces the
cingulum (S. trannsylvanicus) to a cinguloid swelling. The ultimate
picture is a symmetrical, compressed crown with adenticulate trench-
ant edges and a low median rib. It is not known if the teeth were
oriented into an overlapping row. In S. trannsylvanicus, the dental
series numbers at least 20, but only 13 occupy a length commen-
surate with the total complement (18) of Tatisaurus.

Summary.— The specimen is significant in that it represents the
third find of ornithischia in the Triassic; Geranosaurus of the South
African upper Triassic-lower Jurassic was the first recorded and
placed into the primitive hypsilophodont family. In Tatisaurus, the
precoronoid part of the dentary and the relationship of its elements
is morphologically like the Jurassic-Cretaceous iguanodonts, partic-
ularly Iguanodon foxii, rather than the most primitive ornithopods
such as Hypsilophodon and Thescelosaurus where the splenial element
masks the forward course of the meckelian groove. It is, moreover,

72 FIELDIANA: GEOLOGY, VOLUME 15

a good deal more slender than any of the cited forms and tapers more
gradually toward the symphysis. The placement of the foramina,
however, is entirely comparable to these early appearing ornithopods.

The detailed structure of the jaw differs importantly from the
forms cited above; the apparent reduction or complete lack of a coro-
noid element and the distinctly sigmoid character of the dentigerous
border and tooth row resembles most closely the Upper Cretaceous
ankylosaur group, particularly the Acanthopholidae. The form of
the teeth and the pattern of wear especially is remarkably similar to
that of Struthiosaurus austriacus. Since, however, this particular
character occurs only in this form, it is likely that we are dealing with
a particularly conservative rather than a progressive feature and
Struthiosaurus may therefore retain the traces of its heritage.

Evolutionary Considerations of Tatisaurus

By their expansive premaxillae and armor, it seems feasible to seek
the ancestors of the Ornithischia among the Pseudosuchia (Romer,
1956). Yet, no pseudosuchian is known which expresses the orni-
thischian tetraradiate pelvis, toothless premaxilla or specialized den-
tition. Huene's suggestion (Young, 1951) that Platyognathus, with
its polygonal teeth and anterior jaw expansion, might serve as the
forerunner is vitiated by the knowledge of its crocodilian-like post-
cranial skeleton. Nopsca (1923) notes that certain camptosaurs (ex.
Rhabdodon) have teeth with tapered and elongated roots with feebly
polygonal cross sections. This suggests that the iguanodonts, to
which Tatisaurus appears most closely related on the basis of the
precoronoid portion of the jaw, as well as Platyognathus, perhaps
arose from a generalized sphenosuchid line which was sufficiently
plastic to be the predecessor of other evolutionary lineages such as
the crocodiles.

When ornithischians first appear in the Upper Triassic, they seem
already diversified. The jaw of the South African Geranosaurus
from the Stormberg Series has a concave upper surface which indi-
cates that the premaxilla was toothed. A toothed anterior jaw in
Tatisaurus is probably obviated by the narrowness of the bone, but
the dentition was specialized to conform to one of the more advanced
ornithischian families.

The Triassic materials are heterogeneous, and incorporated both
primitive and advanced characters. It is considered that the osteo-
logic affinities of Tatisaurus are to these primitive hypsilophodonts,
although the dentition is particularized as ankylosaurid, and that it

SIMMONS: NON-THERAPSID REPTILES 73

represents an early offshoot from the line of which Scelidosaurus
Owen (1861) is the base. So little is known about the pre-Cretaceous
evolution of the group that the suite of characters which seem to
ally the jaw with the advanced ankylosaurs may really be primitive
rather than diagnostic (Romer, 1959).

STRATIGRAPHIC AND PALEOECOLOGIC
CONSIDERATIONS

Continental Triassic beds are widespread in northern China, but
occur less well developed in the south where the facies are chiefly
marine. Depositional basins in southwest Sinkiang, southeast and
southwest Shansi and in Yunnan — the Lufeng Basin — have yielded
vertebrate fossils, but the temporal sequence of these Triassic sedi-
ments is discontinuous. In order to determine the age of these beds
more precisely, Young (1946) compared the vertebrate assemblages
from these localities to other faunas in the world during the Triassic
and noted their relative developments. Preliminary to a considera-
tion of the fauna from Lufeng which is rather homogeneous in all the
four fossiliferous horizons, it may be useful to visualize a chart com-
paring the Triassic continental stratigraphic divisions pertinent to
the following discussion based upon the work of Young, Huene (1940)
and Reeside et al (1957). The physical character of the rocks is dis-
cussed in this section, but the vertebrates have proven to be the more
sensitive indices of age.

Lower Triassic. — In Sinkiang (Chitai), Lower Triassic sediments
are well developed by the Tunghunshan and Shoufangkou Series.
The older has yielded three genera which appear in the South Afri-
can Lower Triassic Lystrosaurus Zone. Although Lystrosaurus and
Dicynodon are the principal anomodonts of the South African Kar-
roo as well, the Chinese area is relatively impoverished in terms of
diversity.

No.

of

species

Genera

S. Africa

Sinkiang

Dicyndon

Chasmatosaurus

Lystrosaurus

3

1

19

1 (Young, 1939a)

1 (Young, 1936)

1 (Yuan and Young, 1934)

At the type section in Sinkiang, taken at Fuyuan, the Triassic
lies conformably on the Upper Permian; the Tunghunshan fauna in-
cludes a fragmentary specimen of a probable eosuchian, Santaisaurus

74 FIELDIANA: GEOLOGY, VOLUME 15

yuani Koh (1940) which is apparently related (Romer, 1956) to the
Paliguanidae from the Karroo, Cistacephalus Zone. An additional
eosuchian fragment (Efremov, cited by Huene, 1940) has also been
described from the Upper Permian Rhophalodon Horizon (Zone 1)
of Russia. The anomodont character of the Chinese assemblage and
the diagnostic genus Lystrosaurus are, nevertheless, strong arguments
for a lower Triassic age. The genus is also recognized from the Trias-
sic Panchet Beds of India and from the Capitosaurus Level (Zone VI)
in Russia. Eosuchians are known as well from the Karroo Lystro-
saurus Zone.

Middle Triassic. — Three determinable genera have been recorded
from the Shansi Beds: Chasmatosaurus and Lystrosaurus (Young,
1958) from the lower levels (Lutzeyu, Wuhsiang) and Sinokanne-
meyeria pearsoni Young (1937) — osteologically very similar to Kan-
nemeyeria spp. from the Karroo Upper Beaufort Cynognathus Zone
— in the middle level. The Cynognathus Zone has variously been
regarded as Lower Triassic (Watson, 1942), Middle Triassic (Huene,
1940), or Upper Triassic (Broom, 1932). In Shansi, as in Sinkiang,
the Permian and Triassic sediments are entirely conformable and
relatively unfossiliferous, but Young (1946) reasoned that owing to
the high level at which Sinokannemeyeria was found and since the
horizon is apparently overlain elsewhere by a coal-bearing series of
Rhaetic age, the beds were deposited not earlier than the uppermost
part of the Middle Triassic and not later than the lowermost part
of the Upper Triassic. The finds of Chasmatosaurus and Lystrosaurus
connect the Lower-Middle (Chitai) and Middle (Wuhsiang) Triassic
faunas in China.

Upper Triassic. — In Sinkiang, the Upper Triassic is questionably
developed as the Kankou Series, and in Shansi the Sinokannemeyeria
Beds have been divided between the upper part of the Middle Trias-
sic and the lower part of the Upper Triassic. Upper Triassic -Lower
Jurassic vertebrate-bearing beds are represented in a structural basin
in Lufeng, Yunnan, where the age determinations were similarly
based upon the character of the representative vertebrates.

The sediments everywhere appear to have undergone typical red
bed development: (1) alternating red sandstone and shales — Tung-
hunshan Series, Sinkiang; (2) dark red shales, clays and sandstones
for the Lower Triassic and green sandstones with red sandy clays for
the Upper Triassic-Shansi. The character of the Lower Lufeng Series
is entirely like the Upper Triassic beds in Shansi. While physical
correspondence alone is inconclusive evidence of contemporaneity

SIMMONS: NON-THERAPSID REPTILES

75

since the vertebrates are individually exclusive, it may nevertheless
demonstrate somewhat equivalent conditions of deposition.

The predominately silty deposits of the Upper Triassic Moenkopi
and Chinle Formations of North America are fine textured like the
fossiliferous clays, shales and sandstones of the Lower Lufeng Series;
but otherwise, they feature lenticular and conglomeratic members,
etc. — particularly evident in the Chinle, lower Red Member — and

CHIN

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a.

Fig. 12. A chart showing the world distribution of vertebrate bearing horizons
during the late Paleozoic and early Mesozoic comparable in time to the Chinese
section.

the gypsiferous and ripple marked, cross-bedded sands wanting in
the Lower Lufeng Series (Akers et al, 1958). The Triassic-Jurassic
Kayenta Formation, from which Lewis secured a Tritylodon-like rep-
tile (Reeside et al, 1957), is typically silty, grading to sandstone to
the south-east; the sediments from southwest Utah and that part of
northern Arizona demonstrate a reddish siltstone and mudstones
with ripple marks and mudstone pellets characteristic of shallow

76 FIELDIANA: GEOLOGY, VOLUME 15

water deposition which are somewhat grossly similar to the Upper
Lufeng Series, but the beds at Lufeng become somewhat more cal-
careous toward the top of the section.

The German Upper Keuper, from which sauropods comparable
to those at Lufeng have been found, has been characterized as a
lagoonal, saliferous formation containing variegated marls, anhy-
drates and plant bearing sandstones and porous dolomitic limestones
(Gignoux, 1955). To the east in Upper Silesia and Poland, unioid-
bearing fresh water limestones occur which perhaps are attributable
to a facies change concomitant with isolation from the Alpine Sea.
While marly layers are developed much more extensively elsewhere
than in Lufeng during the Triassic, some poorly preserved plant re-
mains have been found (Chang, 1947), but it is doubtful that these
are Equisitales like those from the German Keuper (Gignoux, 1955).
Although the sediments of the Lufeng Series were deposited under
terrestrial conditions in an area isolated from the Triassic Sea enter-
ing Yunnan from the south, unioid-bearing marl-like rocks do occur
in the Upper Series.

In Tanganyika (German E. Africa), the Manda-Schichten upper
bone beds, K8 (Krenkel, 1939), consist of rose feldspathic sandstone
and marl, and iron containing calcareous concretions. A prosauro-
pod, Thecodontosaurus, comparable with the Lufeng Yunnanosaurus
is derived from these strata which are, as in Lufeng, disconformably
separated from the lower bone beds (K6) by a sandstone. The sec-
tions are, however, not entirely comparable in detail. The mineral-
ogy of the Lufeng sediments is unknown, but iron-bearing rocks with
calcareous concretions are common to both. The lower bone beds
contain Dicynodon species like the lower Triassic Sinkiang sediments.

Perhaps the depositional history of the upper Triassic Red Beds
of the South African Stormberg Series parallels that of the Lufeng
section most closely. These consist of well-layered friable, red violet
clay marls penetrated by carbonate and red and green sandstones.
In many places, silicified woody stems of over y<i m. thick are found,
and their presence has been taken to indicate that moist conditions
prevailed, or even an alteration of rainy periods (Huene, 1925b).
Haughton (1924) has considered a semi-arid climate for this time,
since evaporites such as salt and gypsum are absent. While the sedi-
ments are largely bedded, many red marl complexes are discordant
denoting active periodic erosion. Huene believes that the fine-tex-
tured marls represent lagoonal environments from which fish and
crustaceans have been collected, while the coarser sediments resulted

SIMMONS: NON-THERAPSID REPTILES 77

from flooding. The overlying Cave Sandstone (Triassic -Jurassic)
purported to be aeolian in origin, indicate that there was a slow in-
crease in aridity, concomitant with which the residual lagoons and
pools with their faunas became covered over with sand derived from
the desiccated uplands to the south. Organic remains are found in
the lowest levels. The evolution of the faunas progressed from large
saurischians (Plateosaurus, etc.) and smaller and lightly built forms
in the red beds to smaller and fewer saurischians, an ornithischian
and the more primitive crocodilian-like creatures in the Cave Sand-
stones. A degree of faunal overlap does occur nevertheless, due per-
haps to the passing back and forth from the marshes to the highlands
at certain times of the year (Huene, 1925b).

The detail to which the regularity of the bedding corresponds to
that in Lufeng cannot be determined from the descriptions of the
section in the literature. Earlier it was noted that the Lower Series
is highly variegated perhaps due to the inclusion of plant remains
which would have had the effect of differentially reducing the iron
contained in the rocks. Rather moist conditions would certainly
have catalyzed the process and from the scattered nature of the fos-
sil record and the alternating sequence of lithologies, it might be con-
cluded that the basin was crossed by streams of varying competencies
and that even periodic flooding occurred. It is rare that completely
articulated skeletons were found; rather, the bones occur predomi-
nately as scattered nodular elements indicating transport rather than
scavenger action — the epiphyseal regions of the long bones are intact
and have not been gnawed. In his excellent survey of red bed devel-
opment, van Houton (1948) states that nodules of concretionary iron
oxide and calcium carbonate may be formed about fossil bones during
or shortly after deposition. In section, only some of the smaller
bones were impregnated with red color throughout. His thesis is
that red bed formation is optimum where environmental conditions
lie between the extremes of moderate rainfall and semi-aridity under
relatively high temperatures and that rapidity of deposition is most
favorable for the preservation of color in detrital sediments from orig-
inal red bed source areas. The uppermost beds of the Lufeng Series
and the dull-purplish beds of the Lower Lufeng Series contain evap-
orites and calcareous concretions respectively which are attributed by
van Houten to ground water action in warm, humid climates marked
by intense dry seasons. Intermittent aridity might have produced
the relatively thin sandstone dividing the first and second fossiliferous

78 FIELDIANA: GEOLOGY, VOLUME 15

horizons and that serving as a basal marker for the Upper Series,
although these are described as merely massive and otherwise fea-
tureless except for rock fragments in the former (fluvial?).

Toward the top of the Lower Lufeng section, Young's records
show an increase in the number of individuals at his principal col-
lecting sites: Shawan, 24; Tachung, 30; Heilungtan, 45. These fig-
ures, however, probably lack ecologic significance and reflect rather
a sampling bias.

It is evident that a true estimate of the living population cannot
be inferred from the fossilized accumulations. Of the nearly 100 indi-
viduals reported, more than 85 per cent are the larger prosauropods.
The concentration of fossils and their extreme degree of disarticula-
tion makes it probable that the majority were upland forms carried
in during periods of flooding. The poor record of Triassic ornithis-
chians has been explained on the same basis (Huene, 1950). The
few rare articulated skeletons, in addition to the coprolitic nature of
some materials, may infer little transport and imply that some of the
forms may have moved back and forth onto the flood plain proper.
Pseudosuchians, i.e., Platyognathus sp. and the prosauropod, Lufen-
gosaurus, may be cited as animals which possibly ascribed to this
latter category.

The fish and crustacean yielding variegated beds of the Upper
Lufeng Series signify a change in the environmental situation which
has been considered in the initial sections of this paper. A facies
shift is indicated by the fauna peculiar to pond environments. The
Shihmen Sandstone (Jura-Cretaceous) forming the uppermost levels
of the Lufeng Section, but disconformable with it, differs from the
Cave Sandstone in being current-crossbedded. Moreover, it con-
tains a basal lenticular pebble to massive boulder conglomerate; the
sandstone demonstrates shaley intercalations toward the top (Bien,
1941). The calcareous features of the fossiliferous zones and their
faunas (turtles, pelecypods, etc.) are probably good indicators of
shallow water environments with the development of temporary lakes
fed by streams bearing dissolved calcium salts which at times pro-
duce the strongly indurated limestone bands of the upper middle part.

Most of the Lower Lufeng vertebrates show close affinities to the
Stormberg fauna and there is the same general trend of faunal evolu-
tion with the increasing youthfulness of the sediments. In view of
the apparent flood plain environment interpreted for these sediments,
however, and the sharp faunal break above which no vertebrates
(save fish and turtles) appear, the progression may be entirely arti-

SIMMONS: NON-THERAPSID REPTILES 79

ficial. The paucity of articulated skeletons is, nevertheless, evidence
that some upland forms did frequent the basin lands.

Studies of parallel patterns of sedimentation in geographically-
distant sites have little dependency per se as determiners of the time
element. The most definitive proof of contemporaneity is faunal
identity, and reference to the constitution of the assemblages was
unavoidable in the paragraphs above. By means of the rocks, the
Lower Lufeng Series at best can be determined to be Upper Triassic
while those of the Upper Series can only be said to transgress the
Triassic-Jurassic boundary.

ZOOGEOGRAPHICAL AND PALEOGEOGRAPHIC
CONSIDERATIONS

Young's contributions (1946, 1951) established the basis for the
interpretations accorded the new fossil evidences. The taxonomic
work seemed to indicate that there was either a particular corre-
spondence to Triassic-Jurassic forms, especially in South Africa, or
that the larger taxonomic units (coelurosaurs, carnosaurs, etc.) were
represented in like-proportions in faunas when the direct comparison
of forms was not feasible.

His earlier paleogeographic assessment was reinforced only by the
generic identity of the Lower (Sinkiang) and Middle (Shansi) Tri-
assic assemblages — about 60 per cent of the forms — rather than by
the Upper Triassic Lufeng fauna where only one-ninth of the ele-
ments (9 genera, 14 species) were similarly involved — notably by the
single form, Gyposaurus. The problem of interpreting close faunal
ties for the Lufeng assemblage upon such slight evidence was, how-
ever, made less precarious by the common paucity of the pseudo-
suchia and carnosaurs. The exceptional therapsid Bienotherium is
cited as an equivalent of the South African and North American
Tritylodon and tritylodon-like form respectively.

Table 19, a compilation of comparative forms, serves as a resume
pointing out other refractions noted by Young in his considerations
of the faunal relationships and those noted by the findings reported
in this paper.

THECODONTS

Pseudosuchia. — With the exception of two North American forms
occurring where the Triassic-Jurassic stratigraphic boundaries are in

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SIMMONS: NON-THERAPSID REPTLIES 81

doubt, pseudosuchia are limited to Upper Triassic sediments. The
Lufeng fauna as described by Young included one barely determin-
able animal, Platyognathus hsui from Huangchiatien (second fossil-
iferous horizon). The present collection has yielded a diverse array
of forms derived essentially from the same horizon (Ta Ti and Hei
Koa Peng) which have been compared to South African and North
American types; none has yet been found above or below the sedi-
ments just bordering the Upper Series. The levels at which related
thecodonts are found have been tabulated in Table 20. All but
Dibothrosuchus and CUP 2084 resemble elements in the Stormberg
Series.

Dibothrosuchus is similar to Ornithosuchus in the shape of its skull,
but resembles Hesperosuchus and Parringtonia in most other respects.
The jaw of Strigosuchus is hesperosuchid-like. The forms, then, can-
not be older than the lowest part of the Upper Triassic, but their
upper limit in time is ill-defined as Upper Triassic-Lower Jurassic.

The sphenosuchid-like appearance of the skull of Platyognathus
indicates an age not later than the Upper Triassic, but the complete
investiture of the body by scutes in primitive crocodilian fashion is
like the North American Protosuchus (Orange Red Sand, Moenhave
Formation, Dinosaur Canyon sandstone member) which, like Hes-
perosuchus, enjoys a questionable stratigraphic position. Reeside et
al (1957) considers the Moenhave to be Upper Triassic; Harshbarger
et al (1958) considers the orange red sand the lower Member of the
Moenhave (the basal formation of the Glen Canyon Group) not
younger than the Middle Jurassic (Carmel Formation), and inter-
prets it like Colbert and Mook (1951) as both Triassic and Lower
Jurassic. The decision for Platyognathus depends on whether em-
phasis is placed upon the more conservative general character of the
skull or upon the suite of apparently independently evolved, highly
adaptive characters of the postcranial skeleton.

Pelvic girdle and femoral fragments of the indeterminate pseudo-
suchian CUP 2984 bear some resemblance to Typothorax from the
Texas Dockum Group and the New Mexican Chinle Formation. The
Stagonolepidae as a whole are of Middle Triassic age in Europe and
of Upper Triassic age in North America.

Parasuchia (Phytosaurs) .• — Incomplete skull and jaw fragments
of Pachysuchus imperfecta Young (1951) derive from the upper fos-
siliferous horizons of the Lower Lufeng Series. Phytosaurs are major
components of European and North American assemblages and ap-
pear to be an exclusive development of the Triassic. In America,

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SIMMONS: NON-THERAPSID REPTILES 83

they are known from the Dockum, Chugwater and Cumnock For-
mations. The Indian genus Brachysuchus is reported from the Ma-
leri Schichten with two other poorly known forms, and perhaps from
North America as well; it emphasizes the paucity of like forms
from Asia. That the South African group is devoid of phytosaurs
is of particular interest to this discussion. Pachysuchus has been
compared to Mystriosuchus planirostris (Germany) and to Rutiodon
carolinensis (North America).

SAURISCHIANS

The saurischian remains are of limited time diagnostic value.
Prosauropods, known mostly from isolated fragments, are the dom-
inant forms and appear to be typically Upper Triassic forms; Lufen-
saurus hueni is the most complete specimen. "Structurally, the posi-
tion of the skull to the vertebral column, the primitive features of
the teeth, presence of abdominal ribs, the absence of the foot-like
expansion of the pubis and the relative length of the femur, exceed-
ing that of the tibia and fibula and five digits of the hand and foot
are all primitive characters which are rarely or never found in the
Saurischia of later age (Young, 1939a)."

Coelurosaurs. — These are known from the second fossiliferous ho-
rizon of the Lower Lufeng Series. They are so imperfectly realized
that it was considered expedient to refer them (Lukousaurus, CUP
2089, 2090, 2091) to the general Upper Triassic family, the Podoke-
sauridae. Only Lukousaurus is known by cranial materials.

Lukousaurus and other Podokesauridae occur in Europe and
North America in the Upper Triassic sediments. CUP 2089 has
been related to the North American Coelophysis. The only compari-
son afforded the femur CUP 2091 was to an Australian Upper Cre-
taceous form. No coelurosaurs are recognized from the African
assemblage, but Young listed Gryponyx as the faunal equivalent of
Lukousaurus.

Carnosaurs.- — Remains of the sole Lufeng carnosaur, Sinosaurus
triassicus are ubiquitous in the saurischian facies, and Young (1946)
compared it to the German Teratosaurus suevicus. It has also been
cited as the faunal counterpart of the South African Upper Triassic
Orosaurus; while these are not closely compared, it is striking that
both assemblages are characterized by individual specimens of the
Teratosauridae. Elsewhere, the family ranges from the Middle-
Upper Triassic of Europe (3 genera) and North America (1 genus).

84 FIELDIANA: GEOLOGY, VOLUME 15

The jaw (CUP 2097) tentatively identified as that of S. triassicus
may actually represent a second carnosaur.

Among the carnosaurs, the range of generically identical forms is
very broad. An advanced megalosaurid, Antrodemus, has been ten-
tatively identified from east Asia, North America and east Africa.
Similarly, the North American tyrannosaurid, Aublysodon, is reported
from east Asia. It may be considered that carnosaurs, therefore, as
indicators of faunal relationships, need relate only to familial asso-
ciations. The contribution of Sinosaurus to the faunal complex is
in this way directly comparable to that of the South African genus.

Prosauropods. — Saurischia comparable to the Lufeng prosauro-
pods occur in Triassic beds world-wide in distribution.

Age

Geographic position

Site

Lower-Upper Triassic

North America

Phoenixville Tunnel, Pa.

Upper Triassic

Tanganyika

Manda-Schichten, upper
bone bed.

India

Maleri-Schichten.

Germany

Keuper.

South Africa

Red Beds.

"Rhaetic (?)"

South Africa

Cave Sandstone.

The massive Lufengosaurus resembles the Knollenmergel Plateo-
saurus fraasianus of Germany more closely than the correspondent
South African species; Yunnanosaurus spp. however have been com-
pared to Massospondylus of the Red Beds and Cave Sandstones,
although the genus is also known from India and east Africa. The
referral of the most common and rather completely known animal,
Gypsosaurus sinensis, to the South African genus from the Cave
Sandstone (G. capensis) is particularly significant.

ORNITHISCHIA

The new find of Tatisaurus oehleri in the second fossiliferous hori-
zon evidencing both primitive and relatively advanced characters is
particularly pertinent both to the considerations of the time element,
and to the faunal relationships. The geographic distribution of the
first recorded ornithischians is scattered discontinuously — in South
Africa and North America. Although incomplete, Tatisaurus is
more favorably compared to younger European forms which are not
older than Upper Jurassic rather than to Geranosaurus but it never-
theless contributes to the Lufeng assemblage in like proportions.

SIMMONS: NON-THERAPSID REPTILES

85

Ornithischians are rare in Upper Triassic sediments. Gerano-
saurus is derived from the Cave Sandstone, South Africa and is
Rhaetic in age. The progressive ornithischian characters of Tatisau-
rus which resemble the Upper Cretaceous ankylosaur Struthiosaurus
have been considered conservative features which are not indicative
of a direct lineage. It is interesting that the earliest ornithischians
are a heterogeneous group, but are mutually associated with forms
of a more or less late Triassic age.

THERIODONTS

Although outside the scope of this paper, it should be mentioned
that the Lufeng sediments have yielded mammal-like reptiles, the
cynodont Kunminia minina Young (1947a) and the ictiodosaur Bi-
enotherium Young (1940a). Cynodonts appear generally throughout
the Upper Permian to the Upper Middle-Lower Upper Triassic Kar-
roo sediments and their range elsewhere in the world is essentially
the same.

Time

Permian

Upper-Middle Triassic
Lower-Upper Triassic

South

Africa

Time equivalent

Geographic

(zone)

strata

location

Endothiodon-

Ruhuhu-Gebiet:

Tanganyika

Cistacephalus

lower Bone Bed.

Zone

Cistacephalus

Chiweta:

Nyassaland

Zone

upper Bone Bed.

Pareiosaur Zone,

Russia

Zone IV

Upper Rio do Rasto

South America

Cynognathus

Manda-Schichten :

Tanganyika

Zone

upper Bone Bed.

Kunminia is too poorly known to afford direct comparison with
any of the forms representative of the localities cited above; it oc-
curs at Huangchiatien just below the purported Triassic-Jurassic
boundary.

Ictidosaurs range into the red beds and Cave Sandstones of the
Karroo Upper Triassic to the Jurassic boundary and are known
(Archaeodon) from the Stormberg Series in southwest Africa and from
the Kayenta Formation of Arizona (Averett er al, 1955) . The group
is evidenced in Jurassic sediments, Trityodon being closely compared
to Bienotherium.

86 FIELDIANA: GEOLOGY, VOLUME 15

Oehler's collection of therapsids, now under study by Drs. E. C.
Olson and J. Hopson from the University of Chicago, have yielded
a wealth of new Bienotherium materials which demonstrate a more
complex structure than hitherto recognized for the genus. The form
ranges throughout the Lower Lufeng Series.1

SUMMARY

The fauna of the Lower Lufeng Series is best described as cosmo-
politan. Relative to the standard section of the Triassic (Germany),
the sediments should probably be classified Upper Triassic, equiva-
lent in time to the Upper Keuper, Knollenmergel facies. Support
for this correlation is based upon the generalized structure of the
saurischian fauna, but there are many instances of forms morpho-
logically related to animals derived from Rhaetic, Jurassic and even
younger beds. For example, Platyognathus is similar to Protosuchus
(Upper Triassic-Lower Jurassic) and to Sphenosuchus (Upper Tri-
assic Red Beds, Stormberg Series) . Prosauropods are typically Up-
per Triassic forms, yet it is possible to infer a somewhat younger age
from the numerous examples of Gyposaurus (and the theriodonts) .
In reference to the North American section, a tritylodont has been
found in the uppermost level of the Kayenta Formation bearing
likeness to Bienotherium and to Tritylodon from the Red Beds and
Cave Sandstones (?Rhaetic) of South Africa. The opinion has been
expressed (Reeside, et al, 1957) that the Kayenta may be Upper Tri-
assic in time, but the dinosaur Megalosaurus weatherilli, more com-
parable to the Middle-Late Jurassic megalosaurids of Europe than
to the Late Triassic forms in its proportions, derives from a lower
level than Tritylodon.

The theriodont evidence speaks for a Rhaetic or Lower Jurassic
age at the earliest. The ictidosaurs, while a highly advanced spe-
cialized group may also be a relatively small and possibly conserva-
tive aggregation among themselves and one might not expect them
to be a particularly definitive index of stratigraphic contemporaneity.
Bienotherium has been compared (Watson, 1942) to the Upper-
Middle Triassic cynodont Diademodon (Compsognathus Zone). For
the present, it is probably safer to place the greatest reliance upon
the more profuse suarian elements of the Lufeng fauna and to de-

1 Patterson and Olson (1961, Internat. Evol. Mammals, Kon. Vlaamse Acad.
Wetensch. Lett. Sch. Kunsten Belgie, Brussels, pp. 129-191) have recently pub-
lished a description of a triconodontid mammal from Hei Koa Peng of Upper
Triassic age.

SIMMONS: NON-THERAPSID REPTILES 87

emphasize the importance of the mammal-like reptiles where strati-
graphic problems are the principal concern.

The relationships of the Lufeng non-therapsids is predominately
to European, South African and North American forms. The Pseu-
dosuchia relate directly to North American and South African ele-
ments. Coelurosaurs, with which the Lufeng fauna now appears to
be richly endowed, have no South African components. There is,
however, an essential correspondence in the contribution of carno-
saurs, prosauropods, and ornithischians to the faunas of Lufeng and
South Africa during this same approximate geologic time, notwith-
standing the more specific relations of some of the prosauropods to
European forms.

The non-therapsids have an old world flavor despite the apparent
overlap in some groups to the North American elements. Impor-
tantly, the prosauropod contribution is large and for the most part
lacking in Triassic new world assemblages (other than Paleosaurus) .
Instances in which the vertebrates as a group or as individuals
fail to correspond to South African forms are rather exceptional.
Young's interpretation of the cosmopolitanism of the fauna and their
essentially African flavor is supported by the therapsid evidence and
by the important discovery of the early ornithischian.

Equal emphasis has not been accorded to all parts of the Lufeng
Basin where the fauna is known almost entirely from the Lower
Series. However, even here, the general mode of collecting, i.e., from
surface nodules, by two individuals with different habits has yielded
different results. The present collection has brought to light several
new forms and it is most probable that the diversity of life of the
Lufeng Basin is greater than now known. Re-exploration of the
beds is decidedly warranted and additional fossil evidence will clarify
the existing uncertainties as to the time factor.

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