SMITHSONIAN CONTRIBUTIONS TO THE MARINE SCIENCES ? NUMBER 33 
Turbidites Reworked by Bottom Currents: 
Upper Cretaceous Examples from 
St. Croix, U.S. Virgin Islands 
Daniel Jean Stanley 
SMITHSONIAN INSTITUTION PRESS 
Washington, D.C. 
1988 
A B S T R A C T 
Stanley, Daniel Jean. Turbidites Reworked by Bottom Currents: Upper Cretaceous Examples 
from St. Croix, U.S. Virgin Islands. Smithsonian Contributions to the Marine Sciences, number 
33, 79 pages, 63 figures, 3 tables, 1988.?Sedimentological study of the Late Cretaceous 
volcaniclastic deposits in St. Croix, U.S. Virgin Islands, emphasizing primary structures and 
bedforms, reveals a remarkable suite of sandy lithofacies. An inventory of the different sand 
types in several formations shows that a natural continuum of deposits exists between 
downslope-directed gravity flow and bottom current-tractive "end-member" deposits. Most 
sandy strata, herein termed "intermediate variants," record primary emplacement by turbidity 
currents, probably from the north, and a subsequent reworking of these layers by bottom currents 
flowing toward the west. The sand layers accumulated in a proximal setting, perhaps slope 
aprons, and these were then reworked along bathymetric contours. The lower portion of sand 
layers typically displays the original graded (A) turbidite division, while the texturally cleaner 
mid and upper parts of such strata usually show structures more typically associated with tractive 
transport. Photographs of polished slabs and large thin sections of the diverse Cretaceous sand 
layer types on St. Croix, reproduced at a 1:1 scale, may serve as a basis for comparison with 
other deep-water formations in the modern and ancient record. They may be most useful in 
interpreting sequences such as those on St. Croix where a solely turbidite or gravity-emplaced 
interpretation is inadequate. 
This petrologic investigation also sheds further light on the paleogeography of the region. 
Examination of the sandy volcaniclastic sequences supports earlier hypotheses that they 
accumulated in a tectonically active island-arc setting. A strong tectonic and volcanic imprint 
is displayed by the syndepositional deformation of fabric, bedforms, and primary structures. 
Paleocurrent analyses indicate that, in what was to become the northeastern part of the 
Caribbean, the predominant bottom-current trend during Late Cretaceous time was roughly 
parallel to the surface circulation pattern, i.e., directed toward the west. The vigorous reworking 
of coarse sand and granule turbidites, and the development of bioturbation structures in tractive 
deposits indicate that, although the paleo-Atlantic was geographically much narrower, 
bottom-water circulation in this region was not restricted nor were bottom waters anoxic. 
Recognition here of the diverse suite of reworked sandy turbidite lithofacies, poorly documented 
to date, can hopefully serve to clarify other cases in both the modern and rock record where 
there has been interaction between bottom currents and turbidity currents. 
OFFICIAL PUBLICATION DATE is handstamped in a limited number of initial copies and is recorded in the Institution's 
annual report, Smithsonian Year. SERES COVER DESIGN: Seascape along the Atlantic coast. 
Library of Congress Cataloging in Publication Data 
Stanley, Daniel J. 
Turbidites reworked by bottom currents. 
(Smithsonian contributions to the marine sciences ; no. 33) 
Bibliography: p. 
SupLofDocs.no.: SI 1.41:33 
1. Turbidites?Virgin Islands of the United States?Saint Croix. 2. Geology, Stratigraphy?Cretaceous. I. Title. 
II. Series. 
QE471.15.T8S73 1987 552'.5 87-600196 
Contents 
Page 
Introduction 1 
Acknowledgments 1 
A Review of the Problem 2 
Methods 5 
Summary Review of the Pre-Tertiary Geology of St. Croix 11 
Sedimentary Evidence for Downslope Transport 15 
Base-of-Slope Depositional Settings 15 
Slides, Slumps, and Debris-Flow Deposits 16 
Shallow-Water Components in Some Mass-Flow Deposits 17 
Sediment Failure and Deformed Structures in Slope Deposits 22 
Paleocurrent Analysis 31 
Turbidite Sedimentation: The Preliminary Transport Mode 36 
Characteristics of Turbidites on St. Croix 36 
Complete versus Incomplete Turbidites 38 
Questionable Turbidites 45 
Bottom-Current Transport: A Subsequent Depositional Mode 50 
Characteristics of Tractive-Current Deposits on St. Croix 50 
Paleocurrent Analysis 62 
Bottom Currents and the Reworking of Turbidites 63 
Characteristics of Variant Sandy Layers on St. Croix 63 
Interpreting the Depositional Origin of Variants 63 
Bioturbation and Its Significance 63 
Turbidite to Reworked-Sand Continuum 71 
Conclusions 72 
Literature Cited 77 
in 
Turbidites Reworked by Bottom Currents 
Upper Cretaceous Examples From 
St. Croix, U.S. Virgin Islands 
Daniel Jean Stanley 
Introduction 
This study examines the primary sedimentary structures of 
sandy marine deposits that appear to have been initially 
emplaced by turbidity currents and associated gravity flows, 
and then were subsequently reworked by bottom currents 
sweeping the seafloor at depths below wave-base. Most earlier 
investigations that deal with this topic have usually?and 
rationally?emphasized the contrasting characteristics of end-
member sandy facies that can be used to distinguish 
well-defined turbidites from deposits essentially emplaced by 
bottom-current (Heezen and Hollister, 1971, ch. 8 and 9; 
Hollister and Heezen, 1972, table 2; Bouma and Hollister, 
1973, table 1; and Stow and Lovell, 1979, tables II and V). 
This approach to the interpretation of depositional processes 
of deep-sea sands is admittedly much simplified and far from 
comprehensive, and sediment types are almost certainly more 
numerous and varied than has been described. 
It is the premise of this investigation that sandy marine 
layers, which are intermediate, or transitional, variants between 
classic turbidites and strata reworked by well-defined bottom 
currents, are probably much more common and wide-spread 
than is generally recognized. Most publications treating sand 
transport processes in modern oceans and the deposition of 
deep marine sandstones preserved in the rock record usually 
do not detail or illustrate such intermediate facies. It follows 
from this that, in many cases, the transport origin of these 
depositional variants has been misinterpreted (usually as 
turbidites). 
Hsu (1964:383) has suggested that the faulty identification 
of facies has probably caused confusion as well as error in a 
number of paleogeographic reconstructions. In the case of rock 
units that include both graded bedding and sandy layers 
Daniel Jean Stanley, Senior Oceanographer, Division of Sedimenlology, 
Department of Paleobiology, National Museum of Natural History, 
Smithsonian Institution, Washington, DC. 20560. 
deposited by bottom currents, it is logical to consider 
intermediate variants (that is, strata that show attributes of 
both facies) in order to better evaluate depositional conditions. 
In such instances, any thorough paleobasin study should 
include a rigorous assessment of the complete suite of primary 
physical and biogenic structures. 
The present work details rock units in St. Croix, U.S. Virgin 
Islands in the northeastern Caribbean (Figure 1) which, to date, 
have been interpreted primarily as turbidites (Whetten, 1966b; 
Speed, 1974). This monograph illustrates the diverse as?
semblage of sedimentary and biogenic structures characteristic 
of the Upper Cretaceous (Campanian to Maestrichtian) 
Caledonia Formation and associated and volcaniclastic units 
exposed on St. Croix (Figure 2). Photographs of the major 
sedimentary and biogenic structures are reproduced, where 
possible, at a 1:1 scale. In addition to serving as an illustrative 
reference for the interpretation of deep-marine, sandy litho?
facies and for sediment-transport analysis, this type of study 
may have paleogeographic value. For example, it could serve 
to refine, at least in a modest way, our understanding of the 
paleobasin conditions, including slope- and bottom-water 
circulation patterns, that occurred in this part of the Caribbean 
toward the end of the Cretaceous. 
ACKNOWLEDGMENTS.?The assistance of Messrs. L. Ford 
and H. Sheng, National Museum of Natural History (NMNH), 
Smithsonian Institution, in cutting and polishing rock slabs and 
making numerous large thin sections used in this study is 
appreciated. Thanks are also expressed to Mr. Sheng for his 
help in identification of minerals in thin section, separation of 
heavy minerals, and chemical and microprobe analyses of 
selected rock samples. Photos of the many polished rock slabs 
and thin sections were made by Mr. V.E. Krantz, Photographic 
Division, NMNH. Drafting was done by Ms. M. Parrish and 
typing by Ms. D. Larkie, both of the Department of 
Paleobiology, NMNH. 
The West Indies Laboratory (W.I.L.) of Fairleigh Dickinson 
SMITHSONIAN CONTRIBUTIONS TO THE MARINE SCIENCES 
ATLANTIC OCEAN 
D o m i n i c a n ST. CROIX 
e p u b l i c 
u e r t o CED 
R i c o 
, / . 
% 
4 
FIGURE 1.?Map showing location of St. Croix, largest of the U.S. Virgin Islands, in northeastern Caribbean Sea. 
University at Teague Bay, St. Croix, U.S. Virgin Islands, 
kindly provided facilities and served as the supportive base 
from which I conducted this study during six field visits, from 
1981 to 1986. Drs. R.F. Dill, former Director, and D.K. 
Hubbard, geologist, at W.I.L. were enthusiastic hosts who 
guided me during the early phases of the field investigation. 
Dr. Hubbard also generously provided several aerial pho?
tographs reproduced in this study, and provided a most helpful 
review of the manuscript. Drafts of the manuscript also were 
read by Drs. LJ. Doyle, University of South Florida, CD. 
Hollister, Woods Hole Oceanographic Institution, and J.T. 
Whetten, Los Alamos National Laboratory. Funding for the 
study was provided by several Scholarly Studies Program 
awards through the Office of Dr. D. Challinor, Assistant 
Secretary for Research at the Smithsonian Institution. 
This is West Indies Laboratory Contribution Number 168. 
A Review of the Problem 
In an important essay relating sedimentation to tectonics, 
E.B. Bailey, in 1930, called attention to, and contrasted, two 
well-defined and often distinct bedforms displayed by marine 
sandy sediments preserved in folded belts. He attributed 
cross-bedded and non-graded deposits to bottom-current 
transport processes; he attributed the other, strata showing 
graded bedding, to the settling of particles through compar?
atively still bottom water. In a later paper Bailey (1936:1716) 
concluded that "current-bedded sandstones belong to relatively 
shallow water (or to the air), and graded-bedded sandstones 
belong to relatively deep water." The past half century of 
research has shown these earlier ideas on marine sediment 
transport to be essentially in error.. 
The pioneer works by, among others, Kuenen (1937, 1938), 
Bell (1942), and Kuenen and Migliorini (1950), showed that 
gravity-driven turbidity currents are a major cause of graded 
bedding in sands. Since World War II the development of 
underwater photography and the means to measure the velocity 
and direction of current How in deep water have led to an even 
clearer picture of deep-sea processes. For example, it has been 
clearly demonstrated that ripples, scour marks, and associated 
tractive-surface and internal-bedform features, including cross 
lamination typically produced by bottom currents, are widely 
prevalent on modern ocean margins and in basins at highly 
variable depths (Heezen and Hollister, 1971:335^21). 
It is now generally recognized that graded bedding and 
stratification produced by tractive transport are not repre?
sentative of essentially different, mutually exclusive sandstone 
facies as previously proposed. Rather, these two bedform types 
may be found together in a host of non-marine as well as 
marine settings, some as different as terrestrial flood plains 
(Stanley, 1968) and deep-water, base-of-slope, and lower rise 
environments (Stanley, 1969). In this respect, it should be 
added that Bailey (1936:1716) had astutely recognized that 
"sometimes there is an admixture of type, even within one and 
the same bed," i.e., graded and current bedding. 
By the early 1950s, workers considered the rippled bedforms 
NUMBER 33 
sometimes associated with graded sequences as being pro?
duced, in some cases, by "dilute turbidity currents, of sufficient 
velocity to move a light bed load by traction" (Natland and 
Kuenen, 1951:106). Moreover, stratification such as foreset 
lamination, usually associated with bottom-current/tractive 
processes, became recognized as an integral part of turbidites 
by Kuenen and his associates (Kuenen and Menard, 1952:83; 
Kuenen, 1953:1051-1053; 1958:1018; Kuenen and Carozzi, 
1953:364; Kuenen and Sanders, 1956:658; Kuenen and 
Humbert, 1969). Subsequently, Bouma (1962:49) described 
the more specific position occupied by current laminated layers 
in turbidite sequences, and Walker (1965:14-18) and others 
interpreted the hydrodynamic origin of this rippling phase as 
a natural part of a gravitative flow event. From about 1950 
until the mid-1960s, the overwhelming majority of studies in 
both the ancient rock and modern-sediment records concluded 
that the emplacement of sandy layers in deep-marine deposits 
was by turbidity currents. 
By 1970, the apparent distinction between laminated and 
rippled deep-sea sediments resulting from turbidity currents 
and those deposited by fluid-driven circulation was no longer 
an obvious one. It became progressively clear that a greater 
diversity of processes could be used to explain the depositional 
sequences found in the modern and ancient deep sea. A 
growing number of gravity-driven flow mechanisms were 
recognized as likely transport agents responsible for the 
downslope-basinward displacement of shallow-marine faunas 
and clastic particles to deeper environments (cf. Middleton and 
Hampton, 1973:3-30). During this same period, empirical 
calculations and theoretical modelling and subsequent verifica?
tion by actual observation and in-situ measurements on the 
scafloor indicated the importance of moderate to powerful 
bottom currents driven by thermohaline circulation of water 
masses. The importance of deep-water masses sweeping 
extensive areas of the ocean floor, including lower bathyal and 
abyssal environments, was initially recognized by, among 
others, Wiist (1958), Ostapoff (1960), and Swallow and 
Worthington (1961). The phenomenon of deep-bottom currents 
flowing long distances over large surfaces of ocean seafloor is 
now generally accepted (Heezen and Hollister, 1971, chap. 9). 
These physical oceanographic investigations coupled with 
the rapidly growing number of marine geological observations 
in the different world oceans have served to confirm the 
important role of deep-sea currents on sediment transport. Of 
particular significance is the potential role of deep currents in 
the reworking of turbidites. In this area of research three 
geological studies, all published in 1964, were particularly 
influential. (1) In modern oceanic environments, Heezen and 
Hollister (1964) recognized the importance of bottom currents 
on deep-sea transport and their role in redeposition. Their 
conclusions were based on bedforms recorded in bottom 
photographs along with physical structures displayed in 
deep-sea cores (actual examples of these were later amply 
illustrated in chapter 9 of the photographic atlas published by 
these authors in 1971). (2) Hubert (1964), who also recognized 
the significance of current bedding, identified textural attri?
butes of deep-sea sands that he felt were indicative of 
reworking of sandy turbidites by bottom currents. (3) Hsu 
(1964) suggested that turbidites, after deposition, can be 
reworked by bottom currents. Citing examples in both the rock 
record and modern oceans, he based his conclusions on 
bedforms and associated primary sedimentary structures and 
textures, along with the presence of mixed shallow-water and 
deep-sea benthic faunas. 
By the mid-1960s the pendulum, at least in the modern 
marine record, was swinging away from turbidite transport 
toward another pole: the concept that sandy deposits at depth 
were laid down by bottom currents. In a short incisive article 
Heezen et al. (1966) developed an extreme view, i.e., that thick 
masses of sediment forming continental rises, such as those 
on western margins of ocean basins, are built up primarily by 
contour-following currents. In the model presented, the 
currents are geostrophically driven and redistribute material 
originally emplaced by turbidity currents. This concept resulted 
in large part from a series of studies made on the Atlantic 
margin off northern North America. Subsequently, physical 
oceanographic and geologic considerations, pointing to the 
influence of large-scale water mass flow over the ocean floor, 
were integrated in a synthesis paper published by Hollister and 
Heezen in 1972. 
It is now generally recognized that transport of sands to 
deep-marine environments is more complicated than proposed 
by either the turbidity-current or the bottom-current schools. 
Hsu (1964:379) had quite reasonably warned that "indiscrimi?
nate assumption of turbidity current deposition of all deep 
marine sandy sediments has led to confusion, inconsistencies 
and controversies." Unfortunately, another conceptual problem 
has evolved: in the majority of recent investigations, sand 
layers that display rippling and associated cross- and foreset-
laminated structures have been related to fluid-driven circula?
tion as the primary transport mechanism. Such rippled and 
cross-bedded sands have been termed "tractionites" by some 
workers (Unrug, 1977:365) and "contourites" by others 
(Hollister and Heezen, 1972:60). The latter term, more 
commonly used, is defined by Lovell and Stow (1981:349) as 
"a bed deposited or significantly reworked by a current that is 
persistent in time and space and flows along slope in relatively 
deep water (certainly below wave base). The water may be 
fresh or salt; the cause of the current is not necessarily critical 
to the application of the term." This interpretation for 
cross-bedded deep-sea sands, if indiscriminately applied, can 
also lead to confusion. 
In the present monograph the use of these genetic terms 
(tractionite, contourite, winnowite) is avoided since the intent 
herein is to minimize confusion introduced by problems of 
semantics, and to clarify interpretations as to sediment 
transport of Cretaceous rocks in St. Croix. A useful approach 
to understand deep-sea sedimentation is one of comparative 
SMITHSONIAN CONTRIBUTIONS TO THE MARINE SCIENCES 
1 MILE 
FIGURE 2.?Simplified geological map of St. Croix (modified after Whetten (1966b; 1974, fig. 1) showing 57 
localities where samples were collected (geographic names of sites in Table 1 (below), and sample numbers in 
Table 2). Photographs of representative outcrop exposures, rock slabs, and thin sections presented in this study 
were selected from 38 localities (circled site number). 
analysis. In this study, the characteristics of deep-sea sands 
emplaced or reworked by fluid-driven mechanisms are 
compared with diagnostic characters of those transported 
primarily by gravity-driven processes (cf. review article by 
Stow and Lovell, 1979). A series of publications have 
attempted to refine ways by which turbidites, which commonly 
display current lamination as an integral part of the accepted 
vertical succession of bedforms, can be distinguished from 
laminated sandy facies emplaced by bottom currents (Walker, 
1965; Kuenen and Humbert, 1968; Unrug, 1977, 1980; Piper, 
1978; Shanmugan and Walker, 1978; Stow and Shanmugan, 
1980; Lovell and Stow, 1981). As it is often difficult to 
differentiate the depositional products from these two different 
transport mechanisms, most emphasis has been placed on 
contrasting, perhaps in an overly simplified or somewhat 
exaggerated manner, the graded turbidite and rippled, tractive, 
end-member facies. 
The problem most likely encountered by geologists trying 
to interpret sandy layers in modern deep-marine environments 
and in the rock record is that some strata are neither of distinct 
turbidite origin nor emplaced entirely by bottom currents. It 
would be useful, therefore, to have available a photographic 
catalog illustrating the suite of sedimentary features displayed 
in these transitional sandy facies. It would also be particularly 
helpful if examples of such intermediate variants were selected 
from deposits where distinct sand turbidites and bottom-current 
NUMBER 33 
EP<19) 
ALLUVIUM AND BEACH DEPOSITS 
VP 
? 
/ / \ KINGSHILL MARL AND JEALOUSY FM. 
f
 ' ' (MIOCENE-OLIGOCENE) 
\ CALEDONIA FM. 
TUFFACEOUS FORMATIONS 
INTRUSIVE IGNEOUS ROCKS 
- (CRETACEOUS) 
sequences occur together. Moreover, it would be more practical 
to consider the problem in the rock record, where strata can 
be traced along the outcrop and where strata are more 
extensively visible in samples recovered from modern oceans. 
In the latter case, observations are usually limited to 
narrow-diameter gravity and piston cores or wider diameter, 
but shallow, box cores. 
In view of the above considerations, this monograph presents 
examples, many at a 1:1 scale, selected primarily from the 
Upper Cretaceous volcaniclastic Caledonia Formation, and 
associated tuffaceous (including Judith Fancy) sequences on 
St. Croix, U.S. Virgin Islands. These various units on St. Croix 
were selected because they comprise both gravity-driven and 
fluid-driven deposits. The rocks display a fairly extensive 
assemblage of sedimentary structures, and serve to highlight 
deep-marine facies that record the effects of more than one 
transport mechanism. 
Methods 
This study involved field work throughout most of St. Croix 
where Cretaceous rocks are exposed (Figure 2). Field work 
was conducted during six surveys: 6 to 15 February 1981; 12 
to 21 January 1982; 9 to 21 March 1983; 2 to 13 February 
1984; 7 to 16 February 1985; and 19 February to 2 March 
1986. Numerous outcrop localities of Late Cretaceous age 
SMITHSONIAN CONTRIBUTIONS TO THE MARINE SCIENCES 
TABLE 1.?Selected geographic sites (letter code) and localities of upper Upper Cretaceous samples (numerical 
code) retained in the Smithsonian NMNH-Sedimenlology collection. Letter and number codes are shown on 
geological map in Figure 2 (pages 4 and 5). 
Letter Code 
BI 
C 
CB 
CD 
EP 
F 
GC 
GP 
HB 
JF 
KP 
LP 
SP 
SR 
TP 
VP 
Number code 
1 
2 
3 
4 
5 
6 
7 
8 
9 
10 
11 
12 
13 
14 
15 
16 
17 
18 
19 
20 
Geographic Name 
Buck Island 
Christiansted 
Canebay 
Creque Dam reservoir 
East End Point 
Frederiksted 
Green Cay 
Grass Point 
Hams Bluff 
Judith Fancy 
Krause Point 
Long Point 
Sandy Point 
Salt River 
Tague Point 
Vagthus Point 
Geographic name 
Buck Island, west sector 
Buck Island, northwest sector 
Buck Island, north-central sector 
Buck Island, northeast sector 
Buck Island, central, near tower 
Vagthus Point 
Manchenil Point 
Lowrys Hill, road cut 
Milord Point 
Hill (512 feet elevation), 1.3 km NNE of Great 
Salt Pond 
Ml. Fancy Point 
Rod Point, west end of Rod Bay 
Grass Point 
Grapetree Point 
Road cut on ridge, above Grapetree Bay 
Hughes Point 
Isaac Point 
Point Cudejarre 
East End Point 
Andrea Point, NW of East End Point 
Number code 
21 
22 
23 
24 
25 
26 
27 
28 
29 
30 
31 
32 
33 
34 
35 
36 
37 
38 
39 
40 
41 
42 
43 
44 
45 
46 
47 
48 
49 
50 
51 
52 
53 
54 
55 
56 
57 
Geographic name 
Lamb Point 
Coltongarden Point 
Knight Point, E of Knight Bay 
Romney Point 
Tague Point 
Marys Fancy Point, Yellowcliff Bay 
Pow Point 
Coakley Bay Point 
Chenay Bay, W of Pull Point 
Punnett Point 
Shoy Point 
Radio Tower, Christiansted 
Mt. Welcome, Christiansted 
Judith Fancy (Watch Ho) 
Salt River, Faile property 
Baron Bluff 
Canebay, east end of North Star Beach 
Scenic Road, 1 km E of Mount Stewart 
Scenic Road, 0.7 km SW of Davis Beach 
Beach, E of Ellen Point 
Ellen Point 
Point, W of Ellen Point 
Annaly Bay 
Cobble beach, W of Annaly Bay 
Adrienne Bay 
Scenic Road, 0.6 km S of Lighthouse 
Trail N off Scenic Road, 0.7 km SE of 
Lighthouse 
Maroon Hole 
Road cut near Lighthouse, E of Coast Guard 
Station 
Hams Bluff 
Scenic Road, 0.4 km N of Caledonia Gut 
quarry 
Caledonia Gut quarry 
Creque Dam ravine, above reservoir 
Road cut between Oxford and Annaly 
St. Croix Stone and Sand quarry, near St. 
George Hill 
Ravine, ]/2 km S of Allandale 
Springfield Crusher quarry, NW of Grove Place 
were examined during these excursions, with a primary focus 
on the sedimentary attributes of the Caledonia Formation in 
both eastern and western St. Croix, and on Buck Island. The 
latter, slightly longer than 1 mile (1.6 km), lies north of the 
eastern sector of St. Croix (Figure 3). 
The Cretaceous exposures on St. Croix occur along the 
eastern and northwestern ends of the Island (Figure 2). 
Numerous sections were examined in the East End Range, a 
hilly (elevation to 866 ft; = 264 m), topographically irregular 
region approximately 10 miles (16 km) long extending 
eastward to East End Point (site 19, Figure 2). Localities also 
were examined in the generally higher Northside Range 
(elevation to over 1100 ft; = 335 m). This latter physiographic 
province forms an east-northeast trending belt, approximately 
10 miles (16 km) long, extending from the west and northwest 
coast of St. Croix (Figure 4) to the north-central coast of the 
island, i.e., to the Estate Judith Fancy (site 34, Figure 2). The 
two Cretaceous highlands are separated by a low, topographi?
cally more gentle area that trends southwest to northeast. This 
mid-island depression is underlain by Miocene to Recent 
carbonates and alluvium. 
The tectonic complexity of the Cretaceous units is recorded 
on the geological map of St. Croix and Buck Island prepared 
by J.T. Whetten in 1961 and subsequently published by the 
NUMBER 33 
? 
FIGURE 3.?Aerial photographs of eastern St. Croix, a, View toward the WNW, showing several study localities: 
east-northeastern coast of Buck Island (4), Point Cudejarre (18), East End Point (19), Andrea Point (20), Lamb 
Point (21), Cottongarden Point (22), Knight Point, east of Knight Bay (23), and Tague Point (25). Localities 
shown in Figure 2. b, View toward West, showing near-vertical tilting of Caledonia Formation strata at East 
End Point (site 19). Photos made from color slides provided by D.K. Hubbard, West Indies Laboratory, St. Croix. 
8 SMITHSONIAN CONTRIBUTIONS TO THE MARINE SCIENCES 
Geological Society of America (1966a). The rocks, for the 
most part intensely folded, are sometimes tilted to the vertical 
(Figure 3) and even overturned. Locally, sections of varying 
thickness have been subjected to further deformation (Figure 
4) and, in addition to faulting, have been displaced as thrusts. 
Moreover, many Cretaceous sections are highly sheared and 
display the effects of low-grade metamorphism. More locally 
the rocks in some sections are also considerably modified 
petrologically by the effects of igneous intrusions. These 
factors, plus the effects of the generally intense and locally 
deep weathering (to depths in excess of 5 m), result in poor 
preservation, thus making it difficult to identify some of the 
primary sedimentary features, particularly in exposures away 
from the coast. 
It became apparent early in the study that Cretaceous 
exposures near the coast and in quarries are the ones most 
useful for thorough sedimentological (including paleocurrent) 
interpretation in the field. The majority of inland outcrop 
localities are less suitable. This is due to extensive structural 
deformation, poor and discontinuous exposure of the Cre?
taceous rock units, intense tropical weathering, and to the 
vegetal cover. The best exposures for the identification of 
sedimentary structures and for recording paleocurrent measure?
ments occur directly at the coast, where rock strata are polished 
or weathered such that lamination surfaces and other bedding 
features become emphasized. Most localities are readily 
accessible, with the exception of the coastal cliff exposures in 
the extreme northwest sector of the island, i.e., from Hams 
Bluff eastward to Annaly, which are best reached by boat 
(Figure 4). There are also several sections within the island 
away from the coast that provide good exposures for 
sedimentological examination. Noteworthy are large quarries 
(sites 52, 55, and 57) and the Caledonia Formation section 
cropping out in the ravine northeast of Creque Dam reservoir 
(site 53), all shown in Figure 2. The latter locality was also 
emphasized in the study by Whetten (1966b). 
Exposures of terrigenous and volcaniclastic sections of the 
Caledonia Formation and of the equivalent and younger 
Cretaceous units (primarily the Judith Fancy and Cane Valley 
formations, cf. stratigraphic section depicted in Whetten, 
1966b, fig. 3) were examined at about 100 sites on St. Croix 
and Buck Island. Black and white and color photos of strata 
were taken at each outcrop locality shown in Figure 2. In 
addition, notations detailing stratification, sedimentary struc?
tures, and metamorphic, volcanic, and structural characteristics 
were made at these localities. Representative rock samples 
were collected at 57 of these sites and their locations are shown 
in Figure 2 (geographic names are listed in Table 1). The 
numerical field-collection code and outcrop locality name of 
all samples in the Smithsonian collection are identified in Table 
2. The field-collection number of the polished hand specimen 
and thin sections actually illustrated in this monograph are 
listed in Table 3. The polished rock slabs and thin sections are 
presently retained at the Sedimentology Laboratory, Depart?
ment of Paleobiology of the Natinal Museum of Natural 
History (NMNH), Smithsonian Institution. 
Mineralogical identifications were made in thin section. In 
the case of heavy minerals where a sufficient number of grains 
had to be concentrated from highly indurated sandstone, 
including quartzite samples, it was necessary to first crush the 
samples and then separate the denser particles in the 62 to 125 
|im fraction by using bromoform. Determination of the 
composition of light and heavy minerals from thin section 
analysis and examination of heavy liquid separations is often 
difficult. Identification is hampered by grain alteration 
resulting from intense weathering or low-grade metamorphism, 
or usually both. Mineral assemblages are often difficult to 
identify because of extensive iron staining and the effects of 
leaching. In several samples the composition of alternating 
light and dark laminae (which highlight the primary sedimen?
tary structures) were analysed by microprobe. This method 
revealed that, with respect to chemical composition, the dark 
laminae are usually iron-enriched in contrast with the 
light-colored laminae. However, the effects of intense weather?
ing and iron staining have substantially modified original grain 
surfaces and altered the original composition, and thus probe 
analysis was only marginally satisfactory for the penological 
analyses. 
The photographs in this monograph illustrate representative 
features observed in the field and in polished rock slabs and 
thin sections. These examples were obtained at 38 of the 57 
sample sites shown in Figure 2. Most of the 335 collected rock 
samples exceed 8 cm in maximum diameter. All have been 
sliced and polished to reveal features that are generally poorly 
(and sometimes not at all) visible at the outcrop. About 85 large 
(to 7 by 10 cm) thin sections on glass were prepared from 
selected samples to enhance features that in many cases 
are only vaguely defined even in the polished sections. 
Photographs of the polished samples and thin sections 
illustrated in this study are reproduced at a 1:1 scale. 
The basal surface of beds is only rarely exposed at most 
localities. Thus, insofar as paleocurrent measurements are 
concerned, only a moderate number could be made using 
base-of-bed or sole structures on sandstone strata, such as 
groove, cut-and-fill, flame, flute, and load markings. More 
commonly, apparent current-direction measurements were 
made using structures within the upper part of sandstone strata, 
such as foreset, cross-laminated, and climbing-ripple lamina?
tions, as well as aligned and imbricated rip-up clasts. Some 
asymmetrically rippled, upper-bedding surfaces were also 
useful for paleocurrent measurements. Directional measure?
ments indicating gravity flow and bottom-current transport are 
listed in Table 2 and separately depicted in Figure 5. 
In view of the intensity of deformation, including overturn?
ing of strata and the possible allochthonous nature and 
rotational displacement of some Cretaceous sequences, caution 
needs to be exercised in the use of these data. Determination 
of very precise transport directions at any one locality remains 
FIGURE 4.?Aerial photographs: a, Northwestern corner of St. Croix (view toward SSW), showing several 
Caledonia Formation study localities: road cut site near lighthouse east of Coast Guard Station (49), Hams Bluff 
(50) and, in distance, upper part of Caledonia Gut quarry (52). Localities shown in Figure 2. Photo was made 
from color slide provided by D.K. Hubbard, West Indies Laboratory, St. Croix, b. View from sea toward steep 
cliffs of Caledonia rocks behind Maroon Hole (48) and lighthouse terrace (arrow) above Hams Bluff. Strata are 
folded, faulted, and intensely sheared. This structural deformation hampers regional stratigraphic correlation and 
sedimentological interpretations. 
10 SMITHSONIAN CONTRIBUTIONS TO THE MARINE SCIENCES 
TABLE 2.?Cretaceous rock samples collected on St. Croix and Buck Island. Measured paleocurrent directions 
at selected localities are also recorded. 
Sample number code 
(year-sample number) 
81-1 to 85-5 
81-EE (9 samples) 
81-6, 81-7 
81-8 
81-9 to 81-12 
81-13 to 81-15 
81-16 to 81-18 
81-19 to 81-21 
81-22 
81-23 
81-24 
82-1 
82-2 to 82-6 
82-7 to 82-9 
82-10 to 82-12 
82-13 to 82-16 
82-17 to 82-21 
82-22 to 82-25 
82-26 to 82-28 
82-29 
82-30, 82-31 
82-32, 82-33 
82-34 to 82-38 
82-39 
82-40 
82-41,82-42 
82-43, 82-44 
83-1 
83-2, 83-3 
83-4 
83-5 to 83-10 
83-11 to 83-18 
83-19 to 83-24 
83-25 to 83-60 
83-61, 83-62 
83-63 to 83-70 
83-71 to 83-75 
83-76 to 83-80 
83-81 
83-82 to 83-88 
84-1 to 84-3 
84-4 
84-5, 84-6 
84-7, 84-8 
84-9 
84-10,84-11 
84-12, 84-13 
84-14 
Geographic 
locality name 
East End Point 
East End Point 
Point Cudejarre 
Grass Point 
Cottongarden Point 
Isaac Point 
Andrea Point 
Lamb Point 
Hughes Point 
Caledonia Gut quarry 
Grapetree Point 
Lowrys Hill 
Hams Bluff 
Rod Point 
Mt. Fancy Point 
Punnett Point 
Creque Dam ravine 
Hams Bluff 
Milord Point 
Shoy Point 
Chenay Bay 
(west of Pull Point) 
Coakley Bay Point 
Knight Point 
Mary's Fancy Point 
(Yellowcliff Bay) 
Pow Point 
Tague Point 
Romney Point 
Salt River, Faile property 
Radio Tower, 
Christiansted 
Mt. Welcome, 
Christiansted 
Pow Point 
Isaac Point 
Springfield Crusher 
quarry 
Hams Bluff 
Baron Bluff 
Judith Fancy Estate 
Buck Island, 
west sector 
St. Croix Stone and Sand 
quarry (St. George Hill) 
Ellen Point 
Beach, E of Ellen Point 
Point Cudejarre 
East End Point 
Isaac Point 
Buck Island, northwest sector 
Buck Island, north-central sector 
Buck Island, northeast sector 
Buck Island, center, near tower 
Road cut near Lighthouse, 
E of Coast Guard Station 
Locality 
code 
(Figure 2) 
19 
19 
18 
13 
22 
17 
20 
21 
16 
52 
14 
8 
50 
12 
11 
30 
53 
50 
9 
31 
29 
28 
23 
26 
27 
25 
24 
35 
32 
33 
27 
17 
57 
50 
36 
34 
1 
55 
41 
40 
18 
19 
17 
2 
3 
4 
5 
49 
Prevailing 
bottom-
current 
direction(s) 
SSE, SE 
ESE, SE, NW 
W.NW 
w, wsw 
w 
WNW, ESE, E 
ESE 
W 
NW 
W, NW 
W.SW 
Prevailing 
gravity-flow 
direction(s) 
NNW-SSE 
NNE-SSW, N-S 
N-S, NNE-SSW 
SSW 
NUMBER 33 11 
TABLE 2.?Continued. 
Sample number code 
(year-sample number) 
84-15 to 84-22 
84-23 to 84-29 
84-30 
84-31 
84-32 
84-33, 84-34 
85-1 
85-2 to 85-7 
85-8 to 85-13 
85-14 
85-15 
85-16, 85-17 
85-18 
85-19 
85-20 
86-1 
86-2 
86-3 
86-4 
86-5 
86-6, 86-7 
86-8 
86-9 to 86-17 
86-18 to 86-20 
86-21 to 86-26 
86-27 to 86-31 
86-32 to 86-47 
Geographic 
locality name 
Hams Bluff 
East End Point 
Road cut near Oxford 
Scenic road, 1 km 
E of Mt. Stewart 
Scenic road, 0.7 km 
SW of Davis Beach 
Trail SE of Lighthouse, 
off Scenic Road 
Point Cudejarre 
Annaly Bay 
Caledonia Gut quarry 
Scenic Road, S of lighthouse 
Scenic Road, N of Caledonia 
Gut quarry 
Cannebay, east end of 
North Star Beach 
Hams Bluff 
East End Point 
Creque Dam ravine, 
above reservoir 
Road cut on ridge, 
above Grapetree Bay 
Maroon Hole 
Adrienne Bay 
Cobble beach, W of Annaly Bay 
Point, W of Ellen Point 
Ravine, V2km S of 
Allandale 
Hughes Point 
St. Croix Stone and Sand quarry 
Hill (512 feet elev.), 1.3 km NNE 
of Great Salt Pond 
Springfield Crusher 
quarry 
Manchenil Point 
Vagthus Point (Watch Ho) 
Locality 
code 
(Figure 2) 
50 
19 
54 
38 
39 
47 
18 
43 
52 
46 
47 
37 
50 
19 
53 
15 
48 
45 
44 
42 
56 
16 
55 
10 
57 
7 
6 
Prevailing 
bottom-
current 
direction (s) 
SE, ESE, NW 
NW 
WNW 
NW, W 
WSW 
NE 
SW 
NW 
W, E(?) 
SW 
NW.SSE 
Prevailing 
gravity-flow 
direction (s) 
SW 
SE 
SE.SSE 
SSE 
questionable, but the number of observations at the different 
sites are believed to be sufficient to delineate the general 
regional dispersal paths. 
Summary Review of the Pre-Tertiary Geology 
of St. Croix 
The island of St. Croix in the northeastern Caribbean is the 
largest of the Virgin Islands. It is located about 100 miles (161 
km) east-southeast of San Juan, Puerto Rico, and approxi?
mately 1000 miles (1610 km) southeast of Key West, Florida 
(Figure 1). This elongate, east-west trending island is 21 miles 
(33.6 km) long, has a maximum width of 6 miles (9.7 km), and 
covers an area of 85 square miles (220 square km). The island 
is positioned on the St. Croix Ridge (Holcombe, 1979), which 
is separated from the Puerto Rico-Virgin Islands Platform to 
the north by an elongate (also east-west oriented), deep (to 
about 5000 m) depression, the Virgin Islands Trough (also 
called Virgin Islands Basin). Geographic considerations, 
including morphology, climate and vegetation, have been 
discussed in publications by Meyerhoff (1927), Cedarstrom 
(1950), and Multer and Gerhard (1974). Geological studies by 
Quin (1907), Kemp (1923), and Cedarstrom (1950) have been 
updated in the detailed investigation published by Whetten in 
1966. The reader is directed to this latter monograph and 
attached map (1966a, scale of 1:31,680) and to subsequent 
abbreviated summaries (Whetten, 1968, 1974) for a thorough 
analysis of the Cretaceous stratigraphy and structure of the 
distinct rock units forming St. Croix, and for interpretations 
12 SMITHSONIAN CONTRIBUTIONS TO THE MARINE SCIENCES 
TABLE 3.?Sample numbers and localities for the polished rock sections and thin sections in the Smithsonian 
NMNH-sedimentology collections that are illustrated in this study. Geographic name of locality where each 
sample was collected is given in Tables 1 and 2. 
Figure number 
la 
lb 
1c 
Id 
10a 
lOfc 
10c,d 
10c 
10/ 
io? 
10A 
10; 
12a 
12b 
Sample 
number 
83-31 
83-45 
83-21 
83-5 
81-14 
85-14 
83-10 
82-3 
82-6 
83-70 
83-24 
81-21 
83-18 
82-8 
Locality 
code (Figure 2) 
50 
50 
57 
27 
17 
46 
27 
50 
50 
34 
57 
14 
17 
12 
12<r 
124 
I2ef 
12* 
15a 
156 
15c 
ISd 
19b 
20a,b 
2\a,b 
21a,b 
23a 
23b 
23c 
23d 
23<? 
2 3 / 
24a 
24b 
24c 
24d 
24c 
26a 
26b 
26c 
26d 
26e 
30a, b 
30c,d 
30e 
30 / 
30# 
31a 
316 
31c 
31d 
3\e 
81-20a 
81-2b 
81-19b 
81-19a 
83-47 
83-26 
83-38 
82-37 
81-EE 
81-EE 
81-EE 
81-EE 
83-25 
84-12 
82-5 
82-36 
81-23 
82-34 
82-23 
83-46 
83-53 
83-54 
83-78 
83-64 
82-28 
82-38 
82-42 
81-23b 
81-9 
82-19 
81-13c 
81-1 
83-14 
83-23 
85-1A 
83-22 
83-19 
83-41 
50 
50 
55 
34 
9 
23 
25 
52 
22 
53 
17 
19 
17 
57 
18 
57 
57 
50 
Figure number 
35a, b 
36a 
36b 
36c 
36d 
36e 
36/ 
37a 
31b 
31c 
31d 
21 
19 
21 
21 
50 
50 
50 
23 
19 
19 
19 
19 
50 
5 
5-0 
23 
52 
23 
50 
50 
42a,b 
42c,d 
42e 
42f 
42g 
43a 
43b 
43c 
43a" 
43e 
43/ 
43g 
46a 
46b 
46c 
46d 
46e 
47a 
41b 
41c 
41d 
41e 
48a,b 
48c 
48d 
48*/ 
49a 
49 b 
49c 
50a 
50b 
50c 
50d 
50e 
50/ 
52a 
52b 
52c 
54a 
54b 
54c 
54d 
Sample 
number 
Locality 
code (Figure 2) 
82-24 
83-73 
85-1 
84-17 
85-11 
82-26 
83-25 
86-40 
86-41 
86-39 
86-36 
81-9 
81-10 
81-20f 
83-59 
84-27 
86-24 
86-14 
86-4c 
86-7 
86-9 
86-26 
86-18 
83-28 
85-12 
81-17 
84-2 
83-51 
84-1 
82-4 
83-50 
84-8 
83-58 
81-21d 
84-22 
85-20 
81-24a 
83-77 
81-22 
84-15 
83-80 
83-40 
81-20b 
83-71 
85-4 
82-21 
82-25 
84-9 
83-35 
86-1 
86-17 
86-28 
86-27 
50 
1 
1-8 
50 
52 
9 
50 
6 
6 
6 
6 
22 
22 
21 
50 
19 
57 
55 
44 
56 
55 
57 
10 
50 
52 
20 
18 
50 
18 
50 
50 
2 
50 
21 
50 
53 
14 
55 
16 
50 
55 
50 
21 
1 
43 
53 
50 
3 
50 
15 
55 
7 
7 
NUMBER 33 13 
TABLE 3.?Continued. 
Figure number 
55b 
56a,b 
56c 
56d,e 
56/ 
57a 
57b 
57c 
57d 
57e 
57/ 
57* 
58a 
58b 
58c 
58d 
Sample 
number 
81-EE 
81-7 
81-6 
81-5a 
81-23a 
85-18 
85-2 
83-49 
81-15 
82-22 
81-23c 
84-3 
83-57 
84-14 
83-76 
83-34 
Locality 
code (Figure 2) 
19 
18 
18 
19 
52 
50 
43 
50 
17 
50 
52 
18 
50 
49 
55 
50 
60a 
60b 
60c 
60d 
61a 
61b 
61c 
61d 
61e 
61/ 
86-10 
86-13 
86-16 
86-5 
83-79 
85-3 
82-5 
82-18 
82-25 
84-6 
55 
55 
55 
42 
55 
43 
50 
53 
50 
17 
of their mineralogy, petrology, and paleontology. 
It is now recognized that St. Croix, Buck Island (positioned 
1.5 miles, or 2.4 km, north of its eastern margin), and the 
submerged contiguous platform, are underlain largely by rock 
sequences of Upper Cretaceous age. A Late (perhaps latest) 
Cretaceous age for these rocks is indicated by the fossils 
(including rudists, corals, foraminifera) of Campanian and 
Maestrichtian age recovered at several sites (Whetten, 1966b; 
Speed et al., 1979; Kaufman and Sohl, 1974; and N.F. Sohl, 
U.S. Geological Survey, 1986, pers. comm.). Cretaceous 
sequences are locally covered by younger deposits: largely 
limestones of Miocene and Pliocene age, Quaternary alluvium 
and beach rock, and offshore reefs. Miocene and younger 
sediments are exposed primarily in the structurally depressed, 
somewhat lower-lying Central Valley, which extends from the 
western part of the island in a north-eastward direction toward 
Christiansted (Curth et al., 1974; Gerhard et al., 1978). This 
tectonic low is filled in part by the Kingshill Formation of 
Miocene age (Figure 2); the depression defines a paleogeogra?
phic province termed the Kingshill depositional plain (Gerhard 
et al., 1978) or the Kingshill Seaway by Multer et al. (1977) 
and Lidz (1982). 
The focus in the present study is on the Upper Cretaceous 
marine sedimentary and volcanogenic rocks, and primarily the 
Caledonia Formation. This latter is assigned, at least in part, a 
Campanian age (Whetten, 1966b, fig. 3; 1974, fig. 2), although 
it may be somewhat younger. Where the strata are well 
exposed, this formation appears flysch-like (Figure 6a). Fresh 
surfaces display bluish gray to black mudstones (clayey silts 
usually altered to slates) that alternate with lighter colored 
sandstone (generally indurated to quartzite) and conglomerate 
strata (Figure 6b). An island-wide survey shows that the 
thickness of these Caledonia strata is highly variable, with 
layers ranging from a few millimeters to several meters, and 
most commonly 1 to 10 centimeters thick. Fine-grained 
argillite and slate deposits (originally mud, or mixtures of silt 
and clay, prior to lithification) comprise more than two-thirds 
of the formation thickness, while sandstone (fine- to coarse-
grade sand) layers account for, at most, about 25 percent. Strata 
with larger debris of granule to cobble size (diameter rarely in 
excess of 20 cm) form less than 5 percent of the formation 
thickness. The sand-shale ratio ranges from 1:10 to as high as 
1:1. Prior to compaction and lithification, however, the ratio 
of sand to mud thickness was usually little more than about 
1:10. 
Although there were no volcanoes on the seafloor at the site 
presently occupied by St. Croix, the Cretaceous rocks are, for 
the most part, volcanogenic. The dominant components of 
these rocks are of volcanic origin, including epiclastic 
fragments of keratophyres and spillites, and mineral grains 
derived from volcanic rocks, with only rare fossil debris. The 
latter usually occur as fragments embedded within coarse-grade 
fractions and, in the case of microfossils, as shells, usually 
poorly preserved and often recrystallized, in the fine-grained 
layers. Whetten (1966b: 186) interpreted the Caledonia Forma?
tion as a sequence formed largely of epiclastic volcanic 
sedimentary rocks, i.e., deposits consisting of material eroded 
primarily from pre-existing rocks in a volcanic terrain. 
Interbedded within and at the upper part of the Caledonia 
Formation are mappable units of tuffaceous sedimentary rocks. 
The tuffaceous series within the Caledonia Formation (such 
as the East End Member) and the associated Upper Cretaceous 
Allandale, Cane Valley, and Judith Fancy Formations, are 
variable in lithology. They usually comprise "pyroclastic 
debris of primary eruptive origin as well as volcanic ash and 
fragments transported by streams and/or reworked by marine 
currents, in many cases mixed with minor amounts of epiclastic 
volcanic materials" (Whetten, 1966b: 186). At exposures where 
they are not intensely weathered the tuffaceous formations 
sometimes appear greenish (apple green) in color. Associated 
with tuffaceous formations are lava flows, silicified siltstones 
and, very locally, limestone strata (most notably at Vagthus 
Point, locality VP in Figure 2). Altfiough well indicated on 
Whetten's geological map of St. Croix (1966a), it should be 
noted that the stratigraphic relationship between these tuf?
faceous rock units and the Caledonia Formation is often poorly 
defined in the field. The structural-stratigraphic relationship 
between formations and members is a complicated one and 
outside the scope of this investigation. 
14 SMITHSONIAN CONTRIBUTIONS TO THE MARINE SCIENCES 
Prevailing Bottom Current 
* ? Prevailing Gravity Flow 
Cretaceous and intrusive 
igneous rocks 
fe^3 Miocene and younger deposits 
FIGURE 5.?Paleocurrent measurements at 17 selected sites of Cretaceous sequences (primarily Caledonia and 
Judith Fancy formations) in St. Croix and on Buck Island. At some localities die predominant directions based 
on structures typical of tractive-current transport diverge markedly from directions measured on structures in 
sediment gravity-flow deposits. Exposures of Cretaceous rocks shown in white; Tertiary and Quaternary deposits 
crop out in stippled area (simplified from geological map in Figure 2). Abbreviations: C = Christiansted, F = 
Frederiksted. 
The various above-cited lithofacies on St. Croix are not 
strictly equivalent with respect to age of emplacement, to 
petrology, or to depositional environment. It is emphasized 
here that, in the present study, sections and samples from the 
Caledonia Formation and from the tuffaceous series (primarily 
the Judith Fancy Formation) are selected primarily as 
examples to illustrate concepts pertaining to sediment trans?
port in general. The intent is not to formulate a precise 
paleobasin reconstruction, because it is recognized that the 
different Cretaceous formations are not strictly co-eval. In 
particular, isotopic dating would be required in conjunction 
with field work and drilling on and around St. Croix to obtain 
a more precise stratigraphic definition of the various Cre?
taceous units forming the island. 
The oldest strata of the Caledonia Formation are believed 
to crop out on Buck Island (Whetten, 1974:135). Thicknesses 
of the tuffaceous series and of the Caledonia Formation have 
been estimated at about 6000 m and 3000 m, respectively. 
Structural analysis in eastern St. Croix, however, suggests that 
estimated thicknesses of the Caledonia are probably excessive, 
since they are based in part on the assumption of a continuous 
homoclinal structure between Buck Island and East End Point 
(Figure 3). On the basis of the structural complexity recorded 
on St. Croix proper (tight folds, faults, thrusts), a stratigraphic 
continuity of this type can reasonably be questioned. 
Tectonic complexities have been recorded wherever Cre?
taceous rocks crop out and these are depicted on the geological 
map prepared by Whetten (1966). More detailed geometric 
analyses of local deformation structures in St. Croix have been 
presented by Speed (1974) and Speed et al. (1979). The 
structure of specific areas including Grass Point, Isaac Point, 
and Green Cay (localities GP, 17, and GC in Figure 2) has 
been recognized, respectively, by Cohen et al. (1974), 
Loftsgaarden et al. (1974), and Ratte (1974). In addition to 
intense shearing and cleavage, folding and faulting, my surveys 
suggest that allochthonous displacement, including thrusts, in 
both eastern and western parts of the island is probably even 
more important than indicated in these earlier studies. 
Focusing on the eastern part of St. Croix, Speed (1974) and 
Speed et al. (1979) indicate that structural deformation and 
volcanism occurred during, or shortly after, deposition of the 
sediments in the Late Cretaceous. The deformation, as 
exemplified by the rocks in the eastern part of the island, is the 
probable result of strong impulsive, but short-lived, activity 
that affected the whole of the Greater Antilles (Speed et al., 
1979). This is recorded at the outcrop by syndepositional 
modification, including the almost ubiquitous, deformed, 
sedimentary structures, several examples of which are illus?
trated in later sections of this monograph. 
Attention has been called to the small bodies of igneous 
rocks that intruded the Cretaceous rocks. Some of these 
intrusions, mapped by Whetten (1966a), are shown in Figure 
2. Sedimentary rocks adjacent to such igneous bodies are 
usually intensely modified, and the sedimentary and other 
primary structures appear indistinct at the outcrop or are 
obliterated. According to Speed et al. (1979, table 1) such dikes 
NUMBER 33 15 
FIGURE 6.?Photographs at Springfield Crusher quarry (site 57, Figure 2). a, Steeply dipping flysch-like 
Caledonia series of alternating quartzite and slate strata; section shown is about 70 m thick, b, Fresh quarry 
surface, exposing unweathered lower part of thick (about 1 m) sandstone turbidite; note sharp contact (single 
upper arrow) between turbidite base and underlying fine-grained (slate) deposit. Two elongate imbricated rip-up 
mud clasts (lower two arrows) in an underlying sandstone layer indicate transport from right to left; hammer 
(28 cm long) provides scale. 
and at least one pluton were emplaced between 74 and 64 
million years ago, quite probably the product of regionally 
intense plutonism during the Maestrichtian. 
A recent review article on the regional geological evolution 
of the Caribbean by Case et al. (1984) alludes in a general way 
to the Mesozoic and Tertiary history of the Virgin Islands and 
Puerto Rico relative to that of other islands in the region. That 
study and those by Pindell and Dewey (1982), Burke et al. 
(1984, fig. 48), and Mattson (1984, figs. 4 and 5) indicate that 
the Caribbean ocean floor shifted to the northeast, and then to 
the east, between Mexico and South America, during the Late 
Cretaceous. In recent years authors have invoked motion along 
major transform structures (Vila et al., 1986) and active 
underthrusting of the Caribbean plate beneath South America 
during this period. The specific mechanisms that led to this 
structural evolution and resulted in the present island-arc 
configuration are still under discussion. It is quite clear, 
however, that the rocks of Late Cretaceous to Eocene age 
exposed on islands in this part of the Caribbean record the 
effects of particularly intense tectonic deformation and 
volcanism that molded the region. 
Sedimentary Evidence for Downslope Transport 
BASE-OF-SLOPE DEPOSITIONAL SETTINGS.?Field observa?
tions made during the course of this study substantiate the 
16 SMITHSONIAN CONTRIBUTIONS TO THE MARINE SCIENCES 
conclusion that the volcaniclastic deposits forming the 
Cretaceous rocks on St. Croix were transported on slopes, 
probably in an active tectonic arc setting (Whetten, 1966b, 
1974). Perhaps these slopes were the margins bounding an 
island-arc front basin or trench, or alternatively, constituted 
base-of-slope settings between the arc and back-arc basin, as 
suggested by Speed (1974). The present petrologic study 
indicates that these gradients, in either case, were in proximity 
to zones of active volcanic activity, both intrusive and 
extrusive. Not only was sediment accumulation penecontempo-
raneous with volcanism, but the layered deposits were 
structurally deformed (Figure 4) during and shortly after their 
accumulation. 
It would appear that both the Caledonia volcaniclastics and 
the somewhat younger tuffaceous deposits (Judith Fancy and 
other) were transported on slopes. A base-of-slope setting is 
interpreted on the basis of the assemblages of gravity-driven 
mass flow sediments types, the most significant including 
slides, slumps, and coarse-grained, sediment gravity-flow 
deposits (definitions in Middleton and Hampton, 1973:1-31). 
These latter include debris-flow and sand-flow (including 
grain-flow) units (cf. Stanley et al., 1978:106-109), as well as 
coarse-grained turbidites. Although very important for inter?
preting environments, the above-cited sediment types, together, 
account for less than 10% of the total thickness of the 
Cretaceous section. It is difficult to quantify slope gradient, 
but the transport for any distance of the deposits cited above 
(particularly the non-graded or poorly graded sand flow/grain 
flow deposits, Figure 7) may require slopes of at least 5 
degrees. This is a conservative estimate and, locally, steeper 
gradients are suggested. Examples of high-gradient settings 
include the walls of slope channels (to >10?), the configuration 
of which are recognized on the basis of the geometry of strata 
sequences. 
A distal setting has been suggested for the Cretaceous 
deposits on St. Croix by earlier workers: i.e., environments 
beyond the toe of a subsea fan (Speed, 1974:193), or somewhat 
more distal environments on the margins of a basin (Speed et 
al., 1979:631). In my view, the distinctive association of 
mass-flow deposits cited in this text indicates a more proximal 
setting, more likely a slope apron rather than a fan lobe. 
SLIDES, SLUMPS, AND DEBRIS-FLOW DEPOSITS.?A significant 
component of the downslope-directed mass flows consists of 
gravity slides, where large slabs of strata have moved with 
only slight internal deformation as the allochthonous masses 
moved basinward on one, or a few, well-defined slippage 
planes. Identification of slides is most reliable in outcrop 
sections that are sufficiently large and well-exposed, and where 
stratification surfaces can be traced laterally. Several examples 
can be observed (e.g., Caledonia Gut quarry; site 52, Figure 
2). In contrast with slides, slumps involve displaced packets 
of strata that reveal extensive internal deformation. The term 
is also applied loosely herein to a large sediment mass, usually 
sandstone or mudstone or both, that has become detached as 
an allochthonous packet during transport, and is incorporated 
on or within another layer. Slumps are usually of geometrically 
smaller scale than slides and thus are more readily identified 
at the outcrop. Well-exposed examples of slumps include those 
of the Judith Fancy Formation at the Estate Judith Fancy 
locality and illustrated by Whetten (1966b, pi. 6). 
Some conglomerates found in the different Cretaceous 
sequences are identified as subaqueous debris-flow deposits. 
This interpretation is made in those cases where it is surmized 
that large clasts are displaced by processes involving 
matrix-support. In this transport mode, the larger particles are 
borne by moderately concentrated to dense mixtures of sand, 
mud, and water (cf. Hampton, 1972; Middleton and Hampton, 
1973, fig. 10). Various types of conglomerate-rich debris-flow 
deposits, or "debrites," occur in both the eastern and western 
sectors of St. Croix and on Buck Island, where matrix-
supported (Figure 8), partially grain-supported (Figure 9a), and 
grain-supported (Figure 9b) types are recognized. The clasts, 
"floating" in matrix of sand or mud or mixture of both, 
commonly include a diverse polygenic mix (Figure 10) of 
epiclastic fragments of keratophyres and spillites, quartz, and 
other lithologies identified by Whetten (1966b). At several 
localities, conglomerates consist essentially of angular and 
subangular debris of fairly homogenous igneous lithology. 
Although transport-wise, these are sedimentary in origin, they 
resemble deposits of volcanic flow (lahar) units (Figure 11a). 
The larger grains are usually embedded in a volcaniclastic 
matrix (Figure 12a). In the case of finer-grained debris flows, 
a diversity of grain sizes, mineral types, and fabric structures 
are identified in thin section (Figures 10/, \2b,df,g). Pebbles 
in "debrites" may display a coherently organized configuration, 
and examples include graded (Figures 13, 146) and stratified 
(Figure 11a) layers. In more than two-thirds of the observed 
cases, however, particles are dispersed randomly and appear 
as disorganized masses (Figure 9a). 
Clasts with a diameter larger than 100 centimeters have been 
measured, but in most conglomerates the clast diameter is 
usually less than 10 centimeters. Gravity emplaced deposits, 
where coarse sand- and granule-size particles are embedded 
in a matrix of fine-grained sand and finer material (Figures 10, 
\2c-g), are not uncommon. In shape, lithic clasts range from 
angular (some in Figure lOc-e) to well rounded (Figure 8a), 
but most are subangular to subrounded (Figures 9a, 10a). 
Rip-up clasts of sandstone (quartzite) and mudstone (slate) are 
most commonly observed in sandstone and conglomerate 
layers (Figures 6b, 9c, lOe, 13, \5a,c,d), and occasionally in 
siltstone (Figure 15b) and mudstone. In some layers elongate 
particles (lithic fragments and also rip-up clasts) are preferen?
tially oriented with respect to transport direction, i.e., the long 
axis of elongate clasts may be parallel (Figure lib) or 
perpendicular (Figure 13) to flow path. Flattened elongate 
clasts are commonly imbricated (Figures 6b, 13, 15a, 16), and 
thus serve as paleocurrent indicators. 
NUMBER 33 17 
FIGURE 7.? Polished sections of almost structureless, sandy, volcaniclastic layers with sharp top and sharp base. 
These are interpreted as sand-flow (grain- or fluidized-flow) deposits. Lower sandstone layer in a, subtfy graded, 
is similar to basal division A of turbidites. Localities (in Figure 2): a,b = site 50; c = site 57; d = site 27. Scale 
bar applies to all components. 
SHALLOW-WATER COMPONENTS IN SOME MASS-FLOW 
DEPOSITS.?Of particular interest with respect to possible 
environmental setting is the well-exposed section of mass-flow 
deposits (Judith Fancy Formation) at Vagthus Point (also called 
Watch Ho; site 6, Figure 2) on the southern coast of St. Croix. 
This locality, mapped as one of the youngest Cretaceous 
sections on the island (cf. Whetten, 1966b, pi. 7), includes a 
series of carbonate-rich strata tilted to the near-vertical (Figure 
14a). The sequence includes numerous thin (1-10 cm), 
fine-grained, tuffaceous, mudstone and limestone layers (some 
graded) alternating with thicker (1.0-1.5 m) and much coarser 
debris-flow deposits; the latter usually comprise large clasts 
(diameter exceeding 20 cm). Some of the coarse layers display 
graded bedding (Figures 13, lAb). These latter are formed of 
18 SMITHSONIAN CONTRIBUTIONS TO THE MARINE SCIENCES 
FIGURE 8 -Matrix -supported debris-flow deposits with rounded pebbles in sandstone (a) and muddy sandstone 
(b). Localities (in Figure 2): a = site 7; b = site 48. Hammer is 28 cm long. 
NUMBER 33 19 
MMP?sBsgH 
FIGURE 9.?Examples of "disorganized," sandy, debris-flow deposits, a, Subrounded volcanogenic clasts, 
partially matrix-supported; b, Clasts, in large part grain-supported; c, Siltstone rip-up clasts of various shape 
concentrated in coarse sandstone. Localities (in Figure 2): a = site 7;b,c = site 50. Hammer is 28 cm long. 
20 SMITHSONIAN CONTRIBUTIONS TO THE MARINE SCIENCES 
' ? ? ? ' ' ? ? 
?'.:^ '' , 
*?-
' * ? ? * - \ ? 
? -J fey* ' * > 
- ' ? \ - ? 
FIGURE 10.?Hand specimen (c), polished sections (a,b,d-h) and thin section (i) of different debris flow deposits 
(mostly volcaniclastics) showing diverse examples of clast size and shape and clast-to-matrix fabric. For 
example, some clasts tend to be angular in c, d, and e and subangular to subrounded in af, and g. Clasts appear 
to "float" in muddy sand matrix in b; in contrast, clasts are in contact with each other in/. Localities (in Figure 
2): a = site 17; b = site 46; c,d (respectively, hand and polished section of same sample) = site 27; ef= site 50; 
g = site 34; h = site 57; i = site 14. Scale bar applies to all components. 
NUMBER 33 21 
2WS 
FIGURE 11.?a, Stratified volcaniclastic conglomerate wiuh subrounded to angular clasts, probably submarine 
lahar-type flow deposit; hammer is 28 cm long, b. Base of bed showing alinement of elongate pebbles, with 
long axis oriented roughly parallel to flow direction (double headed arrow); direction of transport current not 
defined by pebbles, but by other sedimentary structures such as foreset lamination within bed; book on right is 
13 cm wide. Localities (in Figure 2): a = site 17; b = east of site 1. 
detrital limestone and volcaniclastic clasts and a sandy to 
muddy carbonate matrix, and incorporate complete but worn 
(Figure 17) or broken rudists and coral fragments (identifica?
tion in Whetten, 1966b:209-210; Sohl, 1976:31.4). The 
imbricated orientation of some elongate clasts and the 
horizontal (flat-lying) position of rounded rudists (such as 
Barrettia gigas; Norman Sohl, 1986, pers. comm.) at the base 
of some coarse layers (Figure 13) suggest emplacement by 
high-energy, downslope-directed flows, with probable trans?
port of larger fragments by rolling along the bottom. 
The assemblage of detrital biogenic material of neritic or 
shallower origin, mixed with terrigenous particles in the 
coarser beds at Vagthus Point, strongly suggests a process 
involving offshelf spill-over, i.e., transport of biogenic-rich 
debris from a largely carbonate bank onto a fairly steep slope. 
The rather consistent thickness of strata, the moderate to 
well-developed graded bedding, and the preferential orientation 
and imbrication of clasts at this locality suggest that transport 
(a) involved downslope-directed, sediment gravity-flow me?
chanisms and (b) that these flows entrained sediment 
downslope for a sufficient distance to result in a coherent 
organization of particles during deposition and the "freezing" 
of sediment as laterally continuous and well-stratified strata. 
The Vagthus Point sequence resembles the sequences of mixed, 
coarse, carbonate debris and finer-layered, calcareous muds 
on the present-day lower slope off northern St. Croix. These 
deposits, as observed from the submersible DSRV ALVIN, 
were derived from the narrow platform and upper slope in 
22 SMITHSONIAN CONTRIBUTIONS TO THE MARINE SCIENCES 
1 cm 
FIGURE 12.?Polished slab (a,de) and thin sections (b,cf,g) of various submarine volcaniclastic flows. Hand 
specimen (a) was collected at the exposure shown in Figure 1 la. Samples show disorganized (b), to partially 
organized (c), to organized (graded bedding in d) nature. Localities (in FIGURE 2): a = site 17; b = site 12; c = 
site 21; d = site 19; e-g = site 21. Scale bar applies to all components. 
geologically recent (Quaternary) time (Hubbard et al., 1982). 
SEDIMENT FAILURE AND DEFORMED STRUCTURES IN SLOPE 
DEPOSITS.?Further evidence, albeit indirect, of transport 
processes likely to occur on slopes is recorded by deformed 
sedimentary structures such as convoluted laminations so 
commonly mapped in sediment gravity flow deposits at many 
localities. These convolutions suggest that metastable-
collapsible phenomena related to failure occurred during, or 
shortly after, deposition. Moreover, the structures indicate 
disruption of the original grain-to-grain fabric, some associated 
with spontaneous liquefaction and dewatering phenomena. 
Deformation may be restricted to a localized part of a single 
layer (Figure 186), or may affect the entire stratum (Figures 
19-22). Sometimes several layers are deformed in a parallel 
manner (Figure 18a) or a set of laminae show evidence of 
syndepositional disruption (Figure 23b). The disruption of 
grain-to-grain contact, as indicated by the destruction of the 
overall sediment structure and fabric and the expulsion of water 
NUMBER 33 23 
v 
V 
^ 
?v 
? i 
t 
3 j ' A 1 
FIGURE 13?Coarse, thick (about 1 m) graded, matrix-supported conglomerate with imbricated pebbles (dashed 
lines along major axes; several below arrow and left of hammer handle) showing transport from right to left. 
Light-colored fragment at right base of hammer (28 cm long) is a worn rudist; long axis is horizontal and oriented 
perpendicularly to imbricated pebbles. Smaller dark pebbles are rip-up clasts of siltstone. Locality is Vagthus 
Point (Judith Fancy Formation, site 6, Figure 2). 
24 SMITHSONIAN CONTRIBUTIONS TO THE MARINE SCIENCES 
FIGURE 14.?Strata at Vagthus Point (Judith Fancy Formation, site 6, Figure 2), tilted to vertical, a. Sequence 
of thin, coarse, sand- and granule-rich turbidites alternating with thicker (1-2 m) and much coarser debris-flow 
deposits. Strata comprised of limestone and volcaniclastic components. Arrow shows top of "debrite" toward 
left, b, Close-up photograph of coarse graded stratum; fining upward shown by arrow. Layer contains numerous 
carbonate, including fossil, fragments. Note erosional pebble-rich base cut into underlying sandstone layer. 
Hammer is 28 cm long. 
NUMBER 33 25 
FIGURE 15.?Polished sections showing dark, mudstone rip-up clasts in medium- and fine-grained sandstone 
(a,b), and in coarse-grained sandstone (c,d). Angular fragments may be irregularly distributed (c,d) or 
concentrated along specific parts of layers (a,b). Elongate clasts sometimes imbricated (transport toward left in 
a). Localities (in Figure 2): a-c = site 50; d = site 23. Scale bar applies to all components. 
FIGURE 16.?Imbricated rip-up clasts of sandstone (a) and mudstone (b) in sandy strata: transport of large 
elongate clasts toward right (arrows) in both examples. Localities (in Figure 2): a = site 7; b = site 42. Hammer 
is 28 cm long. 
NUMBER 33 27 
FIGURE 17.?Worn rudists (Barrettia gigas) embedded in coarse carbonate and fossil-bearing debris-flow 
deposits at Vagthus Point (Judith Fancy Formation, site 6, Figure 2; photo of exposure in Figure 14a). Long 
axis of specimens is flat-lying, not vertical as in their living position; such large fossils usually occur near base 
of beds. Hammer is 28 cm long. 
28 SMITHSONIAN CONTRIBUTIONS TO THE MARINE SCIENCES 
FIGURE 18.?Examples of syndepositional deformation structures, a, Crinkling of several sandstone layers 
(arrow) between undeformed strata (hammer is 28 cm long), b, Convolution (arrow) within one layer (15 cm 
thick) between several undeformed sandstone strata. Localities (in Figure 2): a = site 50, b = site 4. 
NUMBER 33 29 
/ 
-
? ? . ? ? ? ? 
FIGURE 19.?a. Single highly deformed layer (arrow) of fine- to medium-grained sandstone of fairly constant 
thickness (7-9 cm thick); it crops out between undeformed strata at East End Point (site 19, Figure 2). b, Base 
and top of stratum are near-parallel, while laminations within most of bed have been tightly folded into 
convolutions along its entirety. Other examples of convolutions along this same bed shown in Figures 20 to 22. 
1 cm 
30 SMITHSONIAN CONTRIBUTIONS TO THE MARINE SCIENCES 
I i 
1 cm 
FIGURE 20.?Hand specimen showing syndepositional deformation structures (very tight convolutions) within 
sharp-based and -topped sandstone bed (see Figure 19a) at East End Point (site 19, Figure 2). a, Weathered 
surface; b, Polished section. Scale bar applies to all components. 
NUMBER 33 31 
I 
1 cm 
FIGURE 21.?Hand specimen showing syndepositional deformation (convolution/probable dewatering) structure 
within sharp-based and -topped sandstone bed (see Figure 19a) at East End Point (site 19, Figure 2). a, Weadiered 
surface; b, polished section. Scale bar applies to all components. 
from unconsolidated strata, may result from several types of 
events. These can include (a) sudden burial by a rapid 
succession of depositional events (sometimes denoted by 
deformed sole markings and load structures) and (b) earthquake 
motion as recorded by some beds that show intensely 
convoluted laminations in a fairly constant and continuous 
fashion over wide areas). 
The structures of the type cited above, occurring in both the 
Caledonia (Figure 23) and the Judith Fancy formations, are 
not only frequently observed but also quite diverse in 
configuration. Syndepositional deformation usually affects 
only a part of a sandy stratum. Examples include structures 
primarily at the upper parts of beds (Figure 24d,e), those within 
the middle and upper part of beds (Figures 24a-c), and those 
at the base of beds (Figure 25). Some deformation features also 
may be post-depositional in origin, i.e., structures formed as 
the still-unconsolidated strata were compressed, tilted, and 
displaced during, and following, Late Cretaceous time. 
Structures that are truly syndepositional, as well as those 
formed subsequent to lithification (e.g., post-depositional 
shear/low-grade metamorphic structures; Figures 23ef, 26b,d,e), 
prevail at many localities; some are difficult to distinguish. 
PALEOCURRENT ANALYSIS.?The tectonic complexity and 
structural deformation affecting the Cretaceous sequences in 
St. Croix have been alluded to in an earlier section. There is, 
therefore, a question of reliability of paleocurrent-paleoslope 
and provenance/dispersal interpretations as determined from 
the directions of measured primary sedimentary structures. 
On the basis of groove markings and other sedimentary features 
mapped in the Caledonia, Judith Fancy, and other tuffaceous 
rocks, it would appear that gravity transport occurred along 
general north-south trends (compass orientations ranging from 
NE-SW to SW-NE quadrants). This is in general agreement 
with earlier conclusions presented by Whetten (1966b, fig. 
18). At sites such as at Manchenil Point and Vagthus Point 
(sites 7 and 6, Figure 2), the apparent downslope-transport 
directions are oriented toward the south, south-southeast, and 
south-southwest quadrants (Figure 5). A determination of 
south-dipping trend of slopes with sediment dispersal from a 
northern source, as based on sedimentary structures and 
mineralogical composition, would assume minimal, post-
depositional, lateral translation or rotation of Cretaceous rock 
units. Surface mapping coupled with subsurface exploration 
of the island are needed to confirm these hypotheses. 
Whatever the exact direction of transport, the association of 
slides, slumps, sand flows, and coarse-grained turbidites in the 
Cretaceous Caledonia and Judith Fancy formations implies 
that sediment transport occurred on slopes. To accommodate 
32 SMITHSONIAN CONTRIBUTIONS TO THE MARINE SCIENCES 
1 cm 
FIGURE 22.?Hand specimen showing syndepositional deformation structures (including very tight convolution 
and possible dcwatering features) within sharp-based and -topped sandstone bed (see Figure 19a) at East End 
Point (site 19, Figure 2). a, Weathered surface; b, polished section. Scale bar applies to all components. 
NUMBER 33 33 
TOBHMHMp 
FIGURE 23. Polished sections showing various types of syndepositional structures (including convolutions) in 
Caledonia Formation. Examples include those restricted to part of bed (a), or affecting entire layer (c, lower in 
d) or affecting set of laminae (bf). Some structures may have a post-depositional component (possibly e). 
Localities (in Figure 2): a,c = site 50; b = site 5; df= site 23; e = site 52. Scale bar applies to all components. 
34 SMITHSONIAN CONTRIBUTIONS TO THE MARINE SCIENCES 
FIGURE 24.?Polished sections showing syndepositional structures (including convolutions) affecting mid- and 
upper parts (a-c), and top (d,e) of sandy beds, while lower parts of strata appear little or not disturbed. Sandstones 
in d and e are graded. Localities (in Figure 2): a-d = site 50; e = site 55. Scale bar applies to all components. 
NUMBER 33 35 
FIGURE 25.?Photographs at outcrop, (a) Load structures (arrows) and (b) load/flame structures (arrows) in lower 
parts of sandstone turbidites. Localities (in Figure 2): a = site 12; b = site 53. Hammer is 28 cm long. 
36 SMITHSONIAN CONTRIBUTIONS TO THE MARINE SCIENCES 
FIGURE 26.?Polished sections showing deformed structures, some (b,d,e) which probably have post-depositional 
component. Note offset of laminae in d. Petrographic analyses indicate recrystallization veins, and mineralogical 
alterations associated with low-grade metamorphism. Localities (in Figure 2): a = site 34; b = site 9; c = site 
23; d = site 25; e ? site 52. Scale bar applies to all components. 
this assemblage of mass-flow deposits, most slopes were 
relatively steep, approximated 5?. Some slopes, locally, were 
probably steeper, i.e., to 10? or more. Moreover, the 
volcaniclastic sediments accumulated in proximal (base-of-
slope), rather than distal, settings. 
TURBIDITE SEDIMENTATION: THE PRELIMINARY 
TRANSPORT MODE 
CHARACTERISTICS OF TURBIDITES ON ST. CRODC.?The gravity-
driven deposits cited in the previous section (slides, slumps, 
NUMBER 33 37 
FIGURE 27.?Turbidites in ravine above Creque Dam reservoir (site 53, Figure 2). a, Granule and coarse sandstone 
massive lower division A of thick turbidite; note erosional base (arrow), b, Thin but complete (A-E) coarse 
sandstone to siltstone turbidites. Hammer is 28 cm long. 
"debrites," sand-flow deposits, and very coarse turbidites), 
recognized as a slope assemblage, constitute only a small 
portion of the Cretaceous sequences on St. Croix. Most sections 
examined are formed largely of thin (rarely in excess of 50 
cm, and usually <10 cm), medium-grained, volcaniclastic, 
sandstone layers (indurated to quartzite) that alternate with 
mudstone strata (silt and clay admixtures usually indurated to 
slate). Although outcrops of the Caledonia and Judith Fancy 
formations are flysch-like in general appearance (Figures 6a, 
14a), it is of note that the majority of localities include only a 
low proportion (usually <20%) of continuous, even-bedded, 
sandstone strata that, on close scrutiny, would be identified 
with certainty as turbidites. 
The term "turbidite," as used herein with reference to sandy 
layers, is restricted to a stratum that displays an established 
vertical sequence (partial or complete) of bedform intervals as 
reviewed in the following paragraph, plus at least a minimal 
amount of textural upward-fining (graded bedding). There is 
usually a sharp basal contact with the underlying mudstone 
(Figures 6b, 21a) and a less well-defined (sometimes quite 
subtle) upper bed contact with the overlying mudstone layer 
(Figures 276-31). Graded bedding is of the type where fine 
grains are present as matrix throughout; the proportion of 
coarser grains, however, gradually decreases upward (Figures 
30a-d, 3lb). Climbing ripples (Figure 23b), sole markings 
(Figures 3 Id, 33-35), convolute laminations (Figure 23), and 
rip-up clasts (Figures 6b, 29a) are additional attributes, but not 
always present. 
In thin section (Figures 35b, 36c) laminae usually appear 
highlighted by darker finer-grained (clay/silt) layers rather than 
38 SMITHSONIAN CONTRIBUTIONS TO THE MARINE SCIENCES 
FIGURE 28.?Sections of superposed A-B and B-C turbidites. a, Lower turbidite division is massive graded 
(A), b, Lower division is plane laminated (B). Localities (in Figure 2): a = site 23; b = site 43. Hammer is 
28 cm long. 
by concentrations of heavy minerals. Sorting is moderate to 
poor. Granule- and sand-sized grains are usually in contact 
(Figure 30) but, in some instances, may also be separated by 
matrix (fine-grained material of silt and clay size, Figure 
31b,c). No conclusive observations are made with reference 
to sand-size grain orientation. Larger, elongate particles, 
however, are sometimes imbricated (Figure 31c,d). The above 
observations that pertain to the texture, fabric, and matrix of 
these Cretaceous turbidites should take into account that rocks 
at most localities have been subjected to low grade metamor?
phism. This latter factor has resulted in disruption of the 
original grain-to-grain and grain-to-matrix contact, and also in 
partial recrystallization and mineralogical changes, especially 
of the fine-grained material. 
Most importantly, turbidites display fining upward and the 
well-defined vertical sequence of bedform intervals, or 
divisions (cf. Bouma, 1962, fig. 8): a basal-graded (sometimes 
termed massive) term (A), ranging from granule- to coarse-silt 
size (Figure 30a,b); a horizontal- or plane-laminated term (B) 
such as those in Figures 2Sb, 3 Id, 32c, 35, and 38a; a ripple 
cross-laminated division (C), sometimes with wavy, climbing, 
and/or convolute laminae (Figures 32b, 35, 36d-f)\ an upper 
parallel laminated term (D), finer-grained than the (B) division 
(Figure 28); and a poorly defined mudstone (usually slate) 
division (E) above the A-D sandstone layer (Figures 31a, 38a). 
Hydrodynamic interpretations of these divisions have been 
made by Walker (1965), Middleton and Hampton (1973), Stow 
and Piper (1984), and others. 
COMPLETE VERSUS INCOMPLETE TURBIDITES.?At most out?
crop localities in eastern and western St. Croix and on Buck 
Island, complete turbidites displaying all the A to E terms 
(Figure 28a) account for only a small percent of all sandstone 
NUMBER 33 39 
b W 
* * 
FIGURE 29.?a, Rip-up siltstone clasts (arrows) in basal massive (A) part of thick turbidite. b, Thin but very 
coarse sandstone turbidites. Note sharp base and well-developed fining-upward trends (arrows). Localities (in 
Figure 2): a = site 16; b = site 50. Hammer is 28 cm long. 
40 SMITHSONIAN CONTRIBUTIONS TO THE MARINE SCIENCES 
' - ? - ' ? 
* -^KHBI 
a A 
?4 
-\;> 
*%> b 
1 
,v;i? 
"C-.*,:^ 
* ' ? 
FIGURE 30.?Polished sections (a,c,g) and large thin sections (b,d,ef) of graded volcaniclastic sandstone 
turbidites. a-d, g, Sharp-based, coarse-grained sandstone, massive A units, ef, Medium-grained sandstone A 
division grading up (arrow) to B and C divisions. Localities (in Figure 2): a,b = site 22; c,d = site 53; e = site 
17;/= site 19; g = site 17. Scale bar applies to all components. 
NUMBER 33 41 
FIGURE 31.?Polished sections of thin-graded, volcaniclastic sandstone to siltstone turbidites showing sharp 
base; note erosional base, loads and flame structure in d. Localities (Figure 2): a,c,d = site 57; b = site 18- e = 
site 50. Scale bar applies to all components. 
42 SMITHSONIAN CONTRIBUTIONS TO THE MARINE SCIENCES 
FIGURE 32.?a, Complete A-E sandstone turbidite. b, Sandstone turbidite with climbing ripples in lower part 
topped by upper horizontal laminated D division, c, Upper thin sandstone (below pen) comprising largely B 
planar laminated division. Localities (Figure 2): a,c = site 22; b = site 50. Pen is 14 cm and hammer is 28 cm long. 
NUMBER 33 43 
FIGURE 33.?Base-of-bed sole markings and erosional structures in sequence at Point Cudejarre (site 18, Figure 
2). a, Large, cut-and-fill, erosional, scour depression (arrow) in coarse sandstone layer, b, loads and flame 
structures (arrows) at base of turbidite. Hammer is 28 cm long. 
44 SMITHSONIAN CONTRIBUTIONS TO THE MARINE SCIENCES 
-
Yt 
? ?--we *m 
V - T > 
iS&afcS raw* 
^ J * 
m 
1 ^ . o * SI k. 
FIGURE 34.?Sole markings at base of coarse sandstone gravity-flow deposits at Manchenil Bay Point (site 7, 
Figure 2). a, large linear (>2 m) grooves (parallel to hammer handle), b, Load-deformed flute marks on base of 
bed (arrows show transport toward left). Hammer is 28 cm long. 
layers. There are exceptions such as the Caledonia Formation 
sections in the ravine above the Creque Dam reservoir (site 
53, Figure 2) where well-defined (including coarse-grained, 
Figures 27, 30c,d) turbidites comprise more than 20% of all 
the sandstone beds (cf. Whetten, 1966, pis. 4 and 5), Hams 
Bluff (site 50, Figure 2), the northwest coast of St. Croix 
(Figure 38fr), and locally along the coast of Buck Island. Also 
observed are the coarse-grained sand to granule and even 
pebble-rich (Figure 14) A to E turbidites preserved in some 
Judith Fancy Formation localities such as Vagthus Point (site 
6, Figure 2). Graded units of the type described above, 
particularly the coarse ones displaying an orderly A to E or B 
to E sequence of bedform divisions, are interpreted as proximal 
turbidites. 
As noted earlier, the basal surface of beds is only rarely 
exposed and thus it is difficult to measure paleocurrent 
directions primarily from sole markings. In several cases, 
directions can be determined from grooves (Figure 34a) and 
cut-and-fill structures (Figure 33a), indicating a general N-S 
orientation; more rarely, flute marks (Figure 34b) show a 
specific (southerly) direction. Such paleocurrent measurements 
are sometimes confirmed by the orientation of foreset 
laminations in the same bed (Figure 35). The observations 
made in this study tend to support Whetten's conclusion 
(1966b:231-232) that downslope transport was primarily 
oriented toward the south (Figure 5), that is, in a direction 
away from major postulated volcanic and clastic sources 
located to the north. 
NUMBER 33 45 
Summarizing from the above observations, then, it is 
recognized that some sandstone beds at most outcrop localities 
fully qualify as turbidites. One of the more significant attributes 
of such layers is a basal-graded term, sometimes massive but 
matrix-rich, usually in sharp or erosional contact with the 
underlying mudstone. Most features illustrated in Figures 6b 
and 27 to 30 are indicative of a sudden but progressive release 
of grains from a sandy mud flow of decreasing concentration. 
Climbing ripple (or ripple-drift) bedding, also associated with 
some graded beds (Figure 32b), usually records weakening 
hydrodynamic conditions in which a very large amount of sand 
is suddenly available for deposition (cf. McKee, 1966). Much 
more frequently recognized at almost all localities, however, 
are the ripple foreset- and cross-laminations that form a large 
part or all of many sandy strata. It is these laminated deposits 
that, at least on first evaluation, have suggested truncated base 
cut-out turbidites (cf. Bouma, 1962, fig. 11). More specifically, 
it is largely on the basis of these dominant and nearly 
ubiquitous structures, i.e., foreset and cross lamination, and 
rippled bedforms (illustrated in the next two sections of this 
study) that earlier workers (Whetten, 1966b, 1974; Speed et 
al., 1979:629) interpreted many of the Caledonia laminated-
sandstone layers as distal turbidites. In this respect, the 
interested reader is directed to the interpretion of C-E turbidites 
as distal turbidites presented by Bouma and Hollister 
(1973:89). 
The mudstones (slate and fine-grained tuffaceous layers) 
between sandstones on St. Croix have earlier been attributed 
to pelagic "rain" or, possibly, deposition from the rearward 
part of turbidity currents. Some of these layers examined in 
large thin-section, displaying subtle grading and lamination, 
in fact appear to have a turbidite origin on the basis of criteria 
defined by Piper (1978), Stow and Shanmugan (1980), and 
Stanley (1981). 
QUESTIONABLE TURBEMTES.?A problem of accurate inter?
pretation remains. It is quite natural that while mapping 
sections in the field most of the attention at any one of the 
exposures would be placed on the more obvious or better-
defined strata. Thus let us assume, for example, that some 
distinct turbidites, whether they show several or all of the A 
to E divisions, have been identified at an outcrop. There may 
then be a tendency to less rigorously examine the many other 
sandstone layers in the section and interpret these as turbidites 
as well, even if their origin is not clearly evident. This is 
commonly the case with the thin (sometimes to 30 cm, but 
usually <3 cm), well stratified, sandy layers with poorly 
exposed or preserved structures in Cretaceous formations on 
St. Croix. Such layers have been identified as turbidites even 
in cases where they do not display the essential turbidite 
attributes listed earlier in this section. Repeated visits on 
subsequent trips to a number of Caledonia and Judith Fancy 
localities have revealed that, tempting as it may be to call them 
turbidites, at least half of these thin sandstone layers do not 
reveal graded bedding (compare, for example, Figure 39a,b). 
1 cm 
FIGURE 35.?Polished section (a) and thin section (b) of Caledonia Formation 
sandstone turbidite showing thin A and well-developed B and C divisions. 
Somewhat deformed foreset laminae in C division show transport to left 
(arrows). Note irregular load-deformed base. Sample collected at Hams Bluff 
(site 50, Figure 2). Scale bar applies to all components. 
Moreover, more than half of the layers do not actually conform 
to the turbidite criteria of an ordered vertical sequence of 
sedimentary structures, i.e., the A to E, B to E or C to E 
divisions defined by Bouma (1962) and other authors. 
Closer inspection indicates that many (and at some localities, 
the majority) of sandstones display, in addition to an inversion 
or irregularity in the vertical sequence of divisions, a sharp 
(sometimes reverse-graded) upper stratal surface, and/or 
laminae (some extending from the base to the top of a bed). 
The laminae are formed by concentrations of heavy minerals, 
46 SMITHSONIAN CONTRIBUTIONS TO THE MARINE SCIENCES 
Tey&tim&ssmmmmm 
FIGURE 36.?Polished sections of thin sandy B-E (a-c) and C-E (d,e) turbidites. Note post-depositional effects 
such as vein filling (d), small-scale "micro-fault" and offsets (e) and extensive recrystallization associated with 
low grade metamorphism (/). Localities (Figure 2): a = site 1; b = site 18; cf= site 50; d = site 52; e = site 9. 
Scale bar applies o all components. 
NUMBER 33 47 
1 cm 
FIGURE 37.?Polished sections of coarse, carbonate-volcaniclastic deposits emplaced by sediment-gravity flows, 
collected at Vagthus Point (site 6, Figure 2). a, Rudist fragment (along margin) embedded in a debris-flow unit. 
b, Graded turbidite. c,d, Coarse sand-flow deposits showing imbrication of some elongate particles (arrows show 
transport toward right). Scale bar applies to all components. 
48 SMITHSONIAN CONTRIBUTIONS TO THE MARINE SCIENCES 
FIGURE 38.?Examples in field of sandstone strata in northwestern part of St. Croix, some of uncertain origin. 
a, Layer below hammer is entirely horizontally laminated and poorly graded, b, Series of superimposed, subtly 
graded layers, c, Large-scale low-angle lamination unlike typical C ripple bedform division of turbidites. 
Localities (Figure 2): a = site 43; b = site 44; c = site 45. Hammer is 28 cm long. 
NUMBER 33 49 
FIGURE 39.?Comparison of graded A-E sandstone turbidite (a, arrow) and B-E turbidite (b, stratum under 
hammer handle) with non-graded, sharp base-sharp top layer with poorly developed sequence of internal 
structures (20 cm-thick layer, at bottom of photo in b). Origin of this latter sandstone stratum remains undefined. 
Localities (Figure 2): a = site 17; b = site 3. Pen is 14 cm and hammer is 28 cm long. 
50 SMITHSONIAN CONTRIBUTIONS TO THE MARINE SCIENCES 
and/or large-scale cross-bedding throughout much of the bed 
(Figure 38c). Extensive bioturbation, in some instances, can 
also thoroughly disrupt most or all of the original stratification. 
Such layers also tend to be discontinuous. 
Thus, many sandstone layers appear markedly different from 
the more "exemplary" and "classic," but less frequent, sandy 
turbidites in the same stratigraphic section. Nevertheless, these 
sandstone layers preserve one or several sedimentary features 
(usually at the base or in the lower part of the bed) that strongly 
suggest that the sands were, at least initially, emplaced by 
turbidity-current flows. It would appear that the assemblage 
of physical and biogenic structures of these "anomalous" strata 
records the effects of some other transport process, i.e., one 
which most probably modified the turbidites after their initial 
deposition in lower-slope environments. 
Bottom-Current Transport: A Subsequent 
Depositional Mode 
CHARACTERISTICS OF TRACTIVE-CURRENT DEPOSITS ON ST. 
CROIX.?The bedforms and sedimentary structures of some 
sandstone layers in both Caledonia and Judith Fancy localities 
on St. Croix are sufficiently distinctive to propose transport 
largely by tractive processes rather than turbidity currents. 
Sandstone strata that appear deposited primarily by some form 
of fluid-driven mechanism?presumably bottom currents? 
comprise up to 20% of the sandy beds in some sections. It is 
of note that such sandy layers of probable tractive-current 
origin are found interspersed with turbidites in the same 
stratigraphic section. As will be discussed below, this 
recognition of two distinct depositional types preserved at the 
same locality is critical for reconstructing the sequence of 
events affecting the emplacement of the sandy strata on St. 
Croix. 
The physical attributes of layers deposited by deep-marine 
tractive currents in modern oceans have been described and 
well illustrated by Heezen and Hollister (1971, chap. 9). The 
characteristics of bottom-current-transported, sandy deposits 
are also summarized and their attributes illustrated in other 
studies of modern ocean sediments (Hollister and Heezen, 
1972; Bouma and Hollister, 1973; Stow and Lovell, 1979) and 
of ancient deep-sea sediments preserved in the rock record 
(Hsu, 1964; Bouma, 1973; Anketell and Lovell, 1976; Unrug, 
1977, 1980; Stow and Shanmugan, 1980; Lovell and Stow, 
1981; Friedman, 1984). It has been demonstrated that bottom 
water driven by thermohaline circulation in some parts of 
modern oceans can displace sediment as coarse as granules and 
coarse-grained sand. Moreover, such material can be displaced 
over large areas at bathyal or greater depths, particularly at the 
western boundaries of ocean basins (Hollister and Heezen, 
1972). Tides and internal waves are additional components in 
sediment transport at depths below the shelf-break. 
Most sandy layers interpreted as being emplaced primarily 
by bottom currents are thin, ranging from 0.5 to 10 cm, but 
usually less than 3 cm thick. Their geometry is diverse: 
moderately even-bedded and fairly continuous, or wavy 
bedded, or discontinuous (lenticular, ripple bedded). The 
vertical sequence of bedforms and textural attributes of sands 
emplaced primarily by fluid-driven circulation differs sub?
stantially from the thin-bedded turbidites discussed in the 
previous section. For example, instead of fining upward as in 
turbidites (Figure 39a) the bottom-current emplaced stratum 
is typically sharp topped as well as sharp-based (Figures 39b, 
40-43), and typically foreset or cross laminated throughout 
most, if not all of the bed, i.e., from base to top (Figures 40-43). 
Lamination inclinations range from about 10? to 30?. The 
massive (A) and lower, distinct, horizontal-laminated (B) 
divisions associated with typical turbidites are usually absent 
at the base of the bottom-current, emplaced layer. 
The sand in such tractive layers is somewhat finer-grained 
and better sorted, with a lower matrix content (Figure 42), than 
in some thin-bedded turbidites of comparable thickness with 
which they are interbedded. In thin section the grains are 
almost always in close contact with each other, and elongate 
particles are sometimes aligned. However, it is recalled here 
again that, as in the case of turbidites, the deposits in many 
sections have been markedly affected by low-grade metamor?
phism. It is expected that the original grain-to-grain and 
grain-to-matrix contact, and also the original grain orientation, 
have been modified, sometimes substantially, after deposition. 
The upper stratal surface is usually sharp and may be flat 
(Figures 42a-a\ f) or wavy and undulating (Figures 42g, 43, 
44a, 45b). In cross-section some sandstone units as a whole 
show large-scale megaripple bedding (Figure 44a) or thick, 
superposed foresets (Figure 44b). Others show discontinuous 
bedding, including lens-like, "starved," rippled (Figure 45a), 
and pulsing-current (Figure 46a) configurations. Flaser bed?
ding, with mud in ripple troughs and partly on crests (cf. 
Reineck and Singh, 1975, 97-99), is also noted in some 
polished sections (Figures 43a, 47c). Reverse-graded bedding 
is sometimes observed in polished slab and thin section (Figure 
48a-d). Thin sections (Figure 42b,d) also reveal some 
cross-and foreset-lamination highlighted by heavy mineral 
concentrations (including apatite, enstatite, actinolite, and 
opaque minerals), and also by iron staining. This observation 
and others cited above suggest processes of placer concentra?
tion (Figure 41a,c) and winnowing of fines, typically 
associated with the development of ripples in an environment 
affected by bottom currents. Microprobe analysis of dark 
laminae shows that these are usually iron-enriched: this may 
be a post-depositional weathering phenomena, perhaps altera?
tion of selected, iron-rich, heavy-mineral grains concentrated 
along lamination surfaces. 
Bioturbation is an important attribute of the tractive deposits 
of Cretaceous formations in St. Croix. Reworking by 
organisms may be moderate or disrupt much, if not all, of a 
bed (Figures 49, 50) or even several closely-spaced strata. 
In large outcrop sections, including the Springfield (Figure 
NUMBER 33 51 
FIGURE 40.?Sandy strata with sharp base and sharp top, displaying well-defined foreset lamination. Apparent 
current transport, shown by arrows, toward right in a and toward left in b. Localities (Figure 2): a = site 18; 
b = site 19. Hammer is 28 cm and pen is 15 cm long. 
52 SMITHSONIAN CONTRIBUTIONS TO THE MARINE SCIENCES 
'1*1+' 
FIGURE 41.?Current laminated sandy strata, with sharp flat base but wavy upper surface. Apparent current 
transport, shown by arrows, toward right in a and toward left in b and c. Dark laminae in c highlighted by 
concentrations of heavy minerals. Localities (Figure 2): a = site 7; b = site 57; c = site 55. Pen is 13 cm and 
hammer is 28 cm long. 
NUMBER 33 53 
l l ? ? ? ! * ? 
i i 1111 i iifrmpr-'-
? ? ? ? . ^ ? , , , ' . t i . . 
FIGURE 42.?Polished sections (a,c,e-g) and thin sections (b,d) showing non-graded sandy strata with sharp 
base and top. Foreset lamination (arrows indicate apparent current directions); some laminae highlighted by 
heavy minerals (a-d). Note lens-shaped ripple-bedded stratum in g. Localities (Figure 2): a-d - site 22; e = site 
21; /= site 50; g = site 19. Scale bar applies to all components. 
54 SMITHSONIAN CONTRIBUTIONS TO THE MARINE SCIENCES 
1 cm 
FIGURE 43.?Thin, current-laminated, sandy layers displaying wavy and discontinuous bedding. Apparent current 
directions shown by arrows. Note Baser-like bedding in a and diverse, rippled- bedform configuration of layer 
in b to e. Localities (Figure 2): af= site 57; b,e = site 55; c = site 44; d = site 56; g = site 10. Scale bar applies 
to all components. 
NUMBER 33 55 
1 %:w 
FIGURE 44.?Megaripple bedform (crest-to-crest distance about 1 m) in a and thick overlapping foresets in b. 
Both exposures at Manchenil Bay Point (site 7, Figure 2). Apparent direction of transport toward right in both 
examples (arrows). Pen is 13 cm and hammer is 28 cm long. 
56 SMITHSONIAN CONTRIBUTIONS TO THE MARINE SCIENCES 
FIGURE 45.?Thin sandy layers, some discontinuous and lens-like (arrow in a, with apparent current transport 
toward left), and others lenticular and wavy bedded (arrow in b). Stratigraphic sections in a and b include both 
bottom-currentAractive transport and turbidite layers. Localities (Figure 2): a = site 57; b = site 20. Centimeter 
scale in a and pen is 14 cm long in b. 
NUMBER 33 57 
? ? . . ? ? . 
FIGURE 46.?Polished sections of sandy laminated (some cross-bedded) sections showing wavy and rippled 
configurations. Apparent transport directions indicated by small arrows. Localities (Figure 2): a,e = site 50; 
b = site 52; c = site 20; d - site 18. Scale bar applies to all components. 
58 SMITHSONIAN CONTRIBUTIONS TO THE MARINE SCIENCES 
^ - ~ - * * r 
1 cm 
FIGURE 47.?Polished sections of current-laminated strata, some showing flaser-like structures (upper in C). 
Dark laminations in these selected non-graded samples highlighted by heavy minerals (a, lower in c) and also 
by fine-grained sediments (b.de,). Localities (Figure 2): a = site 18; b,c,e = site 50; d = site 2. Scale bar applies 
to all components. 
NUMBER 33 59 
-
-
- --^ -- .'it-..-'. v-.iiT0 gfcffg -
'. Si ? ~V *"^ *? "i'-'Vl^Y- :?--** V;". ,,-...' 
?.<.--" V i^ Sfe 
S A f * ^ 
? f ' ?"??'? & ? h i S j ? * " ? - ' ' 
? 
FIGURE 48.?Polished (a, c?e) and thin sections (b, f) showing non-graded (ef) and reverse-graded bedding (in 
b-d). Note rippled bedform in a,b, and lenticular configuration in d. Localities (Figure 2): a.b = site 21; c = site 
50; d - site 53; ? = site 14. Scale bar applies to all components. 
60 SMITHSONIAN CONTRIBUTIONS TO THE MARINE SCIENCES 
3 1 cm 
FIGURE 49.?Polished sections illustrating diverse examples of bioturbation noted in bottom-current transported, 
including rippled, layers (c). Reworking by organisms involves both sandy and mud-rich layers. Localities 
(Figure 2): a = site 55; b = site 16; c = site 50. Scale bar applies to all components. 
NUMBER 33 61 
FIGURE 50.?Polished sections illustrating diverse examples of bioturbation noted in bottom-current transported, 
including rippled, layers such as b. Note complete disruption of stratification in some sandy layers (lower part 
in a, and e). Localities (Figure 2): a = site 55; b = site 50; c - site 21; d = site 1; e = site 43; / = site 53. Scale 
bar applies to all components. 
62 SMITHSONIAN CONTRIBUTIONS TO THE MARINE SCIENCES 
FIGURE 51.?A well-exposed ripple-train surface showing weakly undulating-to-straight crested ripples in 
fine-grained sandstone in Springfield Crusher quarry (site 57, Figure 2). Current direction, toward upper left, 
shown by arrows. Section in a is close-up of large surface shown in b. Hammer is 28 cm long. 
5lb), the St. Croix Sand and Stone, and the Caledonia Gut 
quarries, the well-exposed upper surface of some beds is 
entirely rippled. These surfaces covered by ripple trains display 
several types of ripple forms. The most common are weakly 
undulatory to straight-crested (Figure 51a), asymmetric in 
profile. Ripples superimposed on larger mega-ripples (Figure 
44a) are also observed on a more restricted scale (Manchenil 
Point, site 7, Figure 2). 
PALEOCURRENT ANALYSIS.?The paleocurrent measurements 
determined from rippled bedding surfaces and foreset lamina?
tion in both eastern and western St. Croix and on Buck Island 
indicate regional trends in tractive transport, primarily toward 
the WNW, W, and WSW quadrants. The directions at any one 
site, however, are usually not uniform, a phenomenon also 
noted by Whetten (1966b: 195). For example, tractive-current 
structures in the Caledonia rocks at Point Cudejarre and East 
End Point (sites 18 and 19, Figure 2), and in the Judith Fancy 
sequence at Manchenil Bay (site 7, Figure 2), indicate transport 
toward both the NW and the SE (Figure 5). 
The exact orientation of the above-cited paleocurrent trends 
during the Late Cretaceous may be compromised by the 
intense, post-depositional, structural activity that has deformed 
the Cretaceous series. However, the overall regional westerly 
direction of tractive transport recorded by different Cretaceous 
rock units at diverse localities, all of which have been 
tectonically modified, is sufficiently consistent to allow the 
generalized east-to-west interpretation proposed herein. 
Interestingly, it appears that in some Caledonia and Judith 
NUMBER 33 63 
Fancy sections the major tractive-current transport trends 
(primarily toward the W) are oriented in a direction 
perpendicular to that measured on turbidites (primarily N-S 
trends). That paleocurrent trends measured from bottom-
current structures are oriented in directions that are normal, or 
at a considerable angle, to those of sediment-gravity flows 
(presumably oriented downslope) at the same locality (Figure 
5) provides a powerful argument favoring contour-following 
tractive flow. Neither the mechanism(s) inducing such bottom 
currents in this region nor the precise orientation or intensity 
of their flow are known. From the sum of observations, 
however, it is clearly apparent that the currents sweeping the 
ocean floor were sufficiently powerful to displace fine- to 
coarse-grade sand along the lower-slope environments. 
Bottom Currents and the Reworking of Turbidites 
CHARACTERISTICS OF SANDY VARIANT LAYERS ON ST. 
CROIX.?The assemblage of sedimentary structures discussed 
in the previous section indicates that me flow of water above 
the bottom was sufficiently strong to displace coarse sand and 
granules and thus was able to rework and redeposit volcaniclas?
tic sand layers. It is these currents that have resulted in the 
lithofacies variants that are transitional between typical 
turbidite and distinct, bottom-current deposited end-members. 
These, herein, are termed variant layers. This section focuses 
on these sandy turbidite-tractive current variants that are 
observed in both the Caledonia and Judith Fancy formations 
and constitute the dominant lithofacies in these Cretaceous 
series. 
Most stratigraphic sections on St. Croix include some 
distinct, well-graded, sandstone turbidites (see the lower bed 
in Figure 52a). Most of these sections, however, usually 
comprise substantially more strata that display stratification 
characteristics different than classic turbidites. Many of these 
variant units, for example, display a bedform geometry that is 
wedge-shaped or wavy-ripple bedded (strata in the middle and 
top part of Figure 52a, and in the upper part of Figure 52b) 
rather than evenly stratified. Moreover, foreset lamination is 
usually pronounced throughout most of the bed, usually 
occurring just above a thin, generally much-reduced, basal-
graded horizon. Confusion in identification of lithofacies 
usually arises because variants often show some upward-fining 
at or near their base. As in the case of typical turbidites, the 
base of this lower-graded portion is usually sharply defined 
and displays an erosional contact with the underlying mudstone 
(Figure 52b,c). 
At the same outcrop it is sometimes difficult to distinguish 
a thin sand A-E turbidite with a well-developed foreset-
laminated C division (Figure 53a) from a thin sandy variant 
layer where the basal-graded massive A division passes directly 
to a laminated section similar to the C division of turbidites 
(Figure 53b). Careful inspection shows that the basal-graded 
unit is delimited by a sharp upper stratification contact that 
sometimes forms a wavy rippled surface; directly above this 
contact lies the foreset-laminated unit (Figure 536). This 
contact is interpreted as a break in sedimentation wherein 
currents depositing the upper layers have eroded and/or 
reworked the turbidite layers remnant in the lower bed. In 
sandy variants, the planar horizontal-laminated division B, 
usually found above the graded A term of turbidites, is notably 
absent (Figures 53b, 54a,b). Moreover, in some of these sandy 
layers, the lower-graded portion is topped by a foreset- and 
cross-laminated section where the laminae are highlighted by 
heavy-mineral concentrations (Figures 54c,d, 55b). 
INTERPRETING THE DEPOSITIONAL ORIGIN OF VARIANTS.? 
Thus, in most cases it is the lower part of sandy variants that 
is most closely similar to that of thin sandstone turbidites: (1) 
a graded-basal unit (usually sand plus matrix) may be present; 
(2) the sharp base frequently shows an erosional contact with 
the underlying mudstone, and (3) the base of bed also 
commonly displays what appear to be load-deformed sole 
markings (Figures 54c, 55b) and flame structures (Figures 
56c, 57a). In contrast with turbidites, however, is the absence 
of a planar division and upward passage from the graded-
bedding layer directly to the laminated rippled section (Figures 
56a,a\e, 51 g) consisting of texturally cleaner sand. This upward 
sequence of bedforms provides an essential clue to interpret 
the origin of the variants: the foreset and cross lamination 
indicate a partial reworking by tractive processes of the sands 
forming the upper and middle parts of original turbidite layers. 
Tractive processes progressively erode a sand layer from the 
top downward. This downward reworking of the sand would 
thus best explain the disrupted (sometimes reversed) normal 
base-to-top sequence of turbidite bedform divisions. 
The truncation of laminae at the upper bedding surface of 
sand layers (Figures 55b, 56c, 51b-d, f), recording erosion of 
rippled sand layers, provides additional evidence of bottom 
current processes. Other indications of such processes are the 
concenuation of heavy minerals along lamination surfaces 
(Figures 56d, 51b-d), and the presence of flaser-type 
stratification (Figure 58a,d). All the above characteristics, 
together, attest to the extensive reworking of sand layers, 
including winnowing by bottom currents and deposition of 
placer deposits. If the tractive process is allowed to continue, 
all of the sand grains forming an original turbidite would be 
displaced and the original layer completely reworked. The 
end-product lithofacies should then resemble the bottom-
current remolded deposits described in the previous section. 
BIOTURBATION AND ITS SIGNIFICANCE.?It is of note that thin 
sandy layers recognized as anomalous turbidites, or variants, 
like many strata emplaced almost entirely by tractive processes, 
are commonly bioturbated. In those infrequent cases where 
bedding surfaces are exposed, burrows and grazing structures 
are sometimes observed (Figure 59a). In cross-section, layers 
reveal structures produced by benthic organisms that may be 
vertically oriented (Figure 60a-c). The activity of organisms 
is such that original internal stratification features can be 
-? j^-irtj i y n fttt^Wb^-t .?-??- w 
? - ? ? ? - -
FIGURE 52.?Polished sections showing examples of diverse sandy strata in Caledonia Formation. Thin-bedded, 
graded, sandy turbidites (lower stratum in a; arrow shows upward fining) interbedded with non-graded, largely 
laminated layers. Note foreset, laminated, wavy- and lenticular-rippled layers in a and b, wedge-shaped layer 
(top in a), and sharp-topped and sharp-based, even-bedded layer in c. Localities (Figure 2): a,c site 50; b = site 
3. Scale bar applies to all components. 
NUMBER 33 65 
FIGURE 53.?Two sandy layers of about same thickness, each with basal massive and upper foreset and paraUel 
laminated units, but probably of different origin, a, Sharp-based, well-graded, sandy turbidite showing upward 
progression of A, B, and C divisions; apparent transport direction toward right (arrow), b, Sandy sharp-based 
layer, with lower, poorly graded (perhaps massive A) division topped by rippled upper surface (two large 
arrows). This surface directly covered by sharp-topped, foreset-laminated unit (apparent transport direction 
toward left, small arrow), and in turn topped by separate, horizontal, laminated section. Rippling of basal layer 
and absence of lower B division below foreset laminated section should be noted. This layer interpreted as 
turbidite reworked by tractive current-transport. Localities (Figure 2): a = site 50; b = site 18. Hammer handle 
width is 3.5 cm. 
66 SMITHSONIAN CONTRIBUTIONS TO THE MARINE SCIENCES 
1 cm 
FIGURE 54.?Polished sections illustrating sandy layers that lack planar horizontal B division between graded 
base and upper foreset (a,b) or cross-laminated (d) part of stratum. Note marked erosional base in a and c. 
Apparent transport directions indicated by arrows. Localities (Figure 2): a = site 15; b = site 55; c,d = site 7. 
Scale bar applies to all components. 
substantially disrupted and, in some cases, obliterated (Figures 
59b, 60d). Bioturbation of fine-grained deposits is difficult to 
observe in the field but more readily apparent in polished 
sections (Figure 61). The sections indicate that reworking of 
the sea-floor surface by organisms was not restricted to sandy 
layers. Direct visual study of the seafloor shows that in some 
modern oceans bioturbation is intense and may occur rapidly, 
even at great depths. If observations made in modern settings 
are applicable to the Cretaceous rocks on St. Croix it would 
appear that there was ample time for benthic organisms to 
NUMBER 33 67 
* * * ^ ? * * < 
FIGURE 55.?Weathered exposure at the outcrop (a) and polished section (b) of same units. Latter shows sandy 
layer with sharp-erosional base, sharp top, graded bedding at very base, and prevalence of cross-lamination 
through stratum. Sandy lens (arrow) within finer-grained layer in (b) probably not biogenic in origin (laminae 
are preserved). Sample collected at East End Point (site 19, Figure 2). Scale bar applies to all components. 
68 SMITHSONIAN CONTRIBUTIONS TO THE MARINE SCIENCES 
FIGURE 56.?Examples of sharp-based and sharp-topped, graded and laminated layers suggesting multiple 
depositional origin. a,c,e are polished sections; b,dfare thin sections. a,b, Graded layer (A division) not followed 
upward by horizontally layered B division; note, however, upper rippled bedform and sharp top. c-f = Graded 
layers with erosional base (note small flame structures), and cross stratified throughout; some dark laminations 
(in d and/) highlighted by concentrations of heavy minerals. Localities (Figure 2): a-c = site 18; a\e = site 19; 
/ = site 52. Scale bar applies to all components. 
NUMBER 33 69 
FIGURE 57.?Polished sections showing examples of thin, sharp-based (some with an erosional surface), and 
sharp-topped layers; some display moderate graded bedding at base. Upper foreset laminations may be truncated 
(particularly b-d, f); small arrows indicate apparent direction of transport. Foreset laminations can extend from 
(or near) top to base of bed. In several cases, laminations are highlighted by heavy mineral concentrations (b,c). 
Geometry of such strata is diverse: wavy bedded (a), wedge-like (c) or lenticular (j>). Localities (Figure 2): 
a,c,e = site 50; b = site 43; d = site 17;/= site 52; g = site 18. Scale bar applies to aU components. 
rework and thoroughly disrupt the surficial sediment layers 
between the periodic incursions of sand emplaced by turbidity 
currents. 
The generally good preservation of layering is probably a 
function of continuous sedimentation and relatively high rates 
of accumulation rather than a low benthic population or 
changes in the assemblages of organisms. Thus, it would 
appear that the pulses of sediment supplied to the lower slope 
70 SMITHSONIAN CONTRIBUTIONS TO THE MARINE SCIENCES 
FIGURE 58.?Thin, moderately graded sandstone layers that suggest evidence of turbidite and also tractive-current 
origin. Strata almost entirely laminated, some showing flaser-like stratification (upper in a, lower in d), 
wavy-ripple bedding (lower in both a and d), cross-lamination (b), and alternating sequences of planar-horizontal 
and ripple laminations (c). Localities (Figure 2): a,d = site 50; b = site 49; c = site 55. Scale bar applies to all 
components. 
NUMBER 33 71 
FIGURE 59.?a, Worm burrows preserved on extensively reworked bedding surface; pen is 16 cm long, b, 
Even-bedded, sharp based-sharp topped, fine-grained, tuffaceous layers. Absence of internal structures may 
possibly be the result of extensive biogenic reworking throughout beds; hammer head is 17 cm long. Localities 
(Figure 2): a = site 19; b = site 55. 
in this region were important and frequent. Moreover, the 
bottom-currents were apparently sufficiently strong so that the 
original turbidite sands could be redistributed laterally, often 
with only modest or no bioturbation. 
TURBIDITE TO REWORKED-SAND CONTINUUM.?The rework?
ing of sands was primarily by physical processes capable not 
only of disrupting the original vertical sequence of turbidite 
bedform divisions and forming wavy and ripple bedding 
(Figure 62a,b), but also of producing a discontinuous lateral 
extension and pinch-out of strata (Figure 62c). Pinch-out and 
development of relatively clean sandy lenses (such as starved 
ripples) may be observed within short stretches of exposed 
section at many outcrop localities. Thus, the majority of thin 
sandy strata such as those in Figure 62, which on cursory 
observation appear to be C-to-E turbidites, are more 
reasonably interpreted as partially to thoroughly current-
reworked turbidites. On the basis of their characteristics, these 
layers are not distal turbidites, and it does not appear that the 
original gravity-flow units were emplaced beyond the base of 
slope. 
Current-reworked turbidites, overall, comprise more than 
half of the thin sandy strata in die Caledonia Formation, and 
they also constitute a substantial proportion of sandy layers in 
the tuffaceous-rich series on St. Croix. The examples of 
Cretaceous strata illustrated in this monograph are petrologi-
cally diverse. An inventory of all observed attributes enables 
us to postulate a rational continuum of sandy deposits that 
includes complete turbidites, through a series of partially to 
72 SMITHSONIAN CONTRIBUTIONS TO THE MARINE SCIENCES 
FIGURE 60.?Many of the thin sandstone strata of poorly or undefined origin (some perhaps current-reworked 
turbidites) show various types of organic structures produced by organisms that have deformed original 
stratification (arrows). Burrowing and grazing by some organisms affect upper stratal surface (a) or may be 
vertically oriented (c), and sometimes disturb several layers (b,d). Localities (Figure 2): a-c = site 55; d = site 
42. Scale bar applies to all components. 
thoroughly current-reworked turbidites, and finally to deposits 
whose petrology records primarily a tractive origin (Figure 
63). The ultimate lithofacies in this scheme are those in which 
all original sediment gravity-flow structures, bedforms, and 
sedimentary fabric have been eradicated and replaced by new 
ones recording the effects of erosion and a subsequent bottom 
current transport mode. 
Conclusions 
This sedimentological study of the Late Cretaceous volcani?
clastic rocks on St. Croix reveals a remarkable diversity of 
sandy lithofacies. The petrological approach used is a 
descriptive one emphasizing sedimentary structures and 
bedforms, and indicates that a natural continuum of sandy 
lithofacies exists between deposits emplaced by downslope-
directed, gravity-driven flows and tractive bottom-current 
processes. Relatively few layers are either distinct turbidites 
or of entirely tractive origin. Rather, most strata are either 
turbidite-like or appear bottom-current related, with these latter 
being recognized as transitional, or variant, bedding types. No 
systematic vertical-temporal changes in proportion of sandy 
lithofacies were observed in outcrop sections at most localities. 
An overall inventory of sediment types indicates that the 
NUMBER 33 73 
FIGURE 61. Polished sections showing evidence of extensive bioturbation in thin sandstone strata of poorly 
defined origin (including some reworked turbidites). Structures by organisms also noted in fine-grained layers 
between sandstone strata. Localities (in Figure 2): a = site 55, b - site 43; c,e = site 50; d - site 53; /= site 17. 
Scale bar applies to all components. 
FIGURE 62.?Thin, laminated, sandstone strata showing some features commonly associated with turbidites 
(graded bedding and basal erosional markings in a), but many lack the accepted, orderly, vertical turbidite 
sequence of A to E bedform divisions. Tractive current transport is recorded by foreset and wavy-ripple bedding 
and concentrations of heavy minerals (b). Discontinuous bedding and pinch-out also commonly observed. Sandy 
units, such as those in b and c, typical of most sandstone layers observed in Caledonia Formation in St. Croix 
and Buck Island and also some sections of the Judith Fancy Formation and other Cretaceous tuffaceous units 
in St. Croix. These sandy layers are probable reworked turbidites. Localities (Figure 2): a = site 3; b = site 19; 
c - site 29. Pen is 14 cm and hammer is 28 cm long. 
NUMBER 33 75 
Ep 
Et 
D 
C 
B 
? t = ^ = ^ r r = ???t== 
? ? "r^ ^=?3: _ 3J?_T 
? 7- ? 
'y ' . ' : ? . ' ?-_? ' . -
* ?S*? r ' ? ..,--,- .-;;:?,.?, ,.\ 
r:'~";-rp, " _ ... :.,^^_ ,'^ 4^WW 
SS!^~ri"~.; ,^^; .^; ;^^; .^2j jy? 
?'?.', ? ? ',' _V.r.-,. ? \ - *' '""'v'1?^?**f.w?2! 
"'jy*" jr.'' . ..???' ,-??"' ..."' ,' " " , 
".^-/~,-:': - ;v.?'?""'":".:_..,'.'. i.:^^^L'r**J^vi^*'^'^ 
A ^ ?vS^ ' 'K :V - : ^f ;^ 
^^^^d0^i^^^i 
;.-..?,?.,;n. 
^#v|||$^tl?|f$ 
-?v..-' ?:?..-rr.-^i^i 
=v; r^ \:*?*?'5A_ 
10 
FIGURE 63.?Scheme showing possible continuum of structures that could result from reworking of sandy layer 
originally emplaced as complete A-E turbidite (1, at left). Reworking would result in partially eroded (2) and 
redeposited turbidite (variant layer) series (3-7), to completely remolded and entirely foreset laminated (8, 9) 
and discontinuous (10) layers. Stratal types 7 to 10 are end-products of reworking by bottom currents. Note 
progressive downward erosion and lateral disruption of original turbidite layer. Actual examples presented in 
this monograph that could be used to illustrate this series as follows: 1 = Figure 39a; 2 = Figure 28a; 3 = Figure 
56a,b; 4-7 = Figure 53b; 8 = Figure 556; 9 = Figure 62b; and 10 = Figure 45a. 
lower portion of the variant sand layers often preserves the 
original basal graded (A) turbidite division, while the mid and 
upper parts of such layers display structures more typically 
associated with tractive transport. The continuum of bedding 
sequences presented herein (Figure 63) is interpreted as a 
genetic organization of sand types: volcaniclastic sands were 
initially emplaced by downslope gravity transport, and 
subsequently reworked by bottom currents. 
This investigation indicates that the sandy deposits were 
emplaced in a proximal setting, perhaps in lower-slope aprons, 
rather than in more distal and better organized submarine fan 
lobes or basinal environments. This more proximal slope 
interpretation is based primarily on the assemblage of selected 
facies including slides, slumps, coarse debris flow deposits, 
coarse and complete (A to E) turbidites, and sand-flow layers. 
Prevailing southward-directed transport directions are mea?
sured from structures in sediment-gravity-flow deposits. At the 
same localities, predominant westwardly (but not uniformly 
oriented) transport directions are based on measurements from 
features formed by bottom currents. This near-perpendicular 
divergence of paleocurrent directions is a strong argument 
indicating that, after downslope transport, turbidites and the 
associated layers show reworking by tractive processes. Sands 
were probably redistributed along bathymetric contours. 
Field and petrologic data accumulated herein suggest that 
the volcaniclastic Cretaceous deposits likely accumulated in a 
technically active, island-arc setting as postulated by earlier 
workers (Whetten, 1966b; Speed et al., 1979). The paleogeogra?
phic position in the Late Cretaceous of the sea-floor sediment 
presently constituting St. Croix and the St. Croix Ridge 
remains uncertain. The geographic position of this region 
relative to the paleo-Atlantic and what was to become the 
northeastern Caribbean is indicated in a very general way in 
studies by Sclater et al. (1977, figs. 15,16), Pindell and Dewey 
(1982), Burke et al. (1984, fig. 7), Ghosh et al. (1984, fig. 10), 
Mattson (1984, fig. 4) and others. The rocks, in any case, record 
evidence of syndepositional deformation of sedimentary and 
biogenic structures and of the original fabric by intense tectonic 
and volcanic imprint in the Late Cretaceous and early Tertiary. 
The paleocurrent analyses provide insight into deep-water 
circulation patterns during the Late Cretaceous in this part of 
the paleo-Caribbean. Although not consistent, the predominant 
76 SMITHSONIAN CONTRIBUTIONS TO THE MARINE SCIENCES 
paleocurrent trend is to the west. This bottom-water flow trend 
roughly parallels the westerly surface circulation postulated for 
this region between 100 and 65 million years ago by Berggren 
and Hollister (1974, fig. 16). The ubiquitous bioturbation 
recorded in current-reworked sandy layers and interbedded 
mudstones is an additional indication that circulation above the 
sea floor was not restricted and that bottom waters were not 
extensively anoxic (cf. Simoneit, 1986, fig. 9). 
The generality proposed by Shanmugan and Moiola (1982), 
that most sequences rich in turbidites and winnowed-reworked 
turbidites closely correspond to global lowstands of paleo-
sealevel, does not apply in this instance. On the contrary, it 
would appear that bottom-water circulation, presumably of 
thermohaline origin, prevailed during the Late Cretaceous, a 
period of high sea level. Currents sweeping the sea floor were 
vigorous and of sufficiently high energy to rework turbidites, 
even those composed of coarse sand. 
The validity of the turbidite-to-tractive deposit continuum 
presented herein could be tested experimentally. It should be 
possible, for example, to observe the influence of bottom 
currents on sandy turbidites in flumes, and to quantify flow 
conditions required to partially, and then completely, remold 
such layers by tractive processes. Observations, albeit indirect, 
relating to this phenomenon already exist. For example, 
evidence of turbidites reworked by bottom currents are 
preserved in modern oceans (Heezen and Hollister, 1964; 
Stanley, 1969, fig. 9), particularly where their western margins 
are subjected to and influenced by geostrophically driven 
contour-following currents (Tucholke and Ewing, 1974; 
Hollister and McCave, 1984; Kuijpers and Duin, 1986). Further 
examination of sedimentary structures, bedforms, and textures 
in sand layers from continental rise cores off the U.S. East 
Coast, for example, may reveal variant lithofacies comparable 
to those of St. Croix described in this contribution. 
The implication here is not that the thousands of turbidite 
studies made to date need reinterpretation. On the other hand, 
it would seem reasonable that observations made in this study 
are not unique to St. Croix, and could thus be applied 
elsewhere. It would be useful to compare observations from 
the Cretaceous sandy rocks illustrated in this investigation with 
other formations in the modern and rock record where sandy 
turbidites appear petrologically anomalous or where a gravity-
emplaced interpretation seems forced or remains questionable. 
Twenty years ago Ph.H. Kuenen (1967:241) ended his 
valuable treatise reviewing the emplacement of flysch-type 
sand beds with the apocalyptic statement that "hasty substi?
tution of turbidity currents by normal currents is like jumping 
from purgatory, where there is hope, into hell, where there is 
none." This view needs to be tempered. Turbidity currents are 
not in question: they do occur, they are clearly a major 
depositional process in the marine environment, and even in 
the Recent have been shown to account for the displacement 
of sand from shallower environments to the deep sea floor. 
But in view of the many documented observations in the 
modern and rock record, a minimizing or ruling out of the 
potentially important role of tractive processes by deep currents 
is unrealistic and untenable. Continuing to refine interpreta?
tions of sand-layer transport would enhance the accuracy of 
paleogeographic reconstructions and paleobasin analyses. To 
overlook the possible interaction between bottom currents and 
turbidity currents would only serve to retard our understanding 
of deep-sea sedimentation. 
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