SMITHSONIAN CONTRIBUTIONS TO THE
EARTH SCIENCES
NUMBER 8
DanielJ. Stanley,
Donald]. P. Swift,
Norman Silverberg,
Noel P.James,
and Robert G. Sutton
Late Quaternary
Progradation and
Sand Spillover on
the Outer Continental
Margin Off Nova Scotia,
Southeast Canada
.APR 1} iQ/>-
SMITHSONIAN INSTITUTION PRESS
CITY OF WASHINGTON
1972
ABSTRACT
Stanley, Daniel J., Donald J. P. Swift, Norman Silverberg, Noel P. James, and
Robert G. Sutton. Late Quaternary Progradation and Sand Spillover on the
Outer Continental Margin Off Nova Scotia, Southeast Canada. Smithsonian
Contributions to the Earth Sciences, number 8, 88 pages, 1972.?Three distinct
sediment types have prograded seaward from the outer shelf to the slope and rise
in the vicinity of Sable Island Bank southeast of Nova Scotia during late Quaternary
time. On the slope, the oldest facies recovered in cores is* a brown to brick red,
irregularly stratified, pebbly-sandy-clayey silt. Locally it is covered by an olive gray,
clayey silt with a low sand and pebble content. This more homogenous gray facies
displays abundant biogenic structures. A third facies, a thin layer of very fine, gray
sand and muddy sand, locally covers brown and olive gray sediments on the slope
and upper rise. All three facies contain similar light, heavy, and clay mineral suites.
The regional distribution of these facies has been determined by core traverses
normal to the shelf edge, including one passing down the axis of The Gully (largest
submarine canyon in the area), and another extending down the dissected slope
off Sable Island Bank. The brown, late Pleistocene unit is exposed on the floor of
The Gully and on its dissected deep-sea fan; postglacial bottom processes have kept
younger sediments from accumulating in these areas. The brown beds also are
exposed on the lower slope and rise off Sable Island in areas of slumping or non-
deposition. The olive gray facies, late Pleistocene-Holocene in age, occurs primarily
on the slope; it is thicker on flanks of slope valleys and thinner or absent on the
divides. It is absent on part of the lower slope and upper rise. On the lower rise,
tan mud with a coarse fraction rich in Foraminifera and shell debris may be the
equivalent of the olive gray slope facies.
These sediments reflect changes in the sedimentary regimen during the post-
Wisconsinan transgression. The observed sequence starts with the Wisconsin low
stand of the sea when glacial drift, including reddish-brown, fluvioglacial sediments,
were deposited over the Nova Scotian Shelf as far as Sable Island Bank. Periglacial
outwash spread across the bank and flowed seaward around it. Deposition of the
slope and rise brown facies is associated with this period; textural inhomogeneity
suggests downslope transport by mass movement. Pebbly lenses resulted, in part,
from ice-rafting prevalent during this phase. The contact between brown and the
overlying olive gray, clayey silt facies is often abrupt, commonly occurring within
several centimeters; this change is correlated with the rise of the late Quaternary
sea above the margin of Sable Island Bank.
As the sea transgressed across Sable Island Bank in late glacial time, fines win-
nowed from fluvioglacial sediment were moved north of the Bank (into the Gully
Trough) and seaward onto the slope. Coarse materials no longer reached the slope
with former frequency, and the fines were supplied at a markedly lower rate. This
decrease in sedimentation rate on the slope coincides with an increase in the organic
fraction and bioturbation. Suspended fines were reduced to a gray hue as they
passed through the sediment-water interface whose rate of upward growth was
now an order of magnitude smaller. The Pleistocene-Holocene boundary of approxi-
mately 10,000 years B.P. occurs within the olive gray facies. As sea level attained
its near-present position, and the present configuration of bottom currents was
established, the lag (modified relict or palimpsest) sands on the Nova Scotian Shelf
began a pattern of radial dispersal that may now be observed on Sable Island and
associated banks. This bottom current activity has resulted in the development of
spillover sands on the upper slope and deposition of thin discontinuous layers
(including someturbidites) on the slope and rise and in The Gully Canyon.
Official publication date is handstamped in a limited number of initial copies and is recorded
in the Institution's annual report, Smithsonian Year.
UNITED STATES GOVERNMENT PRINTING OFFICEWASHINGTON : 1972
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Contents
Page
INTRODUCTION 1
GEOGRAPHY AND TOPOGRAPHY OF THE STUDY AREA 2
General Setting 2
Morphology of the Outer Margin near Sable Island Bank 3
The Gully Submarine Canyon 3
Slope and Upper Rise off Sable Island Bank 6
SUBMERGED TERRACES AND SEA-LEVEL CHANGES 9
SEDIMENT DISTRIBUTION PATTERNS ON THE OUTER NOVA SCOTIAN SHELF ... 9
General Textural Composition of the Shelf 9
General Mineralogical Composition of Surficial Shelf Sediments 13
GENERAL DESCRIPTION OF SLOPE AND RISE SEDIMENTS 16
Cores Examined 16
Four Outer Continental Margin Facies 17
Physical and Biogenic Stuctures in Slope Cores 19
Sediment Sequences on the Lower Rise and Abyssal Plain 22
TEXTURAL ANALYSES OF OUTER MARGIN SEDIMENTS 24
Outer Shelf near Sable Island Bank 24
Gully Trough and The Gully Canyon 26
Continental Slope South of Sable Island Bank: Upper Slope Samples .... 31
Upper Slope to Lower Rise Traverse 32
MINERALOGICAL COMPOSITION OF OUTER MARGIN DEPOSITS 33
Sable Island Bank Sediments 33
Gully Trough Sediments 36
The Gully Canyon Sediments 40
Continental Slope Sediments 43
Upper Slope to Rise Traverse 50
CLAY MINERALOGY ON THE OUTER MARGIN OFF NOVA SCOTIA 56
Slope off Sale Island Bank 56
Slope and Rise Traverse South of Sable Island Bank 59
Clay Mineral Suite in the South Area 62
FORAMINIFERA AND STRATIGRAPHY OF SURFICIAL CONTINENTAL MARGIN
SEDIMENTS 62
INTERPRETING SEDIMENTARY SEQUENCES AND STRATIGRAPHY 65
Slope and Upper Rise Facies 65
Lower Continental Rise Facies 67
SEDIMENT DISPERSAL AND SPILLOVER ON SHELF-EDGE BANKS 67
Introduction 67
Sedimentation During Subaerial Exposure 67
Sedimentation During and Subsequent to Inundation 68
Radial Dispersal and Sediment Spillover 69
'?it
SMITHSONIAN CONTRIBUTIONS TO THE EARTH SCIENCES
Page
QUATERNARY PROGRADATION ON THE NOVA SCOTIAN OUTER MARGIN :
A SUMMARY 70
Introduction 70
Brown Sediment Time 70
Gray Sediment Time 75
Surficial Sand Time 76
ACKNOWLEDGMENTS 76
LITERATURE CITED 77
APPENDIX?Description of Gores Collected South of the Nova Scotian Shelf
by the Lamont-Doherty Geological Observatory of Columbia University ... 82
INDEX 87
NOVA SCOTIAN
SHELF
Bathymetric Chart
(40-fathom Isobaths)
Fm
4080
120160
50n.mi 200
(km.
FIGURE 1 .?Bathymetric chart of the Nova Scotian Shelf showing localities discussed in text.
1, Cape Breton Island; 2, Northeast Channel; 3, Laurentian Channel; 4, Georges Bank;
5, Browns Bank; 6, La Have Bank; 7} Emerald Bank; 8, Sable Island Bank; 9, Banquereau
Bank; 10, La Have Basin; 11, Emerald Basin; 12, Sambro Bank; 13, The Gully submarine
canyon. Shaded area on shelf (< 146 m deep) was subaerially exposed (partially covered by
ice) during the maximum Pleistocene low stand of sea level (Stanley et al. 1968).
DanielJ. Stanley,
DonaldJ. P. Swift,
Norman Silverberg,
Noel P.James,
and Robert G. Sutton
Late Quaternary
Progradation and
Sand Spillover on
the Outer Continental
Margin Off Nova Scotia,
Southeast Canada
Introduction
The surface of the wide, presently submerged, conti-
nental margin bordering the peninsula of Nova Scotia
and Cape Breton Island, southeast Canada, has been
modified in recent geological time by marked glacial
erosion and deposition and by the effect of sea-
level fluctuations. These two phenomena were to
a large degree responsible for modifications of to-
pography and sediment distribution on the Nova
Scotian Shelf as reviewed in a number of earlier
studies, including those of Upham (1894), Goldthwait
(1924), Johnson (1925), Shepard (1931), and Shep-
ard et al. (1934). More recent marine geological
investigations bearing in one way or another on the
effects of ice and eustatic changes on the Nova
Scotian margin have been reported by Shepard
(1963), Heezen and Drake (1964), Hubert (1964),
Nota and Loring (1964), Cok et al. (1965), Marlowe
(1965, 1969), Rvachev (1965), Silverberg (1965),
Clarke et al. (1967), Conolly et al. (1967), Hubert
Daniel J. Stanley, Division of Sedimentology, Department of
Paleobiology, National Museum of Natural History, Smith-
sonian Institution, Washington, D.C. 20560. Donald J. P.
Swift, Institute of Oceanography, Old Dominion University,
Norfolk, Virginia 23508. Norman Silverberg, Department
of Oceanography, University of Washington, Seattle, Wash-
ington 98105. Noel P. James, Department of Geological
Sciences, McGill University, Montreal, Quebec, Canada.
Robert G. Sutton, Department of Geological Sciences, Uni-
versity of Rochester, Rochester, N. Y. 14627.
and Neal (1967), James and Stanley (1967, 1968),
King (1967a and b, 1969), Medioli et al. (1967),
Stanley (1968), Stanley and Cok (1968), Stanley et al.
(1968), Prest and Grant (1969), Stanley and Silver-
berg (1969).
To date, however, little attempt has been made to
synthesize Quaternary sedimentation on the outer
Nova Scotian margin. The present study is an attempt
to detail petrologic characteristics and stratigraphy of
the uppermost sedimentary sections on the outermost
shelf, slope, and rise off Nova Scotia, particularly
in the area southeast of Sable Island Bank. This
report summarizes and synthesizes the following pet-
rologic and topographic data collected by the authors:
core samples from the Nova Scotian Slope and Rise
and Sohm Abyssal Plain (collected by the Lamont-
Doherty Geological Observatory) south of the Nova
Scotian Shelf (Sutton 1964) ; core samples along a
traverse south of Sable Island Bank collected by
Stanley and Swift on the CSS Hudson in December
1964; cores samples and topographic data collected
off Sable Island Bank (Silverberg 1965) ; cores, bot-
tom sediment grab samples, photographs, and topog-
raphic data gathered from the northern and eastern
margins of Sable Island Bank (James 1966). Syn-
thesis of this material makes it possible to demonstrate
how late Pleistocene to Holocene glacioeustatic events
affecting the Nova Scotian Shelf and mainland left
a marked imprint on the sedimentary cover beyond
the shelf-break. In addition to an interpretation of
SMITHSONIAN CONTRIBUTIONS TO THE EARTH SCIENCES
late Quaternary progradation, particular attention is
paid to postglacial and modern sediment-dispersal
processes that have resulted in the spillover of re-
worked relict (palimpsest after Swift et al. 1971)
sands from the shelf to the slope and rise environments
beyond.
Geography and Topography of the Study Area
General Setting
The continental shelf off the Atlantic coast of Nova
Scotia,1 an area of about 120,000 km,2 is over 700
km in length and extends from the Northeast Chan-
nel northeastward to the Laurentian Channel (Fig-
ure 1). It is a broad northeast-southwest-trending
platform, about 100 km wide off the southwest coast
of Nova Scotia and about 250 km wide off Cape
Breton Island. The shelf is narrowest off the north-
east coast of Cape Breton in the area of St. Paul's
Island. The shelf displays the typical dissected to-
1 The three main continental margin provinces are called
Nova Scotian Shelf, Nova Scotian Slope, and Nova Scotian
Rise. Use of the abbreviated name Scotian Shelf and Scotian
Slope is discouraged to minimize possible confusion with
another glaciated region, the Scotian Sea in higher latitudes
of the South Atlantic.
pography of glaciated margins with deep basins and
linear troughs (Shepard et al. 1934, Holtedahl 1955,
Stanley, et al. 1968). The shelf depth is extremely
variable and locally deeper than 375 m. One point
on Sable Island Bank is actually emergent: Sable
Island, nearly 200 km from the mainland. The con-
tinental shelf differs from the nonglaciated shelf
south of the Gulf of Maine in several respects: it is
considerably wider, displays a much higher degree
of relief and dissection, and becomes shallower, not
deeper, along much of its seaward margin. The
Northeast Channel, a linear, U-shaped depression,
separates the Nova Scotian Shelf from the Gulf of
Maine. The northeastern margin of the Nova Scotian
Shelf is delineated by another broad, northwest-south-
east-trending trough, the Laurentian Channel. The
shelf is widest in the region adjacent to the Laurentian
Channel, and extends for a distance of about 250 km
from the southeast coast of Cape Breton to the sea-
ward edge of Banquereau Bank.
The Nova Scotian Shelf is distinguished by its
pronounced relief and extremely complex topography,
particularly on the eastern half of the shelf (Figure 1).
Morphologic cross-shelf gradients do not approach
the exponential curvature associated with mature
construction, "equilibrium" neritic platforms. Phys-
NOVA SCOTIAN
SHELF
Bathymetric Chart
(40-fathom Isobaths)
)km 1000^^^1829
FIGURE 2.?Inner, central, and outer physiographic provinces of the Nova Scotian Shelf as
defined in Stanley and Cok (1968). S.I.B. = Sable Island Bank. B.B. = Banquereau Bank.
NUMBER 8
iographic provinces of the shelf are well displayed
on Canadian Hydrographic Service Fisheries Charts
4040, 4041, and 4350. The shelf may be divided into
three major physiographic zones that are oriented
roughly parallel to the Nova Scotian mainland (Stan-
ley and Cok 1968) ; these are referred to as the inner,
central, and outer shelf provinces and delineated ^n
Figure 2.
Morphology of the Outer Margin Near
Sable Island Bank
The outer Nova Scotian Shelf region emphasized in
this study is generally broad and flat, and is shallower
to the east where two large banks?Banquereau Bank
and Sable Island Bank?are less than 90 m deep.
On the western section of the shelf, Browns Bank,
La Have Bank, and Emerald Bank are somewhat
deeper and their upper surfaces average about 100 m.
This series of generally flat banks along the outer
continental shelf between Georges Bank, south of the
Gulf of Maine, and the Great Bank off Newfound-
land falls physiographically and geologically within
the Submerged Atlantic Coastal Plain Province. The
bottom relief is slight over most broad shelf bank tops
(slope of 1 to 1000): smooth undulations are due
to the presence of migrating subaqueous sand dunes
(James and Stanley 1968). The shelf actually emerges
on Sable Island Bank as Sable Island, the only such
island on the outer shelf off northeast North America.
Sable Island Bank, a sand-covered platform ap-
proximately 250 km in length, has a maximum width
of about 115 km when using the 90 m (50 fm) isobath
as the bank margin (Figure 3). This Bank, the longest
such feature on the outer Nova Scotian Shelf, lies
between Banquereau Bank (to the east-northeast) and
Emerald Bank (to the west-south west) and covers an
area of approximately 17,000 km.2 Sable Island, at ap-
proximately 60 ?W longitude, 43?50'N latitude, is
located on the eastern margin of the Bank, about 185
km southeast of Cape Canso and 334 km southeast of
Halifax on the Nova Scotian mainland. The Island,
a low (1-20 m), east-west trending, arcuate bar of
sand flats and dunes about 39 km long and 1.5 km
wide, has been recently described (James and Stanley
1967). Extremely gentle gradients east and south of
Sable Island are 1:880 and 1:330 respectively, and
1:280 north of the island (Figure 4). More than
one-half of the Bank lies at depths of less than 55
meters. The western part of Sable Island Bank, known
as Western Bank, is separated from Emerald Bank
by a shallow depression, the Western Gully; Western
Bank lies at depths of about 55 to 90 m.
The morphology and sediments of Sable Island
Bank have been discussed in earlier studies by Upham
(1894), Johnson (1925), Shepard et al. (1934) and
more recently by Marlowe (1965, 1967), Rvachev
(1965), James and Stanley (1967, 1968), Stanley and
Cok (1968), Stanley and Silverberg (1969).
A region of irregular submarine topography, The
Gully Trough, separates Sable Island Bank, Middle
Bank, and Banquereau Bank (Figure 3). The domi-
nant feature of this dissected area is a broad valley
oriented east-west with a tributary-like branch enter-
ing from the north between Middle Bank and Ban-
quereau Bank. The Gully Trough includes isolated
topographic highs rising up to a depth of 110 m and
basins deepening to 200 m. The central portion
deepens slowly from west to east and, on swinging
south off the east bar of Sable Island, deepens abrupt-
ly to form The Gully submarine canyon. This feature
is part of a broad relict dendritic pattern leading
southward toward the main canyon. The fluvioglacial
origin of this depression (see Figure 11) is discussed
in a later section.
The Gully Submarine Canyon
The seaward margin of the Nova Scotian Shelf is
dissected at several localities, but nowhere as much
as in the headward region of The Gully, the large
impressive submarine canyon between Sable Island
Bank and Banquereau Bank. The morphology of The
Gully Canyon, extending well onto the Nova Scotian
Shelf and bordering the eastern margin of the Sable
Island Bank (Figure 3), has been detailed elsewhere
(Marlowe 1967, 1969, Stanley 1967). This depression
is a sinuous, steep-walled, V-shaped submarine valley,
that displays most of the criteria of "type" submarine
canyons (Shepard and Dill 1966).
Marlowe (1964, page 17) in his preliminary study
of this area describes the physiography as follows:
The width of the canyon, as defined by the 400 meter con-
tour, increases from one mile near its head to more than
eight miles at the seaward edge of the continental shelf. The
walls of the canyon are steep, attaining a gradient as high
as 1:2 below the 400 meter contour. In profile, the canyon
is V-shaped. Its course is slightly sinuous and it trends gen-
erally southward, with a deflection to the southeast at about
SMITHSONIAN CONTRIBUTIONS TO THE EARTH SCIENCES
fl 3
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NUMBER 8
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SMITHSONIAN CONTRIBUTIONS TO THE EARTH SCIENCES
the 2200 meter contour. Its longitudinal gradient varies
between 1:18 and 1:9. Side canyons occur along the west
wall.
The Gully divides Sable Island Bank from Ban-
quereau Bank, and its shelfward continuation, the
Gully Trough, bifurcates and forms north- and north-
west-trending troughs in the area of Middle Bank
(Figure 3).
Slope and Upper Rise Off Sable Island Bank
The southeastern margin of Sable Island Bank forms
the east northeast-west southwest trending shelf-break
and slope. The transition from shelf to continental
slope (gradient > 1:40) occurs within a distance of
2 to 4 km (Figures 4, 5). The slope bordering the
seaward edge of the Bank is approximately 240 km
in length and extends from the southwest margin
of the Bank (at about 62?00'W longitude, 43?00/N
latitude) to the Gully Canyon at about 59?07'W
longitude, 43?45'N latitude). A detailed chart of the
slope and uppermost rise south and southeast of
Sable Island Bank (Silverberg 1965, his figure 2) was
contoured at a 50-fm (91 m) interval using soundings
of Canadian Hydrographic Service boat sheets as
a base (a simplified version of this chart contoured
at 100-fm interval is shown on Figure 6). This data
was collected to depths of about 2000 m on the CSS
Kapuskasing in 1960 and 1961. DECCA navigation
(? 1 nautical mile accuracy) was used to control
the position of traverses spaced 2.4 to 3.2 km apart
across the maximum slope inclination. The chart,
prepared by Silverberg at a scale of one inch to ap-
proximately five nautical miles, covers the area 59? 00'
to 62?00'W longitude and 42?30' to 44?00'N latitude
(see inset, Figure 6). The same soundings have been
NAUTICAL MILES
O-i
25
50
150
200
300
Fm.
SABLE ISLAND BANK
BOTTOM PROFILES
INDEX MAP
FIGURE 5.?Bottom profiles (from PDR traces) across the southern and eastern margins of
Sable Island Bank (see inset).
NUMBER 8
XX
N. Mlltt After Silvtrbtrg (1965)
FIGURE 6.?Dissected Nova Scotian Continental Slope southwest of Sable Island (modified
after chart by Silverberg, 1965). Note smooth, nonscalloped slope west of the Kapuskasing
Canyon, in contrast with areas between Sackville Canyon and Sable Island Canyon. Cores
(Sc-1 to Sc-20) are detailed in Silverberg (1965). Depth in fathoms.
contoured in a somewhat more generalized fashion
by the Canadian Hydrographic Service on their Fish-
eries Charts 4040 and 4041 (at a scale of 1:300,000).
The slope and rise immediately adjacent to The Gully
Canyon (Figure 16) have been charted (Marlowe
1967). Also available are several profiles of the slope
(Heezen et al. 1959) and of the rise beyond (Pratt
1967).
The break between shelf and slope (gradient 1:40)
occurs at depths ranging from 110 to 146 m, but
most frequently between 119 to 137 m. The shelf-
break occurs at similar depths along most of the
outer margin between Newfoundland and area south
of New England (Uchupi 1968). Gradients from
1:10 to 1:25 characterize the upper slope (Figures
4, 5). Only three large depressions were found actual-
ly to head on the outer shelf margin at depths of
less than 200 m in the region west of The Gully:
(a) Sable Island Canyon, about 5 km wide at ap-
proximately 60?03"W longitude, 43?35'N latitude
(almost due south of Sable Island) ; (b) Sackville
Canyon, about 4 km wide at 61?09'W longitude,
43?10'N latitude; and (c) Kapuskasing Canyon,
about 3 km wide at 61?17'W longitude, 43?16'N
latitude. A small narrow ridge, approximately 1.5X3
km, extends from the shelf edge toward the slope at
59?15'W longitude and 43?41'N latitude.
The slope becomes considerably dissected below
600 m where more than twenty large north northwest-
south southeast-trending depressions 1 to 8 or more
km across are noted on the charts between 59? and
61 ?W longitude. Cross-sectional profiles parallel to
the slope indicate that most valleys tend to be U-shaped
rather than V-shaped (Figure 7). Gradients along the
top of intervalley ridges are approximately 1:20; that
of valley axes are commonly about 1:12. Submarine
valleys and gullies are straight to slightly sinuous,
and most extend to the base of the slope. Some valleys
appear to lack tributaries but this may be an artifact
resulting from an insufficiently tight sounding net.
Relief of several larger depressions exceeds 500 to 700
m on the upper continental rise, but none of the
valleys appear to extend as far as the Sohm Abyssal
Plain to the south (Pratt 1967). Certain valleys such
as Kapuskasing Canyon, heading near the shelf-break,
appear to die out near the base of the slope. It is note-
worthy that most valleys head at depths greater than
400 to 700 m, and in some cases below 900 m. Large
broad mounds, some of them covering an area exceed-
SMITHSONIAN CONTRIBUTIONS TO THE EARTH SCIENCES
fms
1O0
sgp
fms
D
0L 5
nautical miles
ioq cores (Sc )
vertical
exaggeration
X 5
fms
FIGURE 7.?Profiles across the upper slope showing position of cores on valley floor and margins
and intervalley highs. Geographic location of cores are shown in Figure 6. Depth in fathoms.
NUMBER 8
ing 25 km,2 occur beyond the distal termination of
gullies at base-of-slope depths.
In striking contrast with this scalloped and dis-
sected topography is the smoother more regular slope
(gradient about 1:20) south of Western Bank and
west of 61?30'W latitude. The shelf north of the
undissected slope region (Western Bank) is generally
deeper (60 to 100 m) than the bank area east of
61?30'W latitude. There are two possible explanations
for the high relief on the slope south of Sable Island:
(a) Sable Island Bank may have acted as a sediment
barrier preventing the filling of valleys cut in Pleis-
tocene time or earlier on the slope, or (b) conversely,
Sable Island Bank provided an unusually large vol-
ume of sediment to the slope during the Pleistocene,
and the high rate of sedimentation, in turn, induced
overloading and, eventually, slumping. The latter hy-
pothesis of submarine valley formation seems most
probable. Analyses of seismic profiles [Uchupi 1969
(his figure 4), Emery et al. 1970] and cores (Stanley
and Silverberg 1969) collected on the continental
slope and rise off Sable Island Bank do, in fact, sup-
port a slumping hypothesis. Much of this slumping
took place during Quaternary time, and there is fur-
ther evidence to suggest that this process is still active
in this general area at present. The 1929 Grand Banks
slump which occurred northeast of the study area is
the best documented example (Heezen and Drake
1964).
The boundary between slope and rise is difficult to
establish precisely; the decrease in gradient from 2? to
less than 1 ? is gradual. Downslope profiles show local
breaks in slope near The Gully at about 950, 1300,
and 1700 m (Marlowe 1967); some of these terrace-
like features are probable structural benches. The rise
is somewhat steeper, wider, and deeper (1000 to 1500
fm) than in some areas off the northeast United States
continental margin (Heezen et al. 1959, Pratt 1967).
The combined width of the slope and rise southeast of
the Bank is approximately 180 nautical miles (334
km). The density of sounding notations and available
profiles in water deeper than 1800 m does not, at this
time, permit compilation of a detailed topographic
chart of the lower rise southeast of Sable Island Bank.
Submerged Terraces and Sea-Level Changes
A recent survey (Stanley et al. 1968) of submerged
terraces has identified the position and depth of
notches, benches, and other morphological features
identified as terraces on the Nova Scotian Shelf. Two
groups of terraces are particularly pronounced. The
frequently encountered terrace at approximately 66
fm (121 m) is attributed to the maximum low stand
of sea level during the last glacial stage as indicated by
Curray (1965), Shepard and Curray (1967), and
Milliman and Emery (1968). A lower, well-defined
terrace at approximately 80 fm (146 m), cut just be-
low the seaward edge of the outer shelf and on the
steep northern margins of the outer banks, probably
records one of the maximum lowerings of Pleistocene
sea level. Faunal evidence at this horizon in other re-
gions does not rule out an early Wisconsinan age (J.
Ewing et al. 1960, M. Ewing et al. 1960), but there
is strong indirect evidence to attribute the 80-fm ter-
race to an earlier glacial stage probably the Illinoian,
or third major glacial episode (Donn et al. 1962).
The Nova Scotian Shelf is morphologically so irreg-
ular and highly dissected that even a small change in
sea level would alter markedly the configuration of the
exposed continental platform seaward of the Nova
Scotian mainland (Berger et al. 1966). Even during a
maximum low stand, as recorded by the terrace at
approximately 146 m, several large, deeply incised
areas of the shelf probably remained covered with
lakes or with ice or both. These deep depressions,
shown as the nonhachured sectors on the shelf on Fig-
ure 1, include basins south of Halifax, linear troughs
southeast of Cape Breton, and The Gully Trough, an
extension of The Gully submarine canyon. These lows,
almost certainly related to fluvioglacial drainage and
ice transport (Stanley and Cok 1968) have received
fine-grained sediments from adjacent topographic
highs since the postglacial rise in sea level.
Sediment Distribution Patterns on the Outer
Nova Scotian Shelf
General Textural Composition of the Shelf
It is necessary to review the dominant petrologic
trends on the Nova Scotian Shelf proper in order to
properly interpret mineralogical patterns and facies
changes on the continental slope and rise. The re-
gional grain size-distribution pattern is summarized on
a simplified textural facies map (Figure 8). This fa-
cies map is based on over 1000 samples collected on
10 SMITHSONIAN CONTRIBUTIONS TO THE EARTH SCIENCES
?<?
MUD 1O?A.<0625 mm)
V>v ??- N^? "" " ***** "t
SEDIMENT TEXTURE
(PRELIMINARY SURVEY)
SABLE ISLAND
.10%
SAND (.
0 10 30 60
NAUTICAL MILLS
FIGURE 8.?Generalized regional size distribution of surficial sediment on the Nova Scotia Shelf
(Stanley and Cok 1968).
the shelf (Stanley and Cok 1968, their figure 4). A
textural classification, modified after Folk (1954), is
used in which three end-members are recognized:
gravel (fraction coarser than 2.0 mm); sand (fraction
from 0.0625 to 2.0 mm) ; and mud (fraction finer
than 0.062 mm, including both silt and clay). Inter-
mediate textural admixtures consisting of mud and
sand, of gravel and sand, and of gravel, sand, and
mud are also depicted on Figure 8. The resulting dis-
tribution of textural types brings out the pattern of
"outward increasing gradation," e.g., the offshore
coarsening of sediment described by Shepard et al.
(1934). Regional trends are neither strictly parallel,
nor normal to the coast of Nova Scotia, and the over-
all patchiness of sediment distribution indicates that
the shelf is by no means "at grade" or in equilibrium
with present hydrographic conditions. The shallow
outer banks are covered largely by sand or sand-gravel
admixtures; deep basins and troughs on the center
shelf are commonly floored with mud, and mud-sand
admixtures; and much of the remainder of the inner
and mid-shelf regions, particularly at intermediate
depths, are covered with gravel-sand-mud admixtures
that are till-like in textural composition.
The textural distribution pattern suggests that grain
size bears some relation to (a) geographic position
and distance from shore, and (b) depth. The correla-
tion of grain size with depth is largely a function of
recent erosional and depositional processes on the
shelf. No major rivers, for instance, drain the main-
land of Nova Scotia, and little sediment is provided
to the shelf, with the exception of some fine-grained
material that bypasses river mouths (Stanley 1968).
Thus, much of the present sedimentary pattern re-
flects relict distribution ("remnant from a different
earlier environment" according to Emery 1952, page
NUMBER 8 11
1105), subsequently modified by Holocene processes
of reworking. The distribution of gravel-sand-mud ad-
mixtures of the upper sediment surface indicates, for
instance, the widespread cover of poorly sorted di-
amictites transported onto the shelf by glacial ice.
The dominance of sand on much of Emerald Bank,
Sable Island Bank, and Banquereau Bank is probably
related to (a) the buildup of glacial out wash deposits
at the frontal ice contact areas on the northern mar-
gins of these banks, and to (b) the subsequent removal
by winnowing of finer grade fractions from originally
more poorly sorted deposits. That much of these
"fines" have probably been redeposited landward in
deep areas of the center shelf region north and north-
west of the banks following the last rise in sea level
was suggested in an earlier study (Stanley and Gok
1968). We shall show in subsequent sections that some
of the silt and clay winnowed from bank tops was also
redeposited seaward on the continental slope and in
canyon-subsea fan complexes during the late Pleisto-
cene and early Holocene. This seaward dispersal of
fines began prior to the time when sea level began to
cover the bank areas and migrate landward across the
shelf. Thus, as a result of this transgression, recently
transported fine-grained sediments are concentrated
over relict (Pleistocene) sediment in inner and center
shelf regions and beyond the shelf-break, while coarser
lag deposits remain on the outer banks, including
those on the eastern half of the Nova Scotian Shelf.
Details of the textural distribution on Sable Island
Bank are available elsewhere (James and Stanley
1968).
The lateral variation of sorting observed on the
Nova Scotian Shelf (Figure 9) substantiates these
conclusions. A scale showing the relative degree of
sorting is based upon the total number of phi classes
that make up the size distribution of a sample at each
station. Thus, the fewer the number of size classes, the
SABLE ISLAND
Q) V. WELL WELL MODERATE POOR V POOR
BOULDER CONCENTRATION O 1,0 30 60NAUTICAL MILES
FIGURE 9.?Regional variability of sediment sorting and distribution of boulder concentrations
on the Nova Scotian Shelf (Stanley and Cok 1968).
12 SMITHSONIAN CONTRIBUTIONS TO THE EARTH SCIENCES
better the sorting, and vice versa. The best sorted
sediments are those located on the shallow outer banks
(particularly on the eastern half of the shelf), areas
covered predominantly with sand. Areas displaying
the poorest degree of sorting occur in elongate belts
on the inner and center shelf regions; these elongate
areas generally are composed of gravel-sand-mud
admixtures.
Areas of boulder concentration on Figure 9 are
generally closely related with the distribution of linear
belts of poorly to very poorly sorted sediment. This
"boulder-diamictite" association clearly defines major
dispersal trends. These trends, reflecting moraines
and boulder trains, extend from the present coastline
toward the center shelf and outer shelf edge on the
western half of the Nova Scotian Shelf. Other petro-
logic criteria have also resulted in the delineation of
certain of these glacial moraines on the shelf (King
>* Glacial stria
^" Drumlm etc.
?*/.???. Esker ? tunnel valley
**+y End moraine
I
FIGURE 10.?Glacial features indicative of ice flow on Nova Scotia and adjacent areas patterns
(Prest and Grant 1969, their figure 3 with the authors' permission).
NUMBER 8 13
1969). Moderate to very poorly sorted sediments in-
dicative of glacial ice transport predominates on the
eastern half of the shelf north of Emerald Bank, Sable
Island Bank, and Banquereau Bank.
General Mineralogical Composition of Surficial Shelf
Sediments
The relation between mainland tills and sediment off-
shore has been demonstrated by plotting the distribu-
tion of lithic (rock) fragments and heavy minerals in
the sand-size fractions and by examining the composi-
tion of the pebbles and boulders in the coarse fraction
(James and Stanley 1968, Stanley and Gok 1968).
The sum of mineralogical data, evaluated in light of
the textural and morphological data, also serves to
delineate the coverage of glacial deposits on the shelf.
The mineralogical composition of inner shelf sedi-
ments is similar to that of glacial drift on the mainland.
Much of the coarse fraction is composed of Paleozoic
material of the type cropping out on Nova Scotia. The
regional distribution indicates a linear belt approxi-
mately 60 km wide that is roughly parallel to the
mainland and is rich in rock (lithic) fragments (10 to
over 75 percent rock fragments in the 0.6 to 1.0 mm
fraction; 5 to 25 percent in the 0.4 and 0.6 mm frac-
tion ). Heavy mineral assemblages distinguished on the
mainland beaches (Nolan 1963) can be correlated
reasonably well with those on the inner and center
shelf regions. Glacial tongues that traversed the main-
land in south and southeast directions (and toward
the northeast in sections of Cape Breton) according to
Goldthwait (1924), Grant (1963) and Prest and Grant
(1969, their figure 3) undoubtedly continued beyond
the present coast. Generalized ice flow trends on the
Nova Scotian mainland are depicted on Figure 10.
Diagnostic heavy minerals (such as augite) or rock
fragments (granite pebbles from the Cobequid Moun-
tains) are useful for pinpointing specific source loca-
tions. Linear troughs and channels carved into the shelf
(Stanley et al. 1968) indicate the general transport
path of the glacial tongues (Figure 11).
Reddish brown tills, containing iron stained grains,
are found on the Atlantic coast of Nova Scotia, and
it is likely that they extended further onto the shelf.
These mainland tills were derived from source areas
(Carboniferous and Triassic) located in Bay of Fundy,
Prince Edward Island, and New Brunswick regions.
FIGUGE 11.?Probable major glacial and fluvioglacial drainage patterns on northeastern sector of
the Nova Scotian Shelf (Stanley and Cok 1968).
14 SMITHSONIAN CONTRIBUTIONS TO THE EARTH SCIENCES
Heavily stained quartz (Stanley and Cok 1968, their
figures 9, 10) and lithic grains of sand size, so
abundant on the outer banks, are also valuable pro-
venance indicators. It is almost certain that much of
the glacial and fluvioglacial materials preserved on
the outer banks originated in Carboniferous and
Triassic terrains lying several hundreds of kilometers
to the northwest. Many of the pebbles and cobbles col-
lected on Sable Island Bank have been identified as
Paleozoic in origin of the type cropping out on Nova
Scotia (James and Stanley 1968).
A relatively anomalous mineralogical province
occurs on the central shelf northwest of Sable Island
Bank. The presence of nodules, quartzitic and glau-
conitic sandstone fragments, varieties of corroded
garnet, and other heavy minerals of the type not found
elsewhere on the shelf suggests a supply from local
bedrock source areas exposed on this sector of the
shelf. It is conceivable that such isolated ledges include
Tertiary and Cretaceous strata (occasionally dredged
by scallop fisherman) that were eroded by moving ice.
Evidence of Cretaceous strata on the shelf has, in fact,
been cited by Dall (1925), Stephenson (1936), King
et al. (1970), and others. The seaward dipping pre-
Pleistocene Coastal Plain deposits forming the sub-
merged cuestas on the Nova Scotian shelf are evident
in high-resolution subbottom seismic profiles (Uchupi
1969).
Mineralogical data provide additional support for
the conclusion tljat Pleistocene glacial tongues at one
time (although not necessarily during the Wiscon-
sinan) extended seaward as far out as the shelf edge
on the southwestern part of the shelf and as far as the
Sable Island Bank-Banquereau Bank regions on the
northeastern shelf. A paleogeographic reconstruction
displaying the zone of ice coverage is shown in Figure
12. This schema shows that a considerable amount of
ice-borne glacial marine sediment was rafted onto
the slope and rise beyond by bergs breaking off the
glacial front during glacial stages. Bottom photographs
and dredge hauls (Cok 1970) on the slope and rise
show that this did take place. In particular, photo-
graphs collected during the search for the submarine
Thresher, whose hull bottomed at the base of the slope
southeast of the Northeast Channel (Brundage et al.
1967) reveals concentrations of large boulders, some
over 3 m in diameter, which were undoubtedly initially
ICE COVERAGE
DURING MAXIMUM
ADVANCES
FIGURE 12.?Ice coverage on the Nova Scotian Shelf during the Pleistocene, as interpreted
from sediment distribution and topography (Stanley and Cok 1968). 1, Probable extent of
glacial ice during maximum advances; 2, outwash area; 3, area of berg-borne sediment.
NUMBER 8 15
nt oxw
<//////'////,'//////,'/''///''///'''"//<'''///' '/''//A
ICE COVER
OPEN WATER
CURRENTS
MAIN WIND DIRECTION
DURING BREAK-UP
^'//y'/y////////'
NAUI MILES
S1*W 4/N 57*W 45*N
FIGURE 13.?A, Maximum ice-coverage and dominant surface current patterns on the eastern
portion of Nova Scotian Shelf during ice breakup in the spring, B, Major sedimentological
provinces on the northeastern Nova Scotian Shelf (explanation in text). Note that the sector
of ice-rafted material (B) coincides with zone of seasonal ice-coverage shown in A. The outer
banks, zones of intense erosion and textural unmixing, are blanketed by a surficial sand and
gravelly sand lag.
16 SMITHSONIAN CONTRIBUTIONS TO THE EARTH SCIENCES
transported into deep water by ice-rafting during
glacial stages.
Attention has also been called to the importance of
recent (Holocene) ice transport of sediment as a result
of seasonal breakup and movement of ice from the
Gulf of St. Lawrence (Stanley and Cok 1968) onto
the Nova Scotian Shelf (compare the ice distribution
pattern in Figure 13A with area B in Figure 13B) . This
addition of modern ice-rafted material on the shelf
edge near Sable Island Bank and Banquereau Bank
should not be overlooked. Postglacial to modern ice-
rafting would probably also account for thin discon-
tinuous patches of fine to coarse material on the slope
and rise.
General Description of Slope and Rise Sediments
Cores Examined
Recognition of sedimentary facies on the continental
slope and upper rise off Nova Scotia is based on a
study of four sets of cores discussed in this and follow-
ing sections:
(a) 20 piston cores (Figure 14) collected on the
100
200
300
400
500
t_
ou
600
Q.
Q
700
Topographic
Htghs
Valley
Sides
Valley
Axes
Flat
Terrain
15-2 13 20 15 9 11 12 3 7 19 14
Core Numbers (Sc-)
8 5 1 10 17 4 16 18
FIGURE 14.?Cores collected on upper and middle slope southeast of Sable Island Bank (Silver-
berg 1965). Dark cross-hatchure pattern depicts reddish-brown facies; oblique hatchure depicts
olive gray facies; stipples denote uppermost sandy facies.
NUMBER 8 17
slope adjoining the southern margin of Sable Island
Bank and described by Silverberg (1965).
(b) 5 piston cores (Figure 15) collected by Stanley
and Swift on the CSS Hudson in 1964, along a north-
south transect, from the slope due south of Sable
Island to the rise.
(c) Cores (Figure 16) collected by Marlowe (1964)
in the vicinity of The Gully Canyon and adjacent
slope and detailed in James (1966), Stanley (1967)
and Stanley and Silverberg (1969).
(d) 30 cores (Figure 17) collected by the Lamont-
Doherty Geological Observatory on the slope and rise
off Nova Scotia, and examined by Sutton (1964).
Selected Lamont-Doherty cores collected in this area
have also been described by Ericson et al. (1961),
Hubert (1964), Hubert and Neal (1967, and Conolly
etal. (1967).
Only those lithologic aspects of cores pertinent to
this study are presented in this paper. Detailed graphic
and photographic logs of most cores (a) and (c) are
available in the references cited above. Logs of cores
(d), also available from the Lamont-Doherty Geolog-
ical Observatory core collection library and from the
National Oceanographic Data Center, are included in
the Appendix.
Four Outer Continental Margin Fades
Earlier studies have shown that the predominant
surficial textural type on the slope and rise is mud
(silt and clay, largely of terrigenous origin) with vary-
ing, but minor, amounts of gravel, sand, and coarse
silt. Thin layers of clean sand, and occasionally gravel,
are also noted. Muddy sediments generally display
either an olive gray or a reddish-brown coloration.
Cores Sol to Sc-20 (Figure 14) and Hud 30-9 to
Hud 30-14 (Figure 15) display both sediment types
on the slope proper and in The Gully Canyon.
The olive gray mud generally overlies the brown
facies (Heezen and Drake 1964; Conolly et al. 1967).
The contact between these two sediment types can be
sharp or gradational. Interbedded olive gray and
brown sediments are noted in some cores. Olive gray
mud, generally less than 2 to 3 m thick, covers the red-
dish-brown unit on much of the upper- and mid-slope
region. Occasional thin partings of sand occur within
the gray, but more commonly within the brown facies.
A third sediment type noted in several cores on the
slope is a relatively clean sand unit that occurs in thin
laminae (2 to 15 cm) at the uppermost surface. A
fourth facies, observed on the upper rise (cores Hud
30-9A, B), is a pale yellowish-brown mud that covers
the reddish-brown facies.
A simpified sediment distribution chart of the slope
based on the coring program is shown in Figure 18.
Both olive gray mud and brown mud and sand-silt-
mud facies appear to be irregularly distributed across
the slope. The patchy distribution is a function of
topography in the sample locality. On the upper slope,
for instance, brown sediment was recovered only near
the tops of ridges and along relatively flat sections of
the slope. Coring suggests that (a) deposition of the
olive gray facies has been greater in valleys than on
intervalley highs, or (b) that non-deposition or erosion
and removal of the gray facies has been more im-
portant on topographic highs, or (c) both factors are
in force. One core, Sc-16, collected on a relatively
undissected sector of the upper slope provides a re-
presentative section. Core Sc-16, penetrating both
olive gray and brown facies, serves as a base upon
which to compare the thickness of the gray sediment.
A surficial third facies of clean to muddy sand layers
is more frequently cored on topographic highs.
The lithological logs of the CSS Hudson short pis-
ton cores (Hud 30-9A, -9B, -11, -13, and -14) col-
lected south of Sable Island Bank are shown on
Figure 15. The most obvious features are summarized
as follows:
(a) The slope core (Hud 30-14) penetrated olive
gray, silty to clayey mud,
(b) The base-of-slope core (Hud 30-13) displays
the coarsest texture (sand, silt, and pebble fraction
present with predominant mud) of the five cores and
is brown in color,
(c) The rise core (Hud 30-11), also brown, consists
of somewhat fewer coarsely textured horizons,
(d) The two lower rise cores (Hud 30-9A and -9B)
are considerably finer grained than (b) or (c), and
the uppermost (tan to light yellow-brown) sections
are lighter in color than the brown and reddish brown
material in (b) and (c).
The cores collected in The Gully Canyon area by
Marlowe (1964) are also variable in texture (mud,
sand, and pebble fraction) and color (gray, brown,
and mixtures thereof). They present color and tex-
tural characteristics comparable to those in upper
Nova Scotian Slope cores collected by Silverberg
(1965). The position and logs of cores collected by
18 SMITHSONIAN CONTRIBUTIONS TO THE EARTH SCIENCES
LU
COcc
tr
LU
o
LU
CO
tro
LU
CO
en
LUQ_
a.
LU
CO
ro
B
3 8. 3 ?ja* S |
??111
? g3 3
fi 1
P ?"
LU
O
LU
CO
<
LU
a
I s
CM o m
Sa313WllN33 Nl31V0S
OO
?c
? S
NUMBER 8 19
000
A-173-8
? CORE
o SNAPPER SAMPLE
A LAMONT CORE
? LONG CORE
(DEPTH IN FATHOMS)
DJS 35 59?00'
FIGURE 16.?Cores in the vicinity of The Gully Canyon
(collected by Marlowe 1964, and others).
Lamont-Doherty Geological Observatory and examin-
ed by Sutton (1964, this study) are shown on Figure
17.
Physical and Biogenic Structures in Slope Cores
The occurrence of abundant thin laminations, sandy
strata, isolated pebbles, and interbedded gray-and-
brown sediment types and the lack of petrographic
homogenity clearly indicates that sedimentation rates
have fluctuated considerably on the outer margin in
the study area. Processes responsible for the down-
slope transfer of terrigenous sediments have also varied.
The presence of laminated (current-produced) sand,
silt, and mud units, isolated (ice-rafted) pebbles
(Stanley and Cok, 1968, their figure 12) and bould-
ers (Brundage et al. 1967) in mud, contorted
(slumped) strata, and graded (turbidite) beds (Stan-
ley 1970) are obvious and frequently observed struc-
tures on the Nova Scotian Slope. Bioturbate struc-
tures (produced by burrowing organisms) account
for still another group of structures commonly visible
in cores.
In comparison, cores that consist largely of clay and
fine silt, when split, appear homogenous and generally
do not reveal internal structures of either sedimentary
or organic clearly. X-radiography, a technique that
reveals features not apparent to the naked eye, was
used in the inspection of both split (method in Bouma
1964) and unsplit cores (Stanley and Blanchard
1967). Internal structures observed in cores Sc-1 to
Sc-20 can be grouped broadly into the following
categories:
(a) Regular layering: alternating light and dark
(dense and less dense) bands continuous across the
core section.
(b) Irregular layering: discontinuous, often lens- or
pod-shaped, bands.
(c) Indistinct layering: bands which are only faintly
distinguishable, or which show gradational contacts.
(d) Mottling: pods or irregular bodies of contrast-
ing density which exhibit no preferred orientation in
the core. These may be indistinct, displaying no clear
boundary with the other material in the sediment, or
they may be distinct, with sharp boundaries.
(e) Flow-in: undulating or contorted, vertically
oriented pattern found near the lower sections of some
cores. Flow-in structures are an artifact of coring, i.e.,
sediment is drawn into the core liner as the coring
device is raised from the bottom. Flow-in commonly
occurs in instances where the core barrel did not com-
pletely enter the sediment.
Internal structures observed in cores Sc-1 to Sc-20
are depicted on Figure 19. It is apparent from this
figure that no one internal structure is restricted to a
specific sediment facies, although assemblages of
primary structures are of some use in distinguishing
particular sediment types.
The surface sand facies is easily distinguished.
Radiographs show that these sands contain bands of
closely spaced fine mottles (burrows in some cases)
with scattered, distinct, large patches (aggregates of
granules and small pebbles).
The olive gray, muddy sediment type is character-
ized by a general scarcity of internal structures. Some
cores show sections of regular and irregular layering
20 SMITHSONIAN CONTRIBUTIONS TO THE EARTH SCIENCES
SOHM ABYSSAL PLAIN
FIGURE 17.?Gores on the Nova Scotian slope and rise and in the Sohm Abyssal Plain collected
by Lamont-Doherty Geological Observatory and examined by R. Sutton (lithologic description
and appropriate Lamont core number are provided in the Appendix).
NUMBER 8 21
BANQUEREAU
eraiized Distributionof Late Quaternary Sediments on
Outer Nova Scotian Continental Marain.
[Solocene relict sediments on outer banks;
'spill-over fades,on slope and rise.
Largely Holocene gray-green facies,
on slope.
Largely Holocene light gray-brown,
hemipelagic facies, on rise.
Pleistocene brown glacio-marine facies
exposed, on slope and rise.
Pleistocene relict glacial and fluvio-
lacial facies,on shelf. ""
FIGURE 18.?Map showing generalized distribution of late Quaternary surficial sediments on
the outer continental margin off Nova Scotia (Stanley and Silverberg 1969).
(e.g., Sc-5, Sc-8, and Sc-15) but for the most part,
the olive gray facies consists of long sections of homo-
genous sediment. The widely scattered, indistinct, large
and small mottles and irregular layers (e.g., Sc-1, -2,
-3, -7, and -10) are probably the result of bioturbation.
The major characteristics of the brown sediment
type are a widespread occurrence of distinct mottles
(in some cases, pebbles), and a sediment column com-
prising numerous, thin alternating zones of varying
texture and stratification. Regular layering is most
extensive in core Sc-4, and distinct mottling is noted
at the base of core Sc-16. The longest section of brown
sediment penetrated (core Sc-9) shows the diversity
of lithologies characteristic of this facies.
In muddy sediments the burrowing and feeding ha-
bits of benthic fauna can completely modify physically
produced stratification features by shifting and rework-
ing the sediment. Moore and Scruton (1957) noted
22
neterst
5u
c
5
Dep
Core
CORE Sc-
100
150
200
250
1
'i',
|
m'
<*>
2
0
SL-
?
3
%
SMITHSONIAN CONTRIBUTIONS TO THE EARTH SCIENCES
8 9 10 11 12 13 14 15 15-2 16 17 18 19 20
? ' 1
"' >:
OKIc?
1 a
:,..,
??'
sa
* *
? ????
? ^
".'?at'--
??'.
1
?
??v'
MOTTLES LAYERS
coarse fine regular irregular
distinct Eg E3 5 59
indistinct Q ED ?3 SB
FLOW H0M0-
IN GENEOUS
lisa ?
FIGURE 19.?Nova Scotian Slope core (Sc) logs showing sedimentary and biogenic structures
as observed in core photographs and X-radiographs.
that a complete gradation (from regular and irregular
layering, to distinct and indistinct mottling, to homo-
geneous sediment) can develop depending upon the
rate of sedimentation, sediment type, and intensity of
faunal activity. Reversal of this process, i.e., the layer-
ing of an originally near-structureless sediment section
by faunal activity, can also be induced. Preservation of
original primary sedimentary structures generally
occurs in areas where sedimentation rates are parti-
cularly high or where bioturbation by mud-feeding
organisms is uncommon or both.
Interpretation of slope sediments in the light of
these observations indicates that the olive grey sedi-
ment type was deposited rather slowly. The occurrence
of indistinct large mottles indicates that the process of
homogenization did not go to completion. The fine
nature of the regular layering preserved in some core
sections suggests that there were periods of less intense
bioturbation or somewhat higher rates of sedimenta-
tion.
The disruption of layering is also apparent in the
older brown sediment. However, preservation of
thicker sections of stratified layers indicates that rates
of sedimentation were higher during deposition of
this facies. The variable character of the preserved
strata, which include sandy layers, irregular and re-
gular layering, and indistinct mottling, is evidence
that the rate of deposition of the brown sediment was
not constant, but apparently fluctuated considerably.
The occurrence of sand and pebbles in the brown
sediment, as noted on the radiographs is another
significant difference between the two types of sedi-
ment. The higher sedimentation rate and variable
nature of the brown sediment is also confirmed by a
textural study, as demonstrated in following section.
Sediment Sequences on the Lower Rise
and Abyssal Plain
The following is a summary of descriptions of 30
cores collected on the slope, rise, and Sohm Abyssal
Plain south of the Nova Scotian Shelf.
A typical sedimentation rhythm, or sequence, in
Sohm Abyssal Plain cores and in certain cores of the
Nova Scotian Lower Rise consists of the following:
TOP 1. Gray foram lutite
2. Pale red foram lutite, grades
down to darker red at base
3. Mottled red lutite
4. Red lutite; bedding absent;
forams and mottling rare
(Te2)
NUMBER 8 23
BOTTOM
5. Laminated silt (Td)
6. Silt with current ripples, clay
blebs, and forams (Tc)
7. Silty sand usually laminated (Tb)
8. Sand (Ta)
The symbols closely follow those proposed by Bouma
(1962). The lower sand (Ta) is interpreted as the
lower portion of a turbidite, indentified by relatively
poor sorting, absence of bedding, and rarity of forams
and burrows (Figure 20). Rapid emplacement would
best explain this combination of features. The silty
sands (Tb) and rippled and laminated silts (Tc-Td)
represent the fining upward and progressive changes
in the flow regime expected during the later phases
of turbidity current flow (Figure 21). The red
lutite unit (Tei-Te3) is interpreted as the fallout of
finer particles suspended in the water following the
emplacement of the coarser sediment. This fallout,
rapid at first (Tei), declines progressively (Te2) after
several hours (or days) so that the sedimentation rate
is low enough to permit reworking by burrowers
(Figures 22, 24). Red lutite contribution gradually
FIGURE 20.?Brown sandy silt (Ta). Locality 28 (Lamont
core V7-7O) at 322 to 330 cm depth in core.
FIGURE 21.?Cross-laminated, fine-grained, foram-rich sand
(Tb-Tc). Locality 24 (Lamont core V7-38) at 438 to 440
cm depth in core.
decreases (Tea) so that the nonturbidite contribution
(Te4) takes over as an increasing percentage of the
total contribution (Figures 25). The gray foram lutite
is interpreted as a nonturbidite accumulation. The
increased foram content (Te2-Te4) is cited as evidence
of this decreasing sedimentation rate.
Sediment sequences in the lower rise tend to be
thicker (100 cm or more) and contain more sand and
silt than those of the abyssal plain (Figure 17). The
southward thinning of the sequences is cited as
evidence of (a) the northward source of the Ta-Te3
units and (b) dominant dispersal patterns toward the
south. Just north of the New England Sea Mounts,
thick gray foram lutites may have originated by pro-
cesses other than turbidity currents. In some places,
numerous silt laminae and beds are associated with
Te2-Te3 units suggesting that bottom currents, win-
nowing sediment, have removed some of the finer
fractions. It is conceivable that this reworking would,
over a period of time, produce a carpet or veneer of
grains too coarse to be moved by bottom currents.
This lag deposit would, in essence, form a protective
cover over finer grade sediments beneath it. Resu-
spended fines are probably transported by bottom
currents some distance from the initial site of Ta-Td
bottom current resuspension would account for the
turbidite deposition. This combined turbidity current-
24 SMITHSONIAN CONTRIBUTIONS TO THE EARTH SCIENCES
FIGURE 22.?A, Interbedded red lutites and laminated silts (Td-Tei). Locality 29 (Lamont core
V16-213) at 268 to 272 cm depth in core, B, Locality 1 (Lamont core A164-46) at 206 to
215 cm depth in core.
presence of red lutite laminae in many parts of the
Sohm Abyssal Plain.
The frequent absence of burrowing in sands and
silts could be interperted as a preference of the orga-
nisms for lutite over sands and silts rather than an
indicator of sedimentation rate. This hypothesis, how-
ever, is dismissed because burrowed silt units occur on
the upper rise (Figure 26).
Many of the sedimentation cycles, or rhythms, are
incomplete. Those in the more distal parts of the
abyssal plain lack the lower Ta or Ta-Tb sections.
These deposits are thus considered to be the finer
grained deposits from a weaker, diluted current. Else-
where, on the other hand, upper units may be missing.
In some cores virtually every rhythm is truncated at
the top, suggesting greater current activity than at
nearby localities where the rhythms are virtually com-
plete. Local variations of bottom topography might
explain these differences. Where coarser sediments
comprise the upper part of the rhythm, and subdivi-
sions are not clear-cut, only the symbol "Te" is used
(Figure 23).
Textural Analyses of Outer Margin Sediments
Outer Shelf Near Sable Island Bank
Following sections summarize petrographic studies of
core and bottom grab samples collected on the outer
continental margin southeast of Nova Scotia. A total
of 114 samples (Figure 3) collected on and in the
direct vicinity of Sable Island Bank were examined
(James 1966, James and Stanley 1968). Size measure-
ment was obtained with a rapid sediment analyzer
(Schlee 1966a); a size interval of }4</> was selected
and textural parameters including mean, sorting,
skewness, and kurtosis were calculated using the
formulae of Folk and Ward (1957).
Sand is the dominant textural grade covering most
of the banks (Figures 8, 29). Mean grain size is inde-
pendent of depth. In general, medium- to coarse-
NUMBER 8 25
FIGURE 23.?Poorly sorted silt with faint burrows (Te).
Locality 28 (Lamont core V7-7O) at 15 to 22 cm depth
FIGURE 25.?Gray foram-rich lutite with faint mottling due
to burrowing (Te3-Te4). Locality 1 (Lamont core A164-46)
at 15 to 20 cm depth in core.
FIGURE 24.?Micro-mottling in red lutite (Te2). Locality 24
(Lamont core V7-38) at 108 to 112 cm depth in core.
grained sand occupies the area north of a line running
east northeast-west southwest across the bank through
Sable Island; south of the line, sand is fine to very fine
grained. The best sorted sand (very well to well sorted
according to Folk and Ward 1957, and Folk 1966)
forms a broad band trending east-west across the
center of the bank, whereas poorly sorted sediment is
present north and south of Sable Island (Figure 30).
Finely skewed sediment covers the western part of the
bank and an area east of the east terminal bar, and
coarsely skewed sediment is present directly south and
northwest of Sable Island.
Textural patterns present on the island continue
offshore (James and Stanley 1967). Sand north of the
island is coarser than that to the south. Best sorted
sand is present off the southeastern beach and east bar.
Finely skewed sediment dominant on the southwestern
part of the island is also present seaward off the beach.
Sorting has been found to be more sensitive to environ-
ment than either mean grain size or skewness; sand in
26 SMITHSONIAN CONTRIBUTIONS TO THE EARTH SCIENCES
FIGURE 26.?Brownish gray clayey foram-rich silt with mottl-
ing (Te3-Te4). Locality 27 (Lamont core V-67) at 10 to
16 cm depth in core.
FIGURE 27.?Recumbent fold structures in slumped silty
lutite. Locality 19 (Lamont core SP12-1) at 120 to 126 cm
depth in core.
the predominantly eolian environment (dunes cover
much of the island) is consistently better sorted than
beach and offshore sand.
Textural parameters of the sediment on Sable Island
Bank are, in general, interrelated: coarse sand gener-
ally is poorly sorted and coarsely skewed; fine sand
commonly is well sorted and finely skewed. The local
variations superimposed on this pattern can be used to
determine directions of sediment movement.
Gully Trough and The Gully Canyon
The size distribution of samples collected in The Gully
Canyon (Figure 31) and its shallow extension, the
Gully Trough (Figure 32) on the shelf, are plotted.
Most samples are admixtures of sand, gravel, and mud
as shown on a Folk (1954) textural triangle.
In the Gully Trough the textural distribution ap-
pears to be depth dependent. At depths of less than 80
m sediment is dominantly sand; samples below 180 m
in the trough contain a predominant mud (silt and
FIGURE 28.?Slumped silty lutite with darker zones of lutite
cut by burrows. Locality 19 (Lamont core SP12-1) at 102
to 106 cm depth in core.
NUMBER 8 27
61OQ
44
00
43
30
6100 5900
SABLE ISLAND BANK
MEAN GRAIN SIZE (M7 )(After Folk ond Word , 1957)
 z
I I <C 10 COARSE
\fii'?\ 1,0 - 2.0 MEDIUM SAND
|..'1*| 2.0 " 3.0 F'NE SAND IN I UMTS
t-~-] ^>3.0 VERY FINE SAND
FIGURE 29.?Regional variation of mean grain size of surficial sediments on Sable Island Bank
and adjacent area (James and Stanley 1968).
6100 30 6000 30 5^00
6100 5900
SABLE ISLAND BANK
SORTING
(After Folk ond Word,1957)
I I <O35 V.WELL
0.35-0.5 WELL SORTED
0.5 - 0.71 MODERATELY WELL
>0.71 MODERATELY
FIGURE 30.?Relative sorting (calculated after Folk and Ward 1957) of sediment on Sable
Island Bank (James and Stanley 1968).
28 SMITHSONIAN CONTRIBUTIONS TO THE EARTH SCIENCES
THE GULLY CANYON
(TEXTURE)
GRAVEL
MUD SAND
FIGURE 31.?Textural distribution of surficial sediment in The Gully Canyon (classification
after Folk 1954). See Figures 3 and 16 for sample location.
clay) fraction. The textural type is generally more
varied between 80 and 180 m: sand and gravel occur
between 80 and 140 m; sand, gravel and mud between
120 and 160 m, and sand and mud between 160 and
180 m. There is some overlap of these textural zones.
Small bank tops and isolated hummocks within the
Gully Trough are covered with sand. Intermediate
depths contain sand and gravel with or without a mud
admixture, and below 160 m, as well as in isolated
basins, mud is prevalent. Sediment on the western sec-
tion of this region, between Banquereau Bank and
Sable Island Bank, comprises gravel to a depth of 175
m and clean sand in water deeper than 260 m.
A preliminary examination of cores collected in
The Gully Canyon indicates that sediment consists
mainly of sand and mud with minor amounts of
gravel and cobble-size particles (Marlowe 1964).
There appears to be a general increase in mud (silt
and clay) content with increasing depth. Muddy sand
predominates at a depth of 900 m on the east wall of
the canyon and again at a depth of 2,860 m in the
axis. Glean sand is found at 1,400 m in the axis of the
canyon.
Samples analyzed in detail (James 1966) and
plotted on a Folk (1954) textural triangle show a
local variation superimposed on the general trend of
NUMBER 8 29
GULLY TROUGH
(TEXTURE)
59*00'
)*?^
FIGURE 32.?Textural distribution of surficial sediment in the Gully Trough north of Sable
Island Bank (classification after Folk 1954). See Figure 3 for location.
25-
clO-
Sc-I n Sc-2 Sc-3 Sc-4
H 1?1 1 1 ++ -I 1"5-2-10123 -2-101 23 -2-1 012 3  -2-10123
phi units
25-
Sc-5 n Sc-7
10-
Sc-I I
,, -H r
Sc-I3
FIGURE 33.?Grain-size histograms of surficial sediment collected with a bottom grab at core
locations on the upper and middle continental slope off Sable Island Bank.
30 SMITHSONIAN CONTRIBUTIONS TO THE EARTH SCIENCES
80
50
10
0.1
phi units
FIGURE 34.?Cumulative coarse fraction size curves of surficial sediment collected with a
bottom grab at core locations on the upper and middle continental slope off Sable Island Bank.
SLOPE-RISE
TRAVERSE CORES (HUD)
Cloy UPPER SLOPE CORES (SO
(after SHmbwg.1968)
* BROWN
* GRAY
* SURFACE SAND
Clay
Sand
FIGURE 35.?Size distribution of upper and middle slope (Sc) cores are shown on left textural
triangle (classification of Shepard 1954). Triangle on right shows textural distribution of cores
collected on slope-rise traverse (see Figure 71).
NUMBER 8 31
decreasing grain size with increasing depth (Figure
31). Sable Island Bank above 200 m and the upper
reaches of The Gully Canyon are composed primarily
of sand or sandy gravel. Most of the northern portion
and the west wall of the canyon are covered with
muddy sand. A zone of sandy mud drapes from the top
of Banquereau Bank, down the east wall, and across
the mouth of the canyon. Mud is predominant west of
the axis near the mouth of the canyon.
Continental Slope South of Sable Island Bank: Upper
Slope Samples
The grain size distribution of surficial samples recov-
ered with a Dietz-Lafond snapper grab samples used
as a trigger for cores Sc-1 to Sc-20 was measured. Size-
frequency histograms of these surface sediments,
plotted in Figure 33, show that two groups of sediment
can be distinguished on the basis of textural examina-
tion. Samples Sc-5 and Sc-13 from the relatively clean
surface sand layer are relatively coarse-grained and
show a small secondary mode in the coarse sand and
fine pebble range; sorting is poor. The second group of
sediments comprises predominantly very fine sand with
only traces of coarse sand. Cumulative frequency
curves, plotted on a probability scale (Figure 34), show
the spread of the size classes and indicate the poor sort-
ing of the surficial sediment. Samples Sc-2 and Sc-3 are
somewhat better sorted but contain less sand (the
modes lie in the silt range). In general, coarser-
grained sediments are more poorly sorted than those
which are finer.
Samples from cores Sc-1 to Sc-20 were selected
at 10 cm vertical intervals, and these were dispersed,
centrifuged, and sieved (method in Silverberg 1965).
Textural analyses serve to distinguish a brown and
olive gray facies: the gray sediment contains mainly
very fine-grained sand, between 105 and 63 microns,
and the grain-size distribution is relatively uniform
(most olive gray samples would be classified as silt,
clayey silt, and sandy silt). On the other hand, the
brown sediment sand fraction, also largely fine-
grained, does contain a somewhat higher amount of
coarse sand. The brown- facies also displays a greater
sample-to-sample grain-size variation. Analysis of the
uppermost surface sand facies shows that its size dis-
tribution is similar to that of most sands of the brown
facies.
A size-fraction coarser than 2 mm, mostly in the
Core Sc-9
'.v.v.v.v.v.w.v
?50
-100
?200
?25 U
??< Pebbles .?$#* Sand I Silt Clay
FIGURE 36.?Textural variation within an upper slope (Sc-9)
core penetrating a surficial sand layer above the reddish brown
section (see also Figure 14).
granule range, was recovered in some samples; the
grain-size distribution shows a continuum between
granules and the coarse sand grades. There is no
strong indication of bimodality.
The size distribution of 117 upper slope core samples
is plotted on a triangular textural diagram (see left
triangle in Figure 35). The pebble fraction has been
included with the sand component. Each sediment
32 SMITHSONIAN CONTRIBUTIONS TO THE EARTH SCIENCES
Core Sc-IO
?50 &
-100 ??:
-150 ?*:
-200 ?
-250
Pebbles Si&x Sand Silt Clay
FIGURE 37.?Textural variation within an upper slope (Sc-
10) core penetrating an olive gray section (see also Figure
14).
type (surface sand fades, and brown and gray sedi-
ment types) is depicted on a textural triangle (classifi-
cation after Shepard 1954). The surface sandy facies
comprises sand and silty sand; the brown facies samples
occupy mainly sand-silt-clay, sandy silt, and sand
positions on the triangle; and the olive gray sediment
type generally comprises silt and clayey or sandy silt.
It is readily apparent that the brown sediment type
shows a more variable textural distribution than does
the gray. There are some "anomalous" brown sediment
samples such as Sc-18-175 and Sc-4-100; these are
markedly less sandy than most such samples. The
former sample is from a brown layer within a core of
olive gray sediment and the latter from a core show-
ing laminations. Samples of olive gray sediment tend
to be concentrated about the silt end-member, but
show a continuous scattering toward the sand apex.
The textural variation in several slope cores is
illustrated in logs in Figures 36, 37, and 38. The upper
surficial sediment of core sections in occasionally more
sandy than lower portions, as shown in cores Sc-9 and
Sc-10. There are, however, cores of olive gray sedi-
ment in which this tendency is reversed. In general,
core sections of the brown facies (Sc-9) are more
sandy than those of the olive gray facies (Sc-10), but
again some exceptions to this are noted. The vertical
variability in texture is considerably greater within
brown than in the olive gray sediment sections. The
logs also show that the pebble fraction is common in
the brown facies (Figures 36, 38) and rare in the olive
gray (Figure 37.) Noteworthy is the abrupt change in
texture between the gray and brown layers (note
change at about 210 cm in Gore Sc-16, Figure 38).
Upper Slope to Lower Rise Traverse
Samples from the five short piston cores (Hud 30-9A
to -14), selected at 2 to 10 cm intervals (Figure 15)
were sieved and centrifuged to determine grain-size
data. Methods are the same as those to examine the
upper slope (Sc) cores. It is interesting that resulting
textural data is closely comparable to that obtained in
the study of cores Sc-1 to Sc-20.
The sand-silt-clay ratios of these traverse core
samples (data shown on right triangle in Figure 35)
;ndicate that the bulk of material consists of clayey
silt. The olive gray slope core (Hud 30-14) contains
some sandy silt and pure silt; most of the sand fraction
is of very fine sand grade. The brown upper rise cores
(HUD 30-13 and HUD 30-11) contain more poorly
sorted sand fractions. In addition, core Hud 30-13
contains pebbly horizons and a large proportion of
sediment in the sand-silt-clay class. The two upper
rise cores are texturally dissimilar; the shoaler, more
nearshore one (HUD-30-13) contains up to 80 per-
cent sand and also pebbly horizons. In both cores,
NUMBER 8 33
Core Sc-16
?50
-100
-150
??< Pebbles ::?:wX Sand Silt Hi Clay
FIGURE 38.?Textural variation within an upper slope (Sc-
16) core penetrating 210 cm of olive gray section above the
reddish-brown facies. This core displays a representative and
reasonably complete section of late glacial to modern sequence
on the slope south of Sable Island Bank.
however, the sand fraction is distributed more or less
equally over all five Wentworth-Udden grades.
The two tan and yellowish-brown lower rise cores
consist of well-sorted very fine, silty clay, clayey silt,
and silt, and are fairly uniform except the base of core
HUD 30?9A which is possibly a stratum of turbidite
origin.
An analysis of the textural parameters of samples
from 30 Lamont-Doherty cores collected on the slope,
rise, and abyssal plain south of Nova Scotia shows
no obvious differences that are strictly related to water
depth (Table 1). These outer margin core samples
are generally finer grained and less well sorted than
adjacent shelf deposits. Sedimentation units on the
slope and upper rise are coarser grained than those
on the lower rise and Sohm Abyssal Plain. The vari-
ability of sorting values provides a means of distin-
guishing sediments from the different environments
(this variability probably reflects differing modes of
sediment transport processes). Kurtosis values of
slumped (contorted) and of turbidite (graded) sedi-
ments are significantly lower than those moved and
modified by marine currents (laminated). Variation
in grain roundness does not appear to bear any rela-
tion to the environmental province or mode of origin
but is believed to reflect the character of the original
sediment sources.
Mineralogical Composition of
Outer Margin Deposits
Sable Island Bank Sediments
The composition of light and heavy minerals of the
sand-size fraction (0.062?2.00 mm) of surficial sam-
ples collected on Sable Island Bank was examined.
Iron-stained quartz is by far the most abundant sand-
size component on Sable Island Bank. Its distribution
and that of the less abundant feldspar (generally < 15
percent), also coated with ocherous hematite, is
variable on the bank (James and Stanley 1968, their
figure 6). Shell fragments of sand to pebble size (rang-
ing from < 1 to > 10 percent of the total sample),
particularly those in shallow water, show evidence of
considerable wear due to abrasion as a result of sedi-
ment transport. The percent of mica ranges from
trace to 5 percent.
The transparent heavy mineral suite is dominated
by garnet (> 50 percent of the transparent species);
the relative percentage of hornblende, kyanite, and
tourmaline together accounts for 16 to over 32 per-
cent of the suite. Extremely high percentages of
opaque mineral species (mostly magnetite and ilmen-
ite) locally account for over 50 percent of the heavy
34 SMITHSONIAN CONTRIBUTIONS TO THE EARTH SCIENCES
TABLE 1.?Textural data measured for 39 samples from Lamont-Doherty cores (S, slope; U.R., upper rise; L.R.f
lower rise; A. P., Sohm Abyssal Plain). Numbers at left refer to core localities shown in Figure 17. Sample
numbers are listed under "laboratory code"
Loc.
No.
1
2
3
4
5
6
7
9
10
11
12
13
14
15
16
17
18
19
20
21
22
23
24
25
26
27
28
29
30
Lanont - No.
A 164 - 46
A 164 - 47
A 164 - 48
A 164 - 49
A 164 - 54
A 164 - 55
A 173 - 8
- 8
- 8
A 173 ? 10
A 173 - 11
A 173 - 12
A 173 - 13
A 173 - 14
C 25 - 10
KM 1 - 2
KM 1 - 5
KM 1 - 6
KM 1 - 7
SP -12 - 1
12-2
12-3
12-4
V - 2 - 4
V - 7 - 36
- 38
- 38
- 38
V - 7 - 63
- 63
V - 7 - 68
- 6B
V - 7 - 69
V - 7 - 70
V - 16 - 213
- 213
V - 17 - 209
- 209
-209
Lab.
Code
192
193
194
82
195
196
78
77
76
198
199
200
201
202
207
208
210
211
212
73
215
216
217
220
225
226
63
64
243
244
22
21
245
246
247
248
3
2
1
Depth
Core (cm)
2B-30
28-30
18-20
163-5
360-2
250-2
80-2
190-2
B00-2
260-2
30-2
300-2
120-2
10-12
30-2
150-2
12-14
136-8
B0-2
305-7
102-4
77-9
352-4
20-2
80-2
401-3
410-2
442-4
10-12
30-2
60-2
B0-2
98-1BO
150-2
10-12
60-2
170-2
190-2
205-7
Water
Depth (F
2610
2580
2530
510
1230
1820
1490
1490
1490
900
1426
1150
1600
1410
910
750
136
310
450
700
680
1300
1310
2000 ?
2508
2508
2508
2508
220
220
2143
2143
1600
700
2065
2065
2453
2453
2453
Location
A.P.
A.P.
A.P.
S.
U.R.
L.R.
U.R.
U.R.
U.R.
5.
A.P.
U.R.
L.R.
U.R.
S.
S.
5.
5.
S.
s.
s.
U.R.
U.R.
L.R.
A.P.
A.P.
A.P.
A.P.
S.
5.
L.R.
L.R.
U.R.
U.R.
L.R.
L.R.
L.R.
L.R.
L.R.
Round.
.43
.49
.50
.40
.39
.45
.46
.51
.46
.49
.49
.42
.47
.46
.50
.45
.40
.35
.44
.42
.47
.52
.46
.37
.45
.48
.36
.40
.48
.42
.48
.39
% Heavy
2.77
2.08
1.71
0.54
1.38
0.36
1.67
0.29
4.97
0.89
1.23
D.78
2.94
1.24
0.46
0.97
0.57
a.76
1.27
1.05
1.06
0.67
2.49
0.27
0.47
2.01
2.56
1.19
1.70
0.19
1.87
2.31
4.44
% less
than
.063mm
.0
21.0
25.6
24.82
63.5
43.1
11.85
6.40
4.57
77.2
65.9
60.2
44.8
68.1
85.3
73.0
27.7
31.5
62.3
2.73
58.3
46.1
32.9
100
72.0
1.6
6.4
14.05
32.0
53.7
.12
.07
75.0
63.3
74.1
7.37
0.97
0.37
Anal.
H.M.
yes
yes
yee
yes
yes
yes
yes
yes
yes
yes
yes
yes
Mean 0
3.25
3.21
3.58
2.22
2.01
3.06
3.21
3.06
3.06
2.44
1.10
1.35
2.47
1.95
2.68
3.13
3.21
3.24
2.89
0.98
2.30
2.46
2.40
3.04
1.09
1.03
2.80
3.60
3.60
1.66
1.24
0.95
2.59
2.46
2.76
1.74
1.12
Sort.
0.46
0.59
0.42
1.20
1.56
0.97
0.44
0.54
0.46
1.19
0.94
1.57
1.02
1.B3
1.26
0.79
1.23
0.60
1.14
1.39
1.15
1.09
1.15
0.49
1.11
1.25
0.84
0.43
0.33
0.61
0.80
1.94
1.20
0.91
0.62
0.61
1.18
Skewness
-4.46
-12.57
-14.25
-4.08
-3.23
-8,33
-7.25
-6.98
-3.91
-3.33
-1.75
-2.54
-2.99
-3.23
-3.75
-6.46
-12.00
-11.3B
-8.50
0.44
-4.27
-4.78
-4.61
-13.86
0.29
0.69
-5.33
-23.08
-IB.23
-0.10
D.31
0.22
-4.73
-0.63
-5.58
-0.05
-1.30
Kurtosis
9B
331
288
61
37
123
231
167
130
45
29
33
51
30
38
89
173
247
119
31
64
71
66
274
45
37
B5
728
601
69
50
19
58
30
133
90
32
NUMBER 8 35
59 00 43
30
GULLY TROUGH
DISTRIBUTION OF
BROWN-STAINED QUARTZ
>64
32-64
DID 16-32
FIGURE 39.?Relative percentage of brown iron-stained quartz (calculated from the total quartz
content only) in the 250-1000 and 62-250 micron-size fractions of Gully Trough samples.
43_ 30 6000 30
GULLY TROUGH
DISTRIBUTION OF
GREEN-STAINED QUARTZ
> 8
4-8 RELATIVE
CD <4 oi
FIGURE 40.?Relative percentage of green-stained quartz (calculated from the total quartz
content only) in the 250-1000 and 62-250 micron-size fractions of Gully Trough samples.
36
4330
2000-500 u -7
4400
43,
4400
30
SMITHSONIAN CONTRIBUTIONS TO THE EARTH SCIENCES
6000 30 59 00 43
500 - 125 u
6000
GULLY TROUGH
DISTRIBUTION OF
ROCK FRAGMENTS
>8
4-8
I 1 <4
RELATIVE
30
4400
FIGURE 41.?Relative percent of rock fragments (calculated from the quartz -f- rock fragments
portion of the sample only) in the 500-2000 and 125-500 micron-size fractions of Gully Trough
samples.
mineral assemblage. Iron nodules and dark green to
black glauconite grains (1 to over 4 percent of the
light mineral fraction) are noted in samples on the
southern portion of the bank.
i i I I I I I I I I I I I I I I I I I I I I I I | I I II
 III'
0 50 100 150 200 250
DEPTH (METERS)
FIGURE 42.?Relation between percent of rock fragments and
depth in the 250-500 micron-size fraction of sediments in
the Gully Trough area. Note increase in the amount of rock
fragments between the 140 and 200 meter depth range.
Angular as well as well-rounded pebbles recovered
locally on the bank include rock types that appear
similar to those cropping out on the Nova Scotian
mainland (i.e., including Devonian igneous rocks, Car-
boniferous elastics, Triassic basalt, and states, schists,
and metamorphics of the lower Paleozoic Meguma
Group. Some glauconitic sandstone, of the type not
found on the mainland, is probably derived from some
now-submerged coastal plain Tertiary or Cretaceous
bedrock cropping out nearby on the shelf. A detailed
mineralogical study of Nova Scotian surficial sedi-
ments has recently been compiled by A. E. Cok (1970).
Gully Trough Sediments
The mineralogical composition of the sand-size frac-
tion of surficial Gully Trough samples, examined by
James (1966), can be summarized as follows.
QUARTZ.?Three types of quartz are present in
significant quantities:
(a) Orange to red iron-stained quartz, possibly
indicative of subaerial exposure.
NUMBER 8 37
250-125 30
4400
GULLY TROUGH
DISTRIBUTION OF
GLAUCONITE
>4
2-4
I 1 <2
FIGURE 43.?Percentage of glauconite in the 250-500 and 125-250 micron-size fractions of
Gully Trough samples.
(b) Clear quartz, suggesting possible removal of
iron-stain by abrasion.
(c) Green-stained quartz, the origin of which is
unknown (flame spectrophotometry indicates that the
stain is due to the presence of iron). Weller (1960)
has indicated that iron coloration can be used as an
index of the oxidation state: red indicates a high
degree of oxidation, and green a low degree of oxida-
tion. Keller (1953) suggests that a green color in
some sediments may also be due to the presence of
iron in such marine clays as illite and montmorillonite.
The data suggest that the distribution of particular
quartz-types is depth controlled. The amount of red-
stained quartz is relatively high at depths above 120
m; this type of quartz decreases to a low at about 20
m (Figure 39). The relative percentage of green-
stained quartz, generally low at most depths, increases
with depth to a high at the 110 to 145 m depth range,
and then decreases at greater depths (Figure 40).
ROCK FRAGMENTS.?Rock fragments are relatively
sparse on Banquereau Bank, the eastern portion of
Sable Island Bank, and in The Gully Canyon off the
eastern end of Sable Island Bank. Rock fragments,
on the other hand, are relatively abundant in the
central deeper portion of the Gully Trough (Figure
41). Figure 42 shows the relative percentage of rock
fragments in the 250-500 micron fraction (rock frag-
ments of this size are present in almost all samples in
this area) plotted against depth. This diagram indi-
cates that the rock fragments are most abundant
between 140 and 200 m (Figure 42).
GLAUCONITE.?Glauconite content in the coarse
fraction (250-500 micron) is relatively high between
Middle Bank and Banquereau Bank and the central
portion of the Gully Trough and its extension toward
The Gully Canyon (Figure 43). No correlation is
noted between the amount of glauconite and depth,
nor does there appear to be a relation between the
regional distribution and grain size.
This glauconite may have originated from erosion
of (a) older bedrock cropping out in the area, or
(b) from pebbles of glauconitic sandstone, or (c) it
38
4330
4400
4400
30
SMITHSONIAN CONTRIBUTIONS TO THE EARTH SCIENCES
6000 30 59 00 43
SAMPLE
Distribution of
HEAVY MINERALS
>4
2-4
I I < 2 by wt.
44
oc
FIGURE 44.?Relative percentage, by weight, of heavy minerals present in the 125-250 micron-
size fraction of Gully Trough samples. The sample station locations are shown in the lower map.
may be authigenic and forming at present. Its cor-
roded appearance, however, tends to suggest a relict
origin.
HEAVY MINERALS.?Heavy minerals are most abun-
dant on the banks and topographic highs in the Gully
Trough (Figure 44). Bank surfaces have been sub-
jected to current activity resulting in removal of
fines and concentration of heavy minerals as lag
deposits. The heavy mineral content is generally low,
below 200 m, with the exception of the region of The
Gully Canyon between Banquereau Bank and Sable
Island Bank. The latter region may be receiving sedi-
ment of well-sorted material that originates on bank
tops.
Opaque heavies and zircon show similar distribu-
tion trends: high values on the isolated topographic
highs and bank tops, and in the deepest areas (Fig-
ure 45). At intermediate depths off the western end
of Sable Island Bank, however, these minerals are
sparse. A plot of opaques versus depth (Figure 47)
shows that above 120 m the relative percentage of
opaques is consistently above 50 percent, whereas
below 160 m it ranges about 35 percent. This variation
probably reflects depositional differences with depth:
a shallower zone of reworking with "mature" sedi-
ments, and a deeper, quieter deposition zone of un-
mixing ("immature" sediments) occurring between
120 and 160 m.
Weathered heavy mineral species are abundant in
basins and areas deeper than 200 m, suggesting that
they may be the result of in situ chemical destruction
of several mineral species (Figure 45).
Garnet, hypersthene, and staurolite have a similar
distribution pattern in this region (Figure 46), i.e.,
abundant on the western portion of Sable Island Bank
and Middle Bank with lower percentages in the deeper
axis of the depression. The relatively high percentage
of garnet on the bank tops seems to confirm the
"mature" (reworked lag) nature of sediment exposed
at shallower depths than those in deeper regions.
The distribution patterns of hornblende, kyanite,
and tourmaline are similar. Their concentrations are
low on the banks and highs in the deep central region,
except in a deep area between Sable Island Bank and
Banquereau Bank (Figure 46). The percentage of
garnet, on the other hand, shows a generally consistent
6000 30
GULLY TROUGH
DISTRIBUTION OF
HEAVY MINERALS
ALTERITE OZ
X7Z\ >4 (Z3 HIGH REL
DID 2-4 CZH MEDIUM <y '
? <2 HH] LOW ?
FIGURE 45.?Relative percentage of alterite in the nonopaque portion of the heavy minerals
in the 125-250 micron-size fraction. In lower map, relative abundance of zircon and opaque
heavy minerals in the 125-250 micron-size fraction in Gully Trough samples.
59 00 43
6000 30 59 00
GULLY TROUGH
DISTRIBUTION OF
HEAVY MINERALS
H-K-T G-H-S
f^)>40
QIXI 30-40 E53 50-60
I I <30 ["0 40-501 )<40
FIGURE 46.?Relative percentage of hornblende + kyanite + tourmaline (in upper diagram),
and garnet + hypersthene + staurolite (in lower diagram) in the nonopaque 125-250 micron-
size fraction of Gully Trough samples.
40 SMITHSONIAN CONTRIBUTIONS TO THE EARTH SCIENCES
80-r
6ULLY TROUGH
HEAVY MINERALS
VS.
DEPTH
GARNET
6Or
100 200 300
DEPTH (METERS)
x SAMPLES FROM "THE GULLY"
OPAQUES
0 100 200 300
DEPTH (METERS)
FIGURE 47.?Variation with depth of the relative percentage
of garnet (upper graph) and opaque minerals (lower graph)
in the Gully Trough. Garnet decreases progressively with
depth. Opaque heavies also decrease with depth, and par-
ticularly so below 120 m.
decrease with increasing depth (Figure 47). Thus,
it appears that hydraulic selectivity is the dominant
factor governing the heavy mineral distribution in The
Gully Trough. Hornblende, kyanite, and tourmaline,
all of relatively low specific gravity, have probably
been winnowed out of surficial relict (Pleistocene)
deposits on the banks and transported to deeper areas.
The Gully Canyon Sediments
The Gully Canyon and its deep upper slope-shelf
extension due east of Sable Island morphologically
separates Sable Island Bank from Banquereau Bank.
The mineralogical composition of the sand fraction
of samples from the upper parts of cores was deter-
mined (James 1966).
IRON-STAINED QUARTZ.?The relative amount of
brown-colored, iron-stained quartz (Figure 48) does
not appear closely related to grain size, as is the case
on Sable Island Bank. Most samples rich in stained
quartz are fine grained although a smaller amount of
stained quartz occurs as coarse (1.0?2.0 mm) sand.
The amount of coarse iron-stained quartz decreases
downslope along the canyon trend. A zone poor in
iron-stained quartz parallels the 500 fm isobath just
west of the canyon axis. Sediment of very fine sand
grade within the canyon axis contains a relatively
high amount of iron-stained quartz. A zone relatively
rich in iron-stained quartz of all sizes occurs at about
400 fathoms on the east (Banquereau) margin of
the canyon.
ROCK FRAGMENTS.?Sediment of sand grade in the
central portion of the canyon contains proportionately
lesser lithic fragments than on the banks, particularly
Banquereau Bank. A zone of lithic-rich sediment ex-
tends from Banquereau Bank seaward toward deeper
areas near the mouth of the canyon (Figure 49). This
trend suggests a provenance from Banquereau Bank.
SHELL-FRAGMENTS.?Sediment in and near the
canyon axis contains relatively lower amounts of shell
fragment than on the canyon walls and mouth (Fig-
ure 50). The shell-rich area extends from the eastern
and southeastern margins of Sable Island Bank down-
slope into the canyon.
GLAUGONITE.?Glauconite-poor sand covers the
eastern margin of Sable Island Bank as well as sec-
tions of the upper reaches of The Gully Canyon (Fig-
ure 51). Areas of high (8 percent) glauconite content
occur at intermediate depths (100 to 800 m) on the
west wall (Sable Island Bank side) of the canyon,
as well as along most of the Banquereau margin. The
in situ origin of glauconite in this area cannot be
ruled out. It is more probable, however, that glau-
conite-rich strata cropping out along the canyon mar-
gins serve as a source for this mineral.
MICA.?Mica is rare to absent in surficial sediment
on Sable Island Bank and in the upper reaches of
The Gully Canyon (areas of intense bottom current
activity), but is present in low amounts on Banquereau
Bank and in the mid sectors and lower sectors of The
NUMBER 8 41
Rolatlvo %
m^> 20
E^S^l 5-20
1 1<5
A
B
C
P
m > 600 M
? 500-250 yu
* 250-125 /*
? 125-62 M
THE GULLY CANYON
Distribution of
Brown stalnoi Quarts
FIGURE 48.?Relative percent of brown iron-stained quartz (calculated from the total quartz
content only) present in different size fractions in The Gully core samples. Note relatively high
amounts in fine-grained stained quartz in the axis of the canyon.
Gully (Figure 49). The platy shape of mica results
in its deposition with quartz and other minerals of
different (generally smaller) size and density in deeper,
less current agitated environments beyond the shelf-
break, an observation made elsewhere by Doyle et al.
(1968) and Lyall et al. (1971).
HEAVY MINERALS.?The heavy mineral content of
both the 62 to 125/A and the 125 to 25(fyt fractions
in Gully samples were examined. The 62 to 125/u,
distribution is perhaps most reliable in that the very
fine sand fraction is present in most samples examined,
including muddy ones. The proportion of opaque min-
erals in the coarser (125 to 250ft) fraction increases
southward and apparently bears no relation with the
physiography of the canyon. The relative percent of
opaques present in the finer fraction, however, is
related to some degree with canyon morphology, i.e.,
samples in the axis of the canyon containing less
opaques than those in the upper canyon reaches (Fig-
ure 52).
The distribution of zircon is more irregular, parti-
cularly in the smaller grain-size fraction (Figure 53).
In the coarser fraction, zircon is relatively abundant
in the upper reaches and at the mouth of the canyon
but sparse in the central portion. Hornblende and
tourmaline display nearly identical distribution pat-
terns and thus are plotted together (Figure 54). Gar-
net (Figure 55) has a distribution pattern that closely
resembles those of hornblende and tourmaline but
shows opposite trends, i.e., where garnet content is
high, hornblende and tourmaline content is low, and
vice versa. The three mineral species are believed to
have a similar source origin and thus can be discussed
together. In the coarser size fraction, garnet is low
in a region extending from Banquereau, down the
east wall and across the mouth of the canyon; in the
axis of the canyon, at about 700 fm, the opposite
trend is noted, i.e., high garnet values are present.
In the finer fraction, garnet percentages are relatively
high and hornblende and tourmaline relatively low
in two linear belts parallel to the axis, and between
300 and 400 fm on either side of the canyon. It is
possible that these linear trends along both margins
of the canyon are related to local sources cropping
THE GULLY CANYON
DISTRIBUTION OF
ROCK FRAGMENTS
%
MICA
THE GULLY CANYON
DISTRIBUTION OF
GLAUCONITE
^ "? RELATIVE? <8 %
FIGURE 49.?A, relative percentages of rock fragments.
B, presence of mica in surficial sediment of The Gully Can-
yon.
5300
THE GULLY CANYON
DISTRIBUTION OF
SHELL FRAGMENTS
100
1 -100
LZH 1
FIGURE 50.?A, percent of shell fragments in the 500-1000
micron-size fraction in The Gully Canyon, B, sample sta-
tion locations (samples designated with symbol m were
donated by J. Marlowe, Bedford Institute of Oceanography).
FIGURE 51.?Percent of glauconite in the (A) 125-250 and
(B) 62-125 micron-size fractions in The Gully Canyon
samples.
THE GULLY CANYON ^ >60
DISTRIBUTION OF ?X3 30 eo
OPAQUE HEAVY MINERALS \ZJ <3O
FIGURE 52.?Relative percent of opaque heavy minerals of
the (A) 125-250 and (B) 62-125 micron-size fractions in
The Gully Canyon samples.
NUMBER 8 43
125-250/1
B
THE GULLY CANYON
DISTRIBUTION OF
ZIRCON
>8
<8 RELATIVE
FIGURE 53.?Relative percentage of zircon in the (A) 125-
250 and (B) 62-125 micron-size fractions in The Gully Can-
yon samples.
out along the canyon walls. Sediments displaying rela-
tively high hornblende and tourmaline values occur
on Banquereau Bank and extend down the canyon
wall across the mouth of the canyon.
The distribution of hypersthene in the coarser frac-
tion is similar to patterns of opaque heavies and zircon,
i.e., high values in the upper reaches and mouth of
the canyon and lower values in the central part of
The Gully (Figure 56). In the finer grain sizes, two
linear highs of hypersthene on either side of the can-
yon, between 100 and 300 fm (like hornblende-tour-
maline), also suggest that there may be a local source
of sediment cropping out along the margin of the
upper reaches of the canyon.
Relative percentages of kyanite are relatively low
on both banks and in the center of the canyon but
increase along the canyon walls between 400 and 500
fm (Figure 57). Staurolite is asymmetrically distri-
buted about the axis of the canyon, i.e., low on the
Banquereau Bank margin and high on the Sable
Island Bank margin. In the very fine sand fraction,
staurolite is abundant along both margins of the can-
yon but uncommon near the canyon axis (Figure 58).
Both light and heavy minerals are similar to those
reported in Oligocene and Miocene rocks cropping
out along the walls of The Gully Canyon (Marlowe
1969). It is probable that erosion and in situ weather-
ing of exposed sedimentary rock ledges has contributed
at least a minor amount of sediment to the canyon
fill. The primary source, however, of the mineral suite
observed here, as elsewhere on the outer margin, is
plutonic, metamorphic, and sedimentary rock terrains
some two hundred or more kilometers to the northwest.
Continental Slope Sediments
Mineralogical analyses of the coarser-than-silt fraction
(> 62ju) of slope cores Sc-1 to Sc-20 (Silverberg
1965) are reported below. Quartz, the dominant com-
ponent of the sand-size fraction, occurs in many forms.
Many of the grains are iron-stained and the surfaces
may be smooth, pitted, or frosted. An almost complete
gradation, from well rounded to very angular grains,
B
THE GULLY CANYON
DISTRIBUTION OF
HORNBLENDE a TOURMALINE
RELATIVE
FIGURE 54.?Relative percentage of hornblende -}- tourmal-
ine in the (A) 125-250 and (B) 62-125 micron-size fractions
in The Gully Canyon samples.
125-250/1
THE GULLY CANYON
DISTRIBUTION OF
GARNET
S3 >64
C^J 32 64 RELATIVE
? <32 %
FIGURE 55.?Relative percent of garnet in the (A) 125-250
and (B) 62-125 micron-size fractions in The Gully Canyon
samples.
THE GULLY CANYON
DISTRIBUTION OF
HYPERSTHENE
ES3 >s
<8
RELATIVE
FIGURE 56.?Relative percentage of hypersthene in the (A)
125-250 and (B) 62-125 micron-size fractions in The Gully
Canyon samples.
THE GULLY CANYON
DISTRIBUTION OF
KYANITE
C53 >s
I 1 <S RELATIVE
FIGURE 57.?Relative percentage of kyanite in the (A) 125-
250 and (B) 62-125 micron-size fractions in The Gully Can-
yon samples.
I25-2SQAI
B.
THE GULLY CANYON
DISTRIBUTION OF
STAUROLITE
FIGURE 58.?Relative percentage of staurolite in the (A)
125-250 and (B) 62-125 micron-size fractions in The Gully
Canyon samples.
NUMBER 8 45
OLIVE GRAYFACIES
100 0 100 microns O
Percentage ofTotal Sand
50 100
6-56
7-67
SURFACE SAND
13-5
>150
105
62
150
105
62
150
105
62
150
105
62
150
105
62
300
150
105
62
Quartz
Rock fragments
Mica
Dark terr
Glauconite
Carbonate hash
Shell fragments ????
Forammifera ^^^H
FIGURE 59.?Mineralogical variation of the coarse fraction with grain size in selected slope
(Sc) core samples (olive gray and surface sand facies).
46 SMITHSONIAN CONTRIBUTIONS TO THE EARTH SCIENCES
BROWNFACIES
microns 0
Percentage ofTotal Sand
50 100
Quartz
Rock fragments
Mica 1
Dark terr.
Glauconite
Carbonate hash
Shell fragments ????
horammifera HBHol
FIGURE 60.?Mineralogical variation of the coarse fraction with grain size in selected slope
(Sc) core samples (brown facies).
NUMBER 8 47
is found in most samples. Ubiquitous accessory com-
ponents are feldspar, mica, rock fragments, shell mate-
rial, and Foraminifera. Glauconite, dark terrigenous
grains, and carbonate "hash" are additional compon-
ents which may also be present. Mica occurs mostly
as flakes of muscovite; small amounts of biotite and
phlogopite are noted. Fragments of red, green,, and
grey siltstone; red and gray sandstone; quartzite;
mica schist; quartz-biotite gneiss; basalt; and granite
are the principle lithologies comprising the lithic frac-
tion.
Shell material consists of fragments in various stages
of destruction. The bulk of shell fragments is relatively
fresh although some of the larger smooth and rounded
grains show evidence of abrasion. Foraminifera tests
make up most of the shell component: many broken
individuals are noted in grain counts. In this study,
only those fragments which could definitely be identi-
fied as Foraminifera were counted. The remainder
are included in a general component category. Black
grains, concentrated with foraminifers during the
CCI4 flotation procedure, displayed conchoidal frac-
turing, granular and ribbed fine structure. Combus-
tion, using relatively low temperature flames, indicates
that this substance is a hydrocarbon, probably coal
(indication of a terrigenous origin, perhaps Cape
Breton). Other components of this fraction appear
to be biotite aggregates, and altered amphiboles and
pyroxenes.
Carbonate hash is the term adopted to describe
aggregates of pale, greenish, flaky material, fine shell
fragments, and occasionally scattered quartz grains,
all loosely cemented by carbonate material. A flaky
material often present is probably an altered clay
product. Glauconite grains are generally dark green,
somewhat knobbly grains with a smooth or finely pitted
surface.
Mineralogical data plotted as relative percentages
on graphic logs show compositional variation with
grain size in selected samples (Figures 59?61) :
QUARTZ.?The amount of quartz clearly increases
with decreasing grain size. Most grains are angular
in all size fractions but there is a general trend of
increasing angularity with decreasing grain size.
FORAMINIFERA.?Tests, generally smaller than 300/JL,
tend to be concentrated in the 150 to 300/A fraction;
relative percentages decrease regularly in finer size
fractions. This, however, does not imply a decrease in
total numbers, for the total number of grains, includ-
ing quartz, increases with decreasing grain size and
the proportion of Foraminifera tends to be masked
by other components. Actual counts of the foraminif-
ers in concentrates shows that there is indeed a higher
proportion of tests in the fine fractions.
ROCK FRAGMENTS.?In those samples where the
lithic fraction is abundant, there appears to be a
direct relation between frequency and grain size. A
larger number of sand-size basalt fragments occurs
in smaller size fractions.
SHELL.?Although the frequency is relatively con-
stant in different grain sizes, there is a tendency, in
some samples, of a higher shell fraction in the finer
sizes. Complete valves of pelecypods and partially
broken gastropods occasionally are found in the
coarser than 300fx fraction.
MICA.?Many samples show an increase in mica
flakes with decreasing grain size; in some samples,
however, this trend is not obvious.
DARK TERRIGENOUS GRAINS.?This material con-
sists of ferromagnesian and opaque heavy minerals.
It is more commonly encountered in the finer sizes
and is most abundant in the very fine sand grade.
GLAUCONITE AND CARBONATE HASH.?There is no
marked relation between grain size and frequency of
these components although glauconite and carbonate
fragments are slightly more abundant in the finer
sand sizes.
It must be noted that data were obtained using a
percentage determination so that all components are
actually dependent variables. Furthermore, the figures
have been adjusted so that minor components are
exaggerated and the major components subdued. The
most variable components (excluding quartz) are
lithic fragments and Foraminifera, and strong trends
shown by these components invariably result in modi-
fying the remaining mineralogical components. There
is a general tendency for the total carbonate material
to decrease directly in ratio with grain size. This
change is gradual: the increasing percentage of shells
and carbonate hash complements the sharp decline of
Foraminifera with decreasing grain size.
Examination of core Sc-16 indicates that quartz
and dark terrigenous components generally vary di-
rectly, as do mica and glauconite. Shells and foramini-
fers and occasionally carbonate hash also display
similar trends.
The minor components generally show more variable
changes in percentage than the major components.
48 SMITHSONIAN CONTRIBUTIONS TO THE EARTH SCIENCES
CORE Sc-16
0 100 0 100 microns 0
Percentage of
Total Sand
50 100
150
200
220
?????!
240
Quartz
Rock fragments
Glauconite
Carbonate hash
Shell fragments
Forammifera
FIGURE 61.?Mineralogical variation of the coarse fraction with grain size in the representative
upper slope core (Sc-16). Top three samples are olive gray fades; the lower two are brown
facies.
NUMBER 8 49
FACIES
? brown
? olive gray
? surface sand
Rock Fragments
Terrigenous Carbonate
FIGURE 62.?Coarse fraction mineralogical components in
three facies cored (Sc cores) on the continental slope.
These fluctuations of both groups are random, how-
ever, and no distinct tendencies were noted within the
three major Nova Scotian Slope sediment types (sur-
face sand, olive gray and brown facies).
The olive gray and reddish brown sediment types
are most easily distinguished by their accessory com-
ponents: a predominantly calcareous fraction in the
gray sediment facies, and predominantly terrigenous
assemblage in the brown facies. The same lithic frag-
ments are found in both sediment facies, but brown
sediments generally show a greater variety of petro-
logic types in any one sample as well as a higher
proportion of red-colored sedimentary fragments. This
contrast was noted clearly in analyses of coarse sand
in brown and olive gray sediment types in representa-
tive core Sc-16.
The quartz-feldspar fraction also tends to be more
inportant in brown sediment, while glauconite and
carbonate fragments are more abundant in the gray
facies. There does not appear to be a major difference
in content of dark terrigenous grains in the two sedi-
ment types. The absolute amount of mica, Foramini-
fera, and shells is lower in the brown sediment type,
but the relative proportions generally remain the
same in both olive gray and brown sediments.
The abrupt change of lithology at a depth of 210
cm in core Sc-16 reflects the contact between the
reddish-brown and the gray sediments. A plot of rock
fragments, total carbonate, and total terrigenous frac-
tion on a triangular diagram emphasizes mineralogical
differences between the two facies (Figure 62). Fig-
ure 62 highlights the greater variability of carbonate
fraction in the gray sediment type and the higher
amount of rock fragments in brown sediment.
The relatively clean sand facies found at the top
of some cores (samples Sc-9-1, Sc-13-5, and Sc-15-0)
consists of predominantly terrigneous components; the
accessory fraction of the sand is mostly rock fragments.
The similarity of the upper sand layer and the sand
fraction in the brown facies is noteworthy.
The concentration of heavy minerals in the 62 to
500/u, size range is low; the total weight of the heavies
recovered is generally less than 1 percent and only
rarely exceeds 2 percent (Figure 63). The variation
in amount of heavy minerals is similar to that of light
and dark terrigenous components. The abundance of
heavy minerals does not vary significantly between the
brown and gray sediments. Sediments that are fine
grained generally contain a higher proportion of heavy
minerals which, because of their small inherent size,
tend to be concentrated in the finer sand grades.
Opaque grains account for 20 to 60 percent (most
commonly between 25 and 35 percent) of the heavy-
mineral fraction. The abundance of nonopaque min-
eral species forming the predominant suite and found
in all samples is shown in Figure 64. Hornblende is
the most abundant transparent heavy mineral en-
countered (relative percentages range from 10 to 42
percent, but most frequently from 25 to 35 percent).
Garnet accounts for 10 to 30 percent of the heavies,
but individual counts vary widely between these limits.
Hypersthene ranges from 5 to 20 percent (generally
about 12 percent). Augite may account for as much
as 20 percent of the heavy mineral counts but, like
garnet, is a mineral showing much variability from
sample to sample.
Other heavy mineral species show considerably
more variation from sample to sample. Altered min-
erals, for example, are the most commonly encoun-
tered grains (to 24 percent) making up this accessory
suite. Andalusite, zircon, and tourmaline are found in
almost all of the 21 Sc-core samples analyzed, and
each may attain 8 percent of the sample. Epidote
and staurolite, not as common, form up to 10 percent
50 SMITHSONIAN CONTRIBUTIONS TO THE EARTH SCIENCES
200
O 50O
O
50
OLIVE GRAY FACIES
*.
BROWN FACIES
? ?? +
? ?
? ?
2 3 0 1
Weight in grams of 62 - 500 AC fraction
FIGURE 63.?Concentration of heavy minerals in the olive gray and brown sediment types.
and 5 percent of the nonopaques, respectively. Saus-
surite, occurring in six samples, ranges from 3 to 11
percent. Titanite, mica, brookite, kyanite, chloritoid,
and sillimanite are encountered infrequently. The
regional uniformity of both predominant heavy and
accessory mineral suites is noteworthy. Furthermore,
there does not appear to be a notable difference be-
tween heavy mineral assemblages of the brown and
the olive gray sediment facies (Figure 64).
Upper Slope to Rise Traverse
The coarser than 62 micron fraction of samples from
the slope-rise traverse (cores HUD 30-9 to 14) was
sieved into five Wentworth-Udden size classes, and
each fraction was weighed and percentages computed.
The sand-size and coarser components observed were
clean (nonstained) quartz and feldspar grains, iron-
stained quartz and feldspar grains, reddish rock frag-
ments, gray rock fragments, shell debris, Foraminifera,
and glauconite. Counts were made of each of these
components in each size fraction according to the
technique described by Shepard (1963). Two hundred
grains were counted when sufficient sand-size material
was available. Those samples where there were less
than 200 grains available for counts can be identified
in Figure 65: if all fractions of a sample weighed less
than 0.05 grams, then each fraction was arbitrarily
assigned an equal share of the size distributed, and
columns of the histograms are therefore equal in
height (example: HUD 30-11, sample 15-17). If
some fractions weighed over 0.05 grams and some
weighed less, then the former were assigned their
correct weight on the histogram, while each of the
latter received an equal share of the remainder. In
the mineralogical analyses shown in Figure 65, where
two or more histogram columns are of equal height,
their counts are less than 200 grains, and their weight
percent values are arbitrary. The single exception is
core sample HUD 30-9A-35-37, whose two columns
are, coincidentally, of equal weight.
After foraminifers and heavy minerals were ex-
tracted, the residue was stained for feldspar following
the methods of Keller and Ting (1950).
Brown Facies
per cent 100 I I
Non-Opaques
Hornblende >>::[:|:[x-:-_:-_:: Augite
Opaques
Garnet Hypers thene
FIGURE 64.?Principal heavy minerals suite in surface sand,
olive gray and brown sediment types from cores (Sc) col-
lected on Nova Scotian Continental Slope.
Quartz is the most abundant of the major terrigen-
ous constituents, ranging between 70 and 96 percent
(Figures 66, 67 and Table 2). The grains are pre-
dominately subangular to subrounded (Powers 1953)
and of the common quartz variety (Folk 1964). Well-
rounded grains of medium to coarse sand are present
in trace amounts. Silica overgrowths were noted on
several of these, and the grains are believed to be
derived from Paleozoic sandstones of the Maritime
Appalachians.
A variety of quartz which appears to be of signifi-
cance to this study is stained with iron oxide (Figure
51
68). The coating ranges in color from moderate red
(5R 4/6, Rock Color Chart Committee, 1963) through
dusky red (5R 3/4), and dark yellowish orange
(10YR 6/6) to moderate brown (5YR 3/4). Under
the binocular microscope, iron-stained grains appear
filmed with opaque, earthy matter that is thin to
absent on convex surfaces, but thick and clotted on
concavities and fissures. This distribution suggests that
the coatings predate transportation, during which
process the coatings were partially removed by abra-
sion. There are at least two earlier stages in the present
sedimentary cycle where the coatings might have been
formed. Emery (1965:5) described the Atlantic shelf
of North America as floored primarily by sands that
are "coarse . . . iron-stained, and somewhat solution
pitted." Emery concludes that these sands are relict
stream and littoral deposits from Pleistocene low
stands of the sea. The iron coatings of the grains may
have formed also during subaerial weathering of the
original Piedmont source area (Judd et al. 1969).
It may have formed in part during the present stage
of the sedimentary cycle, during subaerial exposure
of the shelf, due to mobilization of iron hydroxide
present in the fine fraction of the sediment (Van
Houten 1968) or from intrastratal solution of iron
hydroxides and oxides (Van Houten 1968, Norris
1965). The coatings may conceivably still be forming
on the coarser sands of shallow banks where bottom
circulation is sufficient to provide a flow of aeriated
water, but not sufficiently intense to abrade grain sur-
faces. As noted in earlier sections, similar iron-stained
sands are abundant on the Nova Scotian shelf (Stan-
ley and Cok 1968), including Sable Island Bank.
In addition, the iron-stained quartz of our cores
probably received parts of its pigment during an ear-
lier sedimentary cycle. Conolly et al. (1967:131), for
instance, describe reddish-brown glaciomarine sedi-
ments from the Laurentian Channel between Nova
Scotia and Newfoundland which contain "Calcite,
quartz, and feldspar grains with relic iron oxide rims
and red calcite-cemented lithic sandstone fragments
and arkosic rock fragments derived principally from
Triassic (and/or Carboniferous-Permian) sediments
of Appalachian Canada or from their reworked de-
rivations." Calcite-cemented reddish sandstone frag-
ments are present in some of our cores as Conolly
and others have described them. Some of these frag-
ments were sufficiently friable to break down to iron-
stained sand grains as we manipulated them. Iron-
52
o
(E
UJ
Q.
HUD 30-14
0-2 cm
10-12
23-25
35-37
0-2 em
le-io
19-21
22-23
25-27
40
20
0
40
20
0
40
20
^ 35-37
F
45-47
65-67
12 3 4
PHI UNITS
SMITHSONIAN CONTRIBUTIONS TO THE EARTH SCIENCES
HUD 30-11 HUD 30- 9B HUD 30- 9A
2-4 em
5-7
15-17
35-37
145-47
55-57
65-67
72-73
I
20
75-77
85-87
0 12 3 4
PHI UNITS
0-2 cm
110-12
13-15
20-22
35-37
40-41
KEY
CLEAR 'QUARTZ AND FELDSPAR
IRON STAINED QUARTZ AND FELDSPAR
REDDISH ROCK FRAGMENTS
GRAY ROCK FRAGMENTS (RARE)
HEAVY MINERALS (RARE)
SHELL FRAGMENTS
FORAMINIFERA
MISCELLANEOUS (COMPONENTS EACH
LESS THAN 3% COMBWED)
6LAUC0NITE
20
0
20
0
20 |
i
40
20
0
80-
60-
40-
20
0
10-12 cm
16-18
22-24
26-28
35-37
48-49
35-57
65-67 Q.
UJ
Q
75-77
1
5
82-84
90-92
0 12 3 4
PHI UNiTS
FIGURE 65.?Mineralogical analysis showing frequency distributions of the coarse fraction of
samples from slope and rise (HUD-30) cores southeast of Sable Island Bank (see Figures 15
and 18 for core locations).
NUMBER 8 53
Quartz.chart
. ORTHOQUARTZITE
CORE 14
CORE 13
CORE 11
CORE 9A
CORE 9B
FMdspar.mka Labile rock fragments
FIGURE 66.?Composition of coarse fractions of slope and
rise (HUD-30) core samples in terms of major terrigenous
components (classification after Folk 1954).
stained quartz correlates more closely with clear
quartz than with reddish rock fragments (Figure 68).
We believe, however, that this is a sorting phenomenon
rather than an indication of genesis, and that iron-
stained quartz in our cores is of both Pleistocene and
Paleozoic origin, in a ratio that we have no means of
determining.
Feldspar grains comprise 4 to 27 percent, and aver-
age 17 percent of the major terrigenous constituents.
The potassium feldspar is predominantly orthoclase,
and is more abundant (62?82 percent) than plagio-
clase. Less than 5 percent of the feldspar grains are
sufficiently altered to be distinguished from quartz
without staining.
Rock fragments comprise less than 10 percent of
the terrigenous constituents of the coarse fraction
(Figure 65). Pale yellowish-brown (10YR 6/2) to
olive gray (5Y 4/1) siltstones comprises 53 percent
of all rock fragments, and dusky red (5R 3/4), mod-
erate red (5R 4/6), and dark reddish brown (10R
3/4) comprise 30 percent (Figures 67, 69). Fine-
grained rock fragments with marked foliation (slates
or shales) comprise 8 percent of the rock fragments.
Gneiss, granite, amphibolite, and red and gray sand-
stone fragments are present in trace amounts. The
sourceland for the study area, the Canadian Maritimes
consists of ihree terrains: (1) a terrain of low to
medium grade metasediments and metavolcanics of
lower Paleozoic age intruded by granite; (2) Permo-
Carboniferous basins containing reddish, drab, and
greenish-gray, coarse to fine continental elastics; and
(3) more restricted Triassic basins containing a simi-
lar sequence. The suite of lithologies present in our
samples reflect original lithologic frequency distribu-
tions strongly modified by selective destruction of the
mechanically unstable very fine and very coarse-
grained rock types.
The sole rock type that is sufficiently abundant and
distinctive to be considered a tracer is a fine- to coarse-
grained, reddish sandstone. Its composition ranges
from subgraywacke to subarkose. The pigment ranges
from dusky red (5R 3/4) through moderate red
(5R 4/6) to moderate reddish brown (10R 4/6).
Some fragments have a carbonate cement; others
have no obvious cement. These fragments closely re-
semble the ones described by Conolly and others
(1967) from the Laurentian Channel. These workers
suggest that the fragments were derived from the
Triassic and Permo-Carboniferous rocks of Prince Ed-
ward Island and Nova Scotia. The fragments in our
cores, however, might also have traveled directly
across the Nova Scotian Shelf (Stanley and Cok
1968) ; reddish tills, derived from the Triassic and
upper Paleozoic of Northern Nova Scotia (Grant
1963) are, in fact, exposed along the sea cliffs on the
Atlantic Coast of Nova Scotia.
Glauconite comprises up to 10 percent of the coarse
fraction (Table 1). Grains range from a moderate
greenish-yellow color (10Y 7/4) and a frequently
irregular shape to a dusky green (5G 3/2) or greenish-
black (5G 2/1) variety which is commonly ellipsoidal
and sub rounded to rounded or rounded/broken. The
mineral is confined to the very fine sand fraction,
where its relative abundance correlates closely with
the relative abundance of quartz and also with the
relative abundance of this size fraction. Both light
and dark glauconite were noted in HUD-30 cores;
grains with lightness values of 5 or greater (equivalent
to medium dark gray or darker) comprise 69 percent.
There is apparently no statistically significant differ-
ence between the light to dark glauconite ratios of
the two most glauconitic-rich cores (i.e., HUD 30-14
on the slope and HUD 30-13 on the upper rise).
Dill (1968), in a detailed analysis of glauconite on
the North Carolina continental slope, detected a
systematic variation in color and properties of this
54 SMITHSONIAN CONTRIBUTIONS TO THE EARTH SCIENCES
FIGURE 67.?Photo-micrographs illustrating coarse fraction assemblages in slope and rise (HUD-
30) cores (see also Figure 65). A, brown facies on upper rise (core 13, 19 to 21 cm): very
coarse fraction showing small gray and red sandstone pebbles, basalt pebbles, and shell frag-
ment, B, brown facies on upper rise (core 13, 8 to 10 cm) : coarse sand fraction showing clear
and iron-stained quartz and rock fragments, c, olive gray facies on slope (core 14, 10 to 12
cm) : very fine sand showing terrigenous fraction with abundant glauconite. D, tan facies on
lower rise (core 9A, 55 to 57 cm) coarse sand fraction showing biogenic assemblage with
abundant Foraminifera.
mineral: the darker glauconite exhibited better crys-
tallinity, greater thermal stability, and a lower water
content; dark, well-rounded glauconite predominates
on the upper slope, while lighter, more poorly rounded
glauconite predominates on the lower slope. The two
populations represent (1) a detrital population of
dark, well-rounded grains weathering out of pre-
Recent rocks cropping out, or formerly cropping out,
on the outer shelf and upper slope, and (2) a ubiqui-
tous authigenic population associated with the fora-
miniferal slope sediments. The predominance of dark
glauconite in Nova Scotian margin samples suggests
that either the authigenic source is not as important
on the Nova Scotian slope, or that authigenic grains,
which Dill determined to be fragile relative to the
detrital group, have been selectively destroyed during
transport. Hubert and Neal (1967) in their study of
the North Atlantic petrologic province have also
noted a correlation between the abundance of very
fine glauconite and very fine quartz sand, and con-
cluded that the two had been sorted during concurrent
transport.
Shell hash and Foraminifera are also significant
components of the coarse fraction (Figure 67). Either
component may comprise up to 70 percent (Figure
70) ; together as much as 90 percent. The two cate-
NUMBER 8 55
TABLE 2.?Relative abundance of light fraction components in slope and rise (HUD-
30) cores collected south of Sable Island Bank
Core
HUD-30-14
HUD-30-13
HUD-30-11
HUD-30-9B
HUD-30-9A
1
Xi
i i(X
rocO
CU
U
M
t
N U
4-1 CO
U CucO co
O* r?1
CUPi P^H
CO
<U T3
fH Pi
O CO
70.62
66.38
55.58
20.43
26.18
CUe
?H
cO4-1
COk
o
M
9
16
13
4
4
CO
CO
1?1
CUP&4
rOa
cO
N4-J
U
cO3
o*
.73
.72
.28
.64
.53
oo
)-l CO
4-1
xi GCO CU
3 I)"O cO
CU M
0.44
3.60
4.06
0.05
0.45
r!*5 CO
CJ 4-t
O Pi
U CU^a
c0 cO
u uO m
0.93
5.92
2.08
0.70
1.76
CO1?1
cOu
CUPi
?He
cO
CU
2.20
2.17
2.96
1.34
1.33
CO
4-1
a
Bto
tou
M-l
r-ir-i
CU
xi
1.68
0.70
6.49
31.68
20.53
cO
U
<uM-l
?HPi
?Hi
o
2.85
2.47
8.10
39.80
44.64
CU
4J
co
CJ
cO
iHO
8.38
3.37
1.19
0.21
1.41
lesPu
CO
M-l
O T)CU
M 00
CU CO
g CU
!25 CO
5
8
11
5
11
gories are not completely exclusive of each other, in
that a significant portion of the shell hash consists of
comminuted foraminifers. Pelecypods, gastropods, bry-
ozoans, and calcareous algae are also common in shell-
rich samples; diatoms, radiolarians, and chitinous or
otherwise noncalcareous fragments are also observed.
Fish vertebrae were occasionally observed in the very
coarse sand fraction.
A triangular plot of the major terrigenous "light"
components (Figure 66) indicates that most samples
have coarse fractions that are subarkosic in composi-
tion. The most quartzose sand fractions are those of
olive gray slope core HUD 30-14, and the most lithic
are sand fractions of brown continental rise core HUD
30-13. These variations may be attributed, at least in
part, to grain-size control as HUD 30-14 has the finest
sand fractions and HUD 30-13 the coarsest.
The transparent heavy mineral suite observed in
the five slope and rise HUD 30 cores (Figure 71) is
the same as that observed in the upper slope (Sc-)
cores (Figure 64). Heavy minerals in cores HUD 30-
14 (gray slope facies) and HUD 30-9 (light tan
lower rise facies) are very similar and can be distin-
guished from the brown facies of cores HUD 30-13
and HUD 30-11 on the upper rise. The former two
cores contain almost 50 percent (range 40 to 54 per-
cent) hornblende, and approximately 6 to 9 percent
(range 4 to 17 percent) garnet and about the same
amount of epidote. The latter two core samples
(brown sediment type on the rise) contain less horn-
blende (range 18 to 35 percent) and epidote (range
1 to 12 percent), but relatively more garnet (5 to 39
percent). The upper rise core HUD 30-13 comprises
a high (> 23 percent) percentage of altered ("alter-
ite") grains; core HUD 30-11 contains a somewhat
higher (> 11 percent) metamorphic suite (staurolite,
kyanite, etc.)
The heavy mineral suites of the slope and rise are
the same as those on Sable Island Bank although the
proportion of mineral types differs. On the bank the
relative percent of garnet generally exceeds that of
hornblende (James and Stanley 1968) while on the
slope and rise the relative percent of hornblende is in-
variably higher than garnet. This difference can prob-
ably be attributed to size sorting (e.g., generally finer
sediments on the slope than on the shelf would contain a
lower amount of garnet, an inherently large mineral).
Samples of Lamont-Doherty cores collected on
other parts of the outer margin south of Nova Scotia
also show a similar suite of minerals (Figure 72, Table
56 SMITHSONIAN CONTRIBUTIONS TO THE EARTH SCIENCES
DSPAR
FEL
0 80-
r
0 40-
A A
ft
A*5A
? ?
A
A
? Q Q
a
o ? o 0
0
4 6 8 10
%GLAUCONITE
12
20 30 40 50
%FORAMINIFERA
60
a
< 80"
< 60"o
a: 401
O20-I
? HUD 30-9A
? HUD 30-9B
* HUD 30-11
? HUD 30-13
? HUD30-I4
2 6 10 14 18 22 26
% IRON-STAINED QUARTZ AND FELDSPAR
a:
(0a
i
ixJ
Q
N
a:
o
Q
LLJ
TAIN
RON-S
28-
24-
20-
16-
12-
8-
4-
?
A
0
a
0
o
+Q +
A
?
. A
? A
A
A ? A
A ?
A
A
A
a
aD
4 6 8 10
% ROCK FRAGMENTS
12
FIGURE 68.?Scatter plots of selected pairs of coarse fraction components in slope and rise
(HUD-30) cores.
3). In most of these samples, garnet plus hornblende
account for approximately half of the mineral suite.
In several cases, the amount of garnet exceeds that
of hornblende. The proportion is generally related to
grain size, i.e., higher amounts of garnet are generally
found in samples of coarser grain size.
Clay Mineralogy on the Outer Margin
Off Nova Scotia
Slope off Sable Island Bank
METHODS.?X-ray diffraction was used to identify
dominant clay mineral suites in the fine fraction of
NUMBER 8 57
REDDISH SANDSTONE
GRAY SANDSTONE
MISCELLANEOUS
CORE 13
MEDIUM TO VERY COARSE
SAND FRACTION
FIGURE 69.?Relative abundance of lithic fragments in coarse
fraction of samples of core HUD-13 collected on the rise
south of Sable Island Bank.
Red-stained quartz+feldspar-f
red and gray rock fragments
Non-stained quartz
+f?ldspor + glauconit? Foraminifers + shell fragments
FIGURE 70.?Triangular plot of coarse fraction suites in
slope and rise (HUD-30) cores.
cores (Sc) on the slope off Sable Island Bank. Stan-
dard methods used are detailed in Silverberg (1965).
The scattering factors developed by Freas (1962)
have been used to determine approximately clay min-
eral (illite, kaolinite, montmorillonite) percentages.
Other minerals identified in the clay fraction are
chlorite, quartz and feldspar. The former was identi-
fied by the strong 101 reflection at 3.3A and by a
weaker 100 line at 4.3A. Feldspar was inferred from
the presence of one, and sometimes two, lines in the
range 3.16-3.21 A. An occasional shoulder along the
high angle side of the 7A reflection also suggested a
7.5A reflection of feldspar.
The most accurate method of analysis involves the
comparison of peak areas with those of internal stan-
dards or of prepared standard mixtures; in our case
the assumption has been made that the peak area
are proportional to the relative quantities of the com-
ponents present (Johns, Grim, and Bradley 1954).
Before peak areas were measured, the background
level and the lower portions of each peak were
smoothed with French curves. Taking the average of
at least four planimeter readings, the areas of the 001
reflections about 14.2, 10.0, and 7.1A were recorded
for the untreated sample. Using the same background
line and peak widths, the areas of the 14A and the 7A
peaks were measured on glycolated and the HC1
treated samples, respectively.
Illite was measured as the area of the untreated
10A peak, chlorite the area of the glycolated 14A
peak, kaolinite the area of the HC1 treated 7A peak,
and montmorillonite, the difference in area of the
14A reflection before and after glycolization.
To determine the approximate composition, the
illite area was multiplied by three, the chlorite area
divided by three, and then the total corrected areas
added. The relative percentages of the various com-
ponents were then computed and converted to parts
per ten of the total. The peak areas of different com-
ponents are not directly comparable because of varia-
tions in the ability to scatter X-rays.
The decision to use the HC1 treated value of the
7A peak as the kaolinite contribution involves the
assumptions that all of the chlorite contribution is
removed by this treatment, and that the area is not
altered by acid attack on the kaolinite. An estimate
of the reproducibility of the procedure was made by
the examination of several slides sampled from the
same suspension. The diffractograms were virtually
identical, save for errors accountable by instrument
variation.
RESULTS.?Relative percentages of illite, chlorite,
montmorillonite, and kaolinite were obtained for eight
samples (Table 4). Illite is the dominant clay mineral,
making up as much as 88 percent of the Sc core sam-
ples (using Freas' scattering factors). Kaolinite ac-
58 SMITHSONIAN CONTRIBUTIONS TO THE EARTH SCIENCES
60* 59*
b cdefgh i
bed efgh i
DEPTH IN FATHOMS
60* 58*
FIGURE 71.?Relative percentages of transparent heavy minerals observed in core (HUD-30)
samples south of Sable Island Bank, a, hornblende, b, garnet; c, alterite; d, epidote; e, zircon
+ tourmaline + rutile; f, augite; g, hypersthene; h, metamorphic suite (staurolite, kyanite,
etc.); i, other minerals.
counts for 2 to 11 percent, montmorillonite 3 to 7
percent, and chlorite between 2 to 5 percent. These
percentages are only approximate.
Noteworthy is the uniformity of the clay mineral
suite in the different slope facies. The uniformity of
this assemblage within a representative slope core
(Sc-16) penetrating both olive gray and brown sedi-
ment types is illustrated in Figure 73. The consistency
NUMBER 8 59
73 76 82 247 21 2 2 1
HORNBLENDE
HYPERSTHENE
TOURMALINE
ZIRCON
16 U 23 13 1.9 2.1 10 a?
OPAQUE/NON-OPAQUE
FIGURE 72.?Variation in relative percentages of the more
abundant nonopaque heavy minerals from 12 Lamont-
Doherty core samples collected south of Nova Scotia. Num-
bers at top refer to "laboratory code" in Table 1. Data
arranged with shallower (Nova Scotia Slope) core samples
at left to deep-water (Sohm Abyssal Plain) samples at right.
Opaque to nonopaque heavy mineral ratio is given at bottom.
Heavy mineral data is also listed in Table 3.
of the clay mineral suite on a regional basis is shown
in diffractograms of samples taken from different slope
cores (Figure 74). Differences determined in the semi-
quantitative study are slight and are well within
experimental errors of this technique.
Slope and Rise Traverse South of Sable Island Bank
METHODS.?Samples were selected for clay mineral
analysis from the top and base of each HUD 30 core
in order to evaluate the mineral suites present in sedi-
ment facies on the slope and rise along the traverse
south of Sable Island Bank. The results cited in the
following study were obtained by T. T. Davies (per-
sonal communication).
Samples were disaggregated and treated to remove
calcium carbonate and iron by the procedure described
by Biscaye (1965) which was modified from Jackson
(1956). The procedure fully described by Biscaye
(1965) was closely adhered to in both sample prepara-
tion and X-ray data treatment. Gravity settlement fol-
lowed by controlled centrifugal sedimentation was
used to isolate the < 2 micron fraction which had
been saturated with calcium ions. Oriented clay pre-
cipitates were made on glass plates from equal density
clay slurries.
A Norelco X-ray diffraction apparatus was used
with a wide range goniometer and a proportional
counter using pulse height analysis and Copper K
radiation. An A.M.R. lithium fluoride monochromator
was used to reduce low angle scattering and produce
monochromatic K radiation. Each sample was scanned
at various speeds over the required angular ranges
in an untreated state, and after glycolation and heat
treatment to 250?C and 450?C.
The mineral phases identified from the diffraction
traces consist almost entirely of clay minerals identi-
fied as illite, chlorite, kaolinite, and montmorillonite.
Small quantities of quartz, feldspar, and amphibole
can be identified in each sample, but they do not
form a significant contribution to the sample min-
eralogy, and consequently they have been ignored in
the quantitative estimates of the mineral contents of
the samples.
The peak areas obtained from the various glyco-
lated samples of the 10A illite, the 17A expanded
montmorillonite, and the chlorite and kaolinite peak
that occurs at approximately 7A were measured on the
diffractometer charts, after background smoothing.
The 3.54A kaolinite peaks could be separated on
charts obtained from the untreated samples. The
ratio of these peak areas was used to define the areal
contribution provided by each mineral to the 7A
glycolated peak (Biscaye 1965). Replicate areal meas-
urements on the montmorillonite peak exhibited great
variation because the peak is located in a region of
rapidly changing background and because the poorly
crystalline mineral occurs in such small quality.
Two methods have been used in estimating the
relative abundance of the clay mineral phases in the
various samples. The relative abundance of two par-
ticular minerals is expressed as a simple ratio of their
analysis peaks. A semiquantitative estimate of the ac-
tual abundance of the clay minerals in the samples
has been made by using scattering factors and weight-
ing the peak areas. The mineral concentration is then
expressed as a percentage of the sum of the weighted
60 SMITHSONIAN CONTRIBUTIONS TO THE EARTH SCIENCES
TABLE 3.?Relative percentages of heavy minerals in samples from the rise and
Sohm Abyssal Plain (Lamont-Doherty cores) south of Nova Scotia (see also Figure
72). Numbers at top refer to samples identified in the laboratory code column in
Table 2
Andalusite
Apatite
Augite
Chlorite
Clinozoisitt
Corundum
Diopside
Enstitite
Epidote
Garnet
Hornblende
(Blua-Green)
Hornblende
(Common)
Hypersthene
Kyanite
Monazite
Rutile
Silliroanite
Sphene
Spinel
Staiarolite
Topaz
Tourmaline
Tremolite
Zircon
Zoisite
Non-opaque
counted
H-73
0.3
0.3
12.0
4O5
3
0.3
1.3
2.9
28.0
10.1
15.4
13.0
0.3
0.8
0.3
0.7
1.6
2.0
1.3
4.2
1.3
309
H-76
1.1
2.0
9.1
3.5
2.4
2.4
22.0
4.0
18.9
4.9
1.1
2.0
1.6
0.2
3.1
1.5
0.9
2.9
1.5
14.5
0.4
455
H-82
0.6
4.8
7.6
1.6
1.7
5.1
23.9
5.4
13.6
6.5
0.6
0.6
1.6
2O8
3.1
0.3
2.5
2.5
14.9
0.3
354
H-247
2O2
3.7
8.2
3.7
3.0
15.7
4.1
7.1
7.5
0.7
0.4
0o4
0.7
2.6
0o7
0.4
10o8
1.9
11.6
230
H-21
2.8
1.8
2.1
11.1
1.0
4.5
18.1
5.6
7.8
2.4
4.9
1.8
1.4
3.8
4.9
8.0
0.7
3.1
2.8
8.3
3.1
287
H-22
1.7
2.6
2.9
6.9
1.4
4,3
4.9
20.0
7O2
8.3
1.4
2.6
1.1
0.6
0.6
3.1
9.2
0.1
8.9
2.3
7.5
1.1
349
H-l
2.9
2.6
3.2
3.9
0.3
0.6
1.0
1.3
37.2
5.8
3.5
6.4
1.6
1.3
1.0
1.3
1.3
2.6
2.3
1.6
7.1
0.3
10.4
0.6
310
H-2
1.9
1.5
5.6
7.1
0.1
0.1
28.9
7.2
3.7
6.6
4.2
0.1
0ol
6.7
2?8
3O3
0.1
12.4
7.5
0.1
217
H-3
2.2
7.2
3.8
2.7
1.2
1.8
20.9
11.7
7.0
2.2
2.2
1.2
0.7
1.7
5.5
1.0
0.8
0.7
5.0
1.4
18.8
0.3
598
H-63
0.3
0.9
4.5
11.9
2.7
3.3
25.3
3.9
8.9
4.5
0.3
0.3
2.1
2.7
5.1
0.3
2.4
2.7
17.3
0.6
335
H-193
1.4
7.4
8.6
4.1
2.7
17.2
4.5
10.3
4.8
4.0
1.4
0.3
0.3
8.6
3.8
23.2
291
H-192
5.4
11.5
1.7
0.3
25.3
5.7
10.2
1.7
1.0
0.3
0.3
0.7
2.0
12.5
4.0
17.4
298
NUMBER 8 61
D.3A 13.5 A ISA
CORE SC - 16
(Untreated Samples)
I/A ho A
FIGURE 73.?Nova Scotian slope core Sc-16, diffractograms of less than 2 micron fraction.
Numbers on right refer to depth (in cm) in core (see Figure 14).
14A
FIGURE 74.?Diffractograms of less than 2-micron fraction,
slope core samples (Sc-1, -4, -7, -9, and -10) collected on the
slope south of Sable Island Bank. Numbers following hyphen
on right refer to depth (in cm) in core (see Figure 14).
peak areas assuming that the clay minerals account
for 100 percent of the sample mineralogy. To retain
consistency with Biscaye's methods the following
weighting factors have been used: four times the
illite 10A peak, the area of the montmorillonite peak
and twice the area of the 7A peak which is divided
proportionally between kaolin and chlorite [Biscaye
(1965), following Johns, Grim, and Bradley (1954),
and Weaver (1961)].
RESULTS.?The peak area ratios and the con-
structed mineral percentage are listed in Table 4
together with the mean clay mineral estimates of
Sc core samples and values given by Biscaye for the
surface sample of a Lamont-Doherty core taken closest
to the samples collected for this study. Sample SAC-
96 was obtained at a depth of 440 m on the upper
slope (above core HUD 30-14). Although there is
considerable variation in the physical properties of
the sediment within a single core there is no significant
consistent variation in the clay mineral content. The
same suite of clay minerals characterizes each of the
core samples analyzed by Biscaye (1965) and Conolly
et al. (1967) from this geographic region. Conolly
et al. (1967, page 145) note a decrease in the per-
centage of kaolinite with time (from brown Pleis-
tocene to gray Holocene facies) in the Gulf of St.
62 SMITHSONIAN CONTRIBUTIONS TO THE EARTH SCIENCES
TABLE 4.?Predominant clay minerals measured in samples from the slope and risk
south of Sable Island Bank. Percentages are only approximate. Results of Lamont'
Doherty core sample (164-47/5) studied by Biscaye (1965) are listed for comparison.
Location of sample SAC 96 is shown as station 96 in Figure 3
SAMPLE NUMBER
SAC 96
HUD-30-14 TOP
BASE
HUD-30-13 TOP
BASE
HUD-30-11 TOP
BASE
HUD-30-9A TOP
BASE
(1965)
BISCAYE SAMPLE
A164-47/5
41?43'N 59?W
RANGE OF VALUES
OF Sc-CORES
(Silverberg, 1965)
WEIGHTED PEAK AREA
WATER DEPTH
(METERS)
440
1326
2222
3795
4938
4720
(Depth
Limits)
600-1200
PERCENTAGE
KAOLIN CHLORITE
7
7
9
5
7
10
6
13
8
12
10-14
2-11
13
14
11
23
16
17
11
17
17
17
15-19
2-5
MONTMORIL-
LONITE
1
7
7
2
2
5
1
3
1
8
9
3-7
ILLITE
79
73
73
71
75
69
82
68
74
63
50
80-88
PEAK AREA RATIOS
K^C
3.58A/3.54A
0.54
0.49
0.83
0.17
0.42
0.58
0.58
0.77
0.48
0.67
7A/10A
0.18
0.18
0.25
0.13
0.18
0.28
0.15
0.38
0.22
0.37
oK/Mo
7A/17A
3.52
0.49
0.69
1.37
1.53
0.95
21.00
2.00
6.25
0.76
NO PEAK AREAS REPORTED
C/I
7A/10A1
0.32
0.37
0.30
0.42
0.43
0.48
0.26
0.48
0.58
0.52
Lawrence region. Such a distinct change could not be
recognized in the area south of Sable Island Bank.
The upper slope (Sc) cores treated in the previous
section show a slightly different proportion of clay
minerals. This slight difference of clay mineral as-
semblages can be attributed to differences in sample
preparation, and particularly the method of dis-
criminating chlorite from kaolinite by hydrochloric
acid leaching techniques. Further, differences are also
derived from a different set of weighting factors to
calculate mineral percentage concentration. The com-
position of sample SAC 96 collected just seaward of
the southern margin of Sable Island Bank is directly
comparable to that of the upper slope (Sc) cores.
Clay Mineral Suite in the Source Area
The similarity of the clay mineral suites in all deep-
water samples in this area indicates a common pro-
venance of the clay fraction for the olive gray and
brown facies. The color difference reflects different
oxidation states of iron, and not differences of clay
mineral suites, in the two sediment types.
In an earlier section we indicated that Carbonifer-
ous, Triassic, and Pleistocene deposits in New Bruns-
wick and Nova Scotia served as the predominant source
of red material of late Quaternary age on the outer
Nova Scotian margin. Red and gray Pleistocene and
Triassic units along the northern shore of the Minas
Basin in the vicinty of Five Islands, Nova Scotia, were
sampled in the summer of 1968. The clay mineral
suites in this area (Table 5) are similar to those on
the slope and rise (Table 4). The similarity of the
olive gray and brown facies clay mineral suite on the
upper continental slope (Sc cores) and that of Trias-
sic units on shore is particularly noteworthy.
Foraminifera and Stratigraphy of Surficial
Continental Margin Sediments
Foraminifera in 40 samples of Nova Scotia Slope
cores (Sc) were examined (F. Medioli, Dalhousie
University, personal communication). Twenty-two
samples were obtained from slope (Sc) cores in which
a total of 31 species are identified (Table 6). Fora-
minifera represented by only a few individuals are
NUMBER 8 63
TABLE 5.?Clay mineral composition (weighted peak area percentage method after
Biscaye 1965) of Pleistocene and Triassic samples collected near Five Islands, on
the mainland of Nova Scotia
Pleistocene
Gray mud
Brown Sandy mud
Reddish-brown mud
Triassic
Red mudstone
Gray mudstone
Red siltstone
Gray siltstone
Kaolin
12
9
9
1
1
3
1
Chlorite
32
22
25
5
5
8
5
Montmorillonite
3
5
4
3
17
7
13
Illite
53
64
63
91
77
82
81
not listed. All the species reported are living in the
North Atlantic region at the present time.
Deep-sea Quaternary chronology is commonly re-
flected by variations in selected colder and warmer
water foraminifers. Forms such a Globigerina pachy-
derma, Elphidium arcticum, and Nonion laboradori-
cum are indicative of a cold water environment. At-
tempts to base a chronology on the coiling directions
of Globigerina pachyderma were without success.
Planktonic: benthonic ratios show several signifi-
cant changes within a single core. The top and bot-
tom of core Sc-16 have relatively high ratios, with
maxima at 80 and 240 cm (Figure 75). High plank-
tonic numbers can imply an actual increase in abun-
dance of planktonic forms, such as might accompany
a rise in sea level, or it can indicate a relative reduc-
tion in benthonic forms.
A study of the distribution of individual species
provides useful stratigraphic information. In core
Sc-16 a total of 29 species were observed (num-
bers 1-29 on Table 5). A change in the planktonic-
bentonic ratio occurs at the boundary between the
brown and olive gray facies at a depth of about 209
cm from the top of the core. It is noteworthy, how-
ever, that the major faunal assemblage change occurs
at a depth of approximately 80 cm within the upper
olive gray facies. Within a section about 70 cm thick,
Rank/ Berth-
Ratio
Q
Planktonic
"BO
200
Benthonic
%E 4 2 0 (sequence as listed m table 6 )
FIGURE 75.?Distribution of Foraminifera in core Sc-16
(see Table 6).
64 SMITHSONIAN CONTRIBUTIONS TO THE EARTH SCIENCES
TABLE 6.?Foraminifera in Nova Scotian Slope core Sc-16 (see Figure 75)
PLANKTONIC FORMS
1. Glbbigerina pachyderma (Ehrenberg)
2. Globlgerina bulloides d'Orb.
3. Globigerina inflata d'Orb.
4. Globorotalla menardil (d'Orb.)
5. Globorotalla truncatulinoldes (d'Orb.)
6. Globlgerlnoides rubra (d'Orb.)
BENTHONIC FORMS
7. Sphaeroidina bulloides d'Orb.
8. Nonion labradoricum (Dawson)
9. Cassidulina norcrossi Cush.
10. Cibicldes lobatulus (Walker & Jacob)
11. Virgullna complanata Egger
12. Elphidium arctlcum (Parker & Jones)
13. Eponides umbonatus (Reuss)
14. Globobulimina auricolata (Bailey)
15. Cassidulina subglobasa Brady
16. Bulimina marginata d'Orb.
17. Bolivina subspinescens Cush.
18. Bulimina aculeata d'Orb.
19. Pullenia bulloides (d'Orb.)
20. Epistomina elegans (d'Orb.)
21. Karreriella brady (Cush.)
22. Uvigerina sp. A - after Cush.
23. Pullenia quinqueloba (Reuss)
24. Reophax atlantica (Cush.)
25. Virgulina fusiformis (Williamson)
26. Buccella frigida (Cush.)
27. Augulogerina augulosa (Williamson)
28? Bulimina exilis Brady
29. Cassidulina neocarinata Thalmann
30. Elphidium incertum (Williamson)
31. Quinqueloculina seminulum Lin.
8 forms disappear and 11 species first appear; 3 other
species make their appearance within a slightly
broader range (see Figure 75).
This faunal change corresponds with the position
of the upper plantonic to benthonic maximum. It also
corresponds with the position of the change from
cold to warmer water conditions reported by Heezen
and Drake (1964) in a similar core sequence (olive
gray facies above brown facies) taken in the Lauren-
tian Channel. Other cores collected on the continental
rise off Nova Scotia show this faunal boundary at
a depth of about 50 to 75 cm (Ericson et al. 1961);
the faunal change is believed to coincide with the
period of glacial retreat and rapid rise in sea level
at the end of Wisconsin glaciation.
Gonolly (1965) has reported a date of 24,000 B. P.
for the upper part of the brown sediment (which in
core Sc-16 occurs at a depth of 209 centimeters). The
top of the brown layer may be as young as 15,000
years old (Gonolly et al. 1967). Heezen and Drake
(1964) do not indicate any evidence for a marked
climatic change across the gray-brown contact. We
thus believe that a position of the Holocene-Pleistocene
boundary at a depth of approximately 80 cm (within
the olive gray facies) on the slope of Nova Scotia is
probably correct. The change in dominant species of
planktonic Foraminifera has been noted in Atlantic
and Caribbean cores and is estimated to have occurred
about 11,000 years B.P. (Broecker et al. 1960, Ericson
et al. 1964). If the faunal change in core Sc-16 cor-
NUMBER 8 65
responds to this climatic event, then a sedimentation
rate of 7 to 8 cm per 1000 years can be postulated for
the upper 80 cm Holocene section of olive gray sedi-
ments south of Sable Island Bank. This rate is some-
what lower than the average rate of 10 cm per 1000
years during Tertiary to Quaternary time calculated
for the slope off eastern North American (Uchupi and
Emery 1967).
A survey of Foraminifera in both olive gray slope
(HUD 30-14) and brown upper rise (HUD 30-13
and 11) cores show a dominance of cold water forms.
In contrast with these assemblages, the lower rise cores
(HUD 30-9A and B) show an alternation of cold and
warm water forms. This latter observation probably
reflects the effect of meandering of warm Gulf Stream
water masses transporting forms indigenous to the
Sargasso Sea back and forth above the Nova Scotian
rise (Cifelli and Smith 1970, and others).
Interpreting Sedimentary Sequences
and Stratigraphy
Slope and Upper Rise Fades
Petrologic investigations detailed in the previous
sections serve to define a trio of mappable sediment
types that occur on the continental slope and upper
rise south of Sable Island Bank. The distribution of
these three facies, as determined by textural, mineral-
ogical, and X-radiographic examinations of cored
surficial and upper sediment sections, is patchy (Figure
18). The three dominant sediment types on the slope
and upper rise are summarized below.
BROWN SEDIMENT TYPE.?This is an easily distin-
guishable brown pebble-sand-mud admixture (see
cores HUD 30-13 and 11, Figure 15) whose pro-
venance, as determined by the clay and coarse fraction
minerolagy, is primarily Paleozoic and Triassic source
areas in the Canadian Maritime Provinces of the
north and northwest. The sand and coarser fraction in
this facies is relatively important (as much as 50 per-
cent pebbles) and is distinguished by an important
"unstable terrigenous assemblage" consisting of red-
stained quartz and feldspar; reddish and gray rock
fragments and abundant heavy minerals (see logs of
cores HUD 30-13 and 11, Figure. 76B). The coarse
fraction also contains red sandstone and shale grains
and occasional basalt fragments in the reddish brown
mud (also noted by Marlowe 1964, and Conolly et al.
1967). It has been postulated on the basis of seismic
evidence that a Triassic trough may once have been
exposed on the Nova Scotian Shelf (Officer and Ewing
1954). It is more probable, however [as suggested by
Marlowe (1964), Silverberg (1965), Conolly et al.
(1967), James and Stanley (1968), and Stanley and
Cok (1968)], that deposits of Carboniferous and
Triassic age were eroded in the New Brunswick-
Prince Edward Island-Nova Scotian area, and served
as the predominant source of red sandstone and basalt
fragments on the outer margin.
The angular and fissile nature of red shale frag-
ments would suggest that this sediment was not trans-
ported very far. Evaluation of geological conditions in
this region, however, indicate another conclusion:
material, although angular, was in fact carried as
much as several hundred kilometers from source areas.
Transport by glacial and berg ice (ice-rafting) is a
process which would best explain the angularity of the
fragments.
The brown facies, the lowermost deposit penetrated
in cores, is pre-Holocene in age. It crops out most
commonly at or near intervalley highs and ridges, and
floors much of the lower slope and rise. Faunal
evidence indicates that the brown facies was being
deposited during the height of the Wisconsin glacia-
tion to perhaps as recently as 15,000 or even 13,000
years B.P. (Conolly et al. 1967). The Pleistocene-
Holocene boundary at about 11,000 years B.P., also
based on faunal evidence, is placed at 80 cm in Core
Sc-16, suggesting an average sedimentation rate of
about 7 to 10 cm per 1000 years during the Holocene.
On the basis of this rate, the age of the top of the
brown facies, lying at a depth of approximately 200
cm, may be as old as 20,000 years B.P. on the upper
continental slope.
OLIVE GRAY SEDIMENT TYPE.?The olive gray facies
covers upper reaches of The Gully Canyon, the Gully
Trough, and valley axes on the upper to midcon-
tinental slope. It does not cover the rise and mid and
lower part of The Gully Canyon. Silt is the pre-
dominant textural fraction (see Core HUD 30-14,
Figure 76A). Sand and pebble layers are propor-
tionately less common than in the brown facies. The
mineral components of fine- and coarse-grained frac-
tions are almost identical with those of the older
brown facies and their provenance is presumed to be
the same. It is note worth, however, that the proportion
of "stable terrigenous assemblage" (clear and unstained
quartz, feldspar, and glauconite) tends to be con-
66 SMITHSONIAN CONTRIBUTIONS TO THE EARTH SCIENCES
SLOPE
(Olive Gray Facies)
HUD 30-14
20 40 60 80 100%
UPPER RISE
(Brown Fades)
HUD 30-13
20 40 60 80 100%
MID RISE
(Brown Facies)
HUD 30-11
0 20 40 60 80 100%
LOWER RISE
(Light Tan Facies)
HUD 30-9B
20 40 60 80 100%
[ ' | Sand (and coarser) fraction.
| 1 Silt fraction
HH| Clay fraction
HUD 30-9A
20 40 60 80 100%
HUD 30-14 HUD 30-13
2? 40 ?> 80
HUD 30-11 HUD 30-9B
"Stable terrigenous assemblage1
HUD 30-9A
Clear quartz 8feldspar, glauconite
,,,. ... . HI 1 Red-stained quartz Bfeldspar; reddish rock
Unstable terrigenous assemblage | | f^ments,gray rockfrogments,heavy minerals
"Biogenic assemblage" Foraminifers, shell fragments
FIGURE 76.?A, Percent of sand, silt, and clay in slope and rise (HUD) cores, B, Percent of
the coarse fraction suites (stable terrigenous, unstable terrigenous and biogenic assemblages)
in the same cores.
siderably higher in the olive gray facies than in the
brown facies (core HUD 30-14, Figure 76B).
Bioturbate structures are also more common in this
facies. The Pleistocene-Holocene boundary lies within
the olive gray sediment type, and presumably sedi-
mentation of the olive gray facies on the upper to mid
slope has continued until recent time.
SURFICIAL SAND SEDIMENT TYPE.?The uppermost
member of the trio, only locally present on the slope,
is particularly common in depressions. It consists of
thin sand laminae composed of light and heavy
minerals similar to those of the underlying olive gray
and brown facies. The composition is also similar to
sand covering adjacent Sable Island Bank. Its position
NUMBER 8 67
in cores clearly suggests that it is the youngest of the
three slope facies and is recent (probably within
historic time) in age.
Lower Continental Rise Facies
LIGHT TAN CONTINENTAL RISE SEDIMENT TYPE.?On
the lower continental rise a fourth sediment type is
apparent. A light tan, soft to stiff mud consists of silt
and clay (cores HUD 30-9A and 9B, Figure 76A)
and is equivalent in age to the olive gray facies on the
upper and mid slope. It blankets most of the outer
margin from the lower rise to the abyssal plain. This
facies contains less sand than either the olive gray or
brown facies (Figure 76A), and its composition is
distinct: the coarser fraction is dominated by a
"biogenic assemblage" consisting of Foraminifera and
shell fragments, with subordinate amounts of the stable
and unstable terrigenous assemblages described above
(cores HUD 39-9B and -9A, Figure 76B; see also
Figure 70). In addition to disseminated terrigenous
constituents, occasional layers of terrigenous sand are
noted in rise cores; these become more frequent below
one meter from the top of the core. This terrigenous
sand is, in fact, a fifth sediment type, but it is practical
to consider it together with the light tan mud and
biogenic sand. This sequence of biogenic with inter-
calated terrigenous strata is referred to as the lower
rise hemipelagic facies. The coarse horizon observed
at a depth of about 80 cm (core HUD 30-9A, Figure
76) may correspond to the brown-olive gray sediment
boundary noted in some slope cores (see Sc-16 for in-
stance at 210 cm, Figure 38). Coarser sediment below
80 cm on the lower rise may have been deposited at the
time of the last maximum lowering of sea level at some
period between 20,000 and 15,000 years B.P. A sedi-
mentation rate of about 4 to 5 cm per 1000 years is
estimated for deposition of fine-grained facies in this
environment, or approximately half of the estimated
sedimentation rate on the continental slope. A some-
what lower rate of 3.4 cm per 1000 years was calcu-
lated for lower rise cores to the southwest (Emery
etal. 1970, page 95).
SAND AND SILT STRATA IN DEEP-SEA CORES.?Sand
and silt strata referred to above as a fifth sediment
type are frequently encountered in cores on the lower
rise and the Sohm Abyssal Plain (Figure 17). These
coarse units, accounting for as much as 50 percent of
the core sections penetrated, are graded or laminated
or both. Insufficient core coverage does not allow
core-to-core correlation of these coarse layers. How-
ever, our preliminary survey suggests that sands grade
into silts in a seaward direction. The composition of
the sand-sized fraction is similar to that of outer shelf
sand, and consists of both stable and unstable terrig-
enous assemblages. These coarse intrusions, some of
them clearly turbidites, are believed to have accumu-
lated much more rapidly than the clay- and silt-rich
strata with which they are interbedded.
Sediment Dispersal and Spillover
on Shelf-Edge Banks
Introduction
The broad shallow banks sited along the outer shelf
have played a unique role in the sediment dispersal
system of the Nova Scotian continental margin. They
have served as reservoirs for sediment received under
one set of conditions (glacial, glaciofluvial, and glacio-
aeolian) and subsequently released under a second set
of conditions (marine littoral conditions, and deeper
marine wave- and tide- agitated environments).
The varying role of the banks are reflected in the
sedimentary record of the more distal depositional
environments of this sediment dispersal system, as
will be demonstrated in the following three sections.
Sedimentation During Subaerial Exposure
During the maximum low eustatic stand of the sea in
Wisconsin time, sea level was believed to be 110 to
120 m lower [approximately 17,500 to 20,000 years
B.P. according to Curray (1965), and closer to 15,000
years B.P. according to Milliman and Emery (1968)].
During this stage the coast coincided closely with the
shelf-break, as determined by a study of terraces
(Stanley et al. 1968, and others).
Pleistocene ice tongues approached Banquereau
Bank and Sable Island Bank but apparently were un-
able to override them (Stanley and Cok 1968). Hence
the bank surfaces received enormous volumes of out-
wash during periods of maximum glacial advances
(see Figure 12). Some of this material accumulated as
a thickening outwash plain which locally underwent
aeolian modification (James and Stanley 1968,
Medioli et al. 1967). Fluvial processes resulted in
deposition of mud to pebble-size material on bank
68 SMITHSONIAN CONTRIBUTIONS TO THE EARTH SCIENCES
surfaces, and local pockets of gravel (Figure 29)
encountered on Sable Island Bank are probably relict
from this phase. Much of the material, however, must
have been bypassed to the shoreline where it became
available for deposition on the slope and beyond.
The coastal margin was dissected with deep bays
formed by the heads of the large canyons (Sable Island
Canyon and The Gully Canyon, for example) which
indent the outer shelf. These embayments un-
doubtedly served as outlets for meltwater. In some
cases they may have contained heavily stratified water
bodies with well-developed estuarine circulation, capa-
ble of serving as hydraulic traps for accumulating fine
sediment (Postma 1967). During peaks of outwash
aggradation, the resulting estuarine clay deposits
would be loaded by rapidly growing intra-estuary
deltas of coarse sediment (Swift and Borns 1967).
Transfer of all sediment-size grades from the bank tops
onto the steep bank margins was probably accelerated
during those phases when ice tongues migrated closest
to the outer banks.
The seaward edge of Sable Island Bank, serving as
the coast, received the brunt of erosion by surface
waves, and if meltwater had sufficiently stratified
coastal waters then possibly by breaking internal waves.
The relatively steep slope (5? or more) of the outer
bank margin meant that storm waves were not damped
by a shallow shelf and that the coast was under inten-
sive attack. Slumping of the heterogeneous coastal
material would be expected and would provide a large
volume of sediment for transfer downslope.
Sedimentation During and Subsequent to Inundation
In late Pleistocene time sea level began to rise first
slowly and then more rapidly (Emery 1968, his figure
15). The transgressing surf would have stripped sedi-
ment from the retreating shore face and would have
released this material on the adjacent shelf floor for
resedimentation by marine currents (Swift 1968). This
resedimentation process has resulted in a second set of
petrographic attributes being overprinted on the
original textures. Most obviously, the finer fractions
(silt and clay, have been winnowed out leaving a clean
sand lag whose pebbly admixture reflects the original
periglacial origin (see Figures 8, 9). Such hybrid
sediments have been designated palimpsest (Swift et al.
1971). Processes resulting in the modification of tex-
ture have been more effective on the outer banks than
in the deeper central shelf physiographic province.
After water deepened over the banks, the blanket
of palimpsest sand continued to undergo textural
modification and transport according to a new and
well-defined system of sediment dispersal. This system
has been best studied on Sable Island Bank where its
elements include Sable Island, the emerged crest of the
bank, and the surrounding submarine bank surface.
Sable Island consists of two parallel beach-dune
ridges which, with the rise of sea level, have converged
toward the crest of the bank until they are contiguous.
This sediment reservoir exchanges material with the
adjacent shallow sea floor according to a seasonal cycle
whereby sediment is accreted to the island in summer
by marine processes and is later deflated by strong
winter winds (James and Stanley 1967).
The island was initiated by convergence of the dune
ridges in late Pleistocene-early Holocene time (Medi-
oli et al. 1967), but it is presently maintained as a
dynamic system of water and sediment circulation.
The island and surrounding bank would, in fact, ap-
pear to be a circulating sand cell of the type described
by Van Veen (1936) from the floor of the southern
bight of the North Sea. The distribution of large-scale
sand waves indicates a clockwise circulation of resid-
ual tidal and wave-driven currents (James and Stan-
ley 1968). Large sand waves are present between 10
and 70 m depth, both north and south of Sable Island
and on the western part of the bank. Smaller sand
waves, averaging 6 to 7 m in height (Figure 77) and
having wave lengths from 300 to 1000 m, are most
abundant south of Sable Island. Their asymmetry in-
dicates a predominant wave migration from east to
west, while north of the island, sand wave asymmetry
indicates migration from west to east. A sequence of
lines trending north-south across the submerged bar
west of the island shows that sand waves in that sec-
tor are migrating northward (Figure 78). The east bar
of Sable Island (Figure 77) has been likened to an
asymmetric sand wave with a steeper northern face
suggesting predominant movement of sand toward
the north just east of the island (Figure 79).
Smaller scale structures, such as asymmetric ripple
marks as observed on most bottom photographs of
Sable Island Bank (Figure 80), show vectorial prop-
erties that are much more variable than those of sand
waves. Regional pattern of these ripples conforms in
NUMBER 8 69
EAST
SABLE
BAR
ISLAND
BATHYMETRY
from
RCA. DEPTH SOUNDER
FIGURE 77.?Diagram showing submarine topography in the vicinity of the east terminal bar
of Sable Island based on records obtained with an RCA depth sounder. The northern face is
steeper than the more gently southern slope (based on data obtained in May 1965).
a general way to the sand-wave circulation pattern:
ripples off the west end of the island indicate pre-
dominantly northward and eastward transport, and
those off the east end show southward and westward
flow; those on the northern part of the bank migrate
west and north. One station (78) at the southern
margin of the bank near the head of Sable Island
Canyon shows a predominant southerly (or off-bank)
transport.
Radial Dispersal and Sediment Spill-Over
While bed-forms indicate primarily a clockwise sys-
tem of sediment transport, textural and mineralogical
patterns on the bank surface (James and Stanley
1968) reflect a net long-term process of radial dis-
persal off the banks into the adjacent lows. Transport
patterns are clearly marked as orthogonals to isopleths
of mineralogy, mean grain size, sorting, and skewness.
In general, on Sable Island Bank, sediment is being
70
O-i-O
SMITHSONIAN CONTRIBUTIONS TO THE EARTH SCIENCES
60 58 ff
M40-
BOTTOM PROFILES ALONG SAMPLE STATIONS
SCALE 52.1 : I
SABLE ISLANO BANK
FIGURE 78.?Bathymetric profiles of the surface of Sable Island Bank plotted from PDR and
RCA depth sounder records. Sand waves and related bed-forms are shown to depths of 70 m.
Note the northward set of sand waves along selected portions of profiles.
transported from central areas of relatively coarse,
coarse-skewed sand to marginal areas of relatively fine,
fine-skewed sand. These marginal areas tend to be
less sorted than the zones where unmixing and trans-
port is most intensive. Sediment-yielding lag deposits
are richer in the heavier, coarser, heavy minerals
(opaques, garnet); sediment-receiving areas are richer
in the lighter heavy minerals (hornblende, kyanite, and
tourmaline). The intensity of iron-staining of relict
quartz is assumed to be inversely proportioned to the
intensity of abrasion during modern transport; areas
of stain-free quartz are areas indicated by other cri-
teria to be areas of active sediment unmixing and
transport. A pattern of erosion, transport, and deposi-
tion on Sable Island Bank emerges upon integration
of all data (Figure 81).
Thus, the present cyclical movement results in a net
loss of sediment from the bank surface by transfer of
sand-size material off Sable Island Bank. This transfer
of silt and sand by bottom currents from the outer-
most shelf across the shelf-break and onto the upper
slope and beyond is here designated as spillover.
There appears to be several large areas of sand
spillover: south and southwest of Sable Island, from
the outer shelf onto upper slope; north of the island,
from the bank margin into the Gully Trough; and
east of the bank, into The Gully Canyon. Details of
sediment spillover into The Gully Canyon have been
presented elsewhere (Stanley 1967). Relatively clean
palimpsest sands are noted draping onto both east and
west canyon walls (Stanley 1967, his figure 3B), pre-
sumably from the adjacent bank surfaces. Further evi-
dence of spillover in the shelf-break area occurs south
of the bank. Here, also, sand drapes from the outer
shelf onto the upper slope (Figure 29), and cores in
the area penetrate a surficial sand layer above older
muds.
NUMBER 8 71
SABLE ISLAND BANK
NEARSHORE BOTTOM PROFILES
L-tO
NAUTICAL MILES
9
FIGURE 79.?Bathymetric profiles of the surface of Sable Island Bank. Profiles are oriented
roughly parallel with Sable Island. Asymmetric sand waves appear to progress westward on
southern side and eastward on northern side of island. Net movement north of the island is
directed eastward, except between stations 38 and 46 which appears to be a zone of confluence.
Quaternary Progradation on the Nova Scotian
Outer Margin: A Summary
Introduction
The shift in sediment dispersal processes and patterns
on the Nova Scotian banks through late Quaternary
time has resulted in a corresponding sequence of dep-
ositional events on the slope and rise. The consan-
guinous nature of these two sedimentary provinces is
clearly indicated by the similarity of mineral suites
noted repeatedly in preceding sections of this study.
Thus the late Quaternary history of the study area
has been one of progradation: the seaward extension
of the shelf edge, slope, and rise by sediment accumu-
lation. Seismic study of the continental margin off
Nova Scotia has led Uchupi and coworkers (Uchupi
and Emery 1967, Uchupi 1969, Emery et al. 1970,
Uchupi, 1970) to estimate 5 kilometers of prograda-
tion, although they do not clearly indicate the strati-
graphic horizon from which this progradation was
initiated. These workers can distinguish among such
gross lithostructural units as seaward dipping strata,
slumps and slides, turbidites, and pelagic deposits. On
the other hand, our data based primarily on cores
provides much higher resolution of the thinner upper-
most section of Wisconsin to recent age. The time se-
quence of events which generated the progradation
and the resulting stratigraphic sequences, illustrated in
Figures 82 and 83, are evaluated below.
Brown Sediment Time
During Pleistocene time, large volumes of fine to
coarse reddish-brown, fluvioglacial material carried
south to the coast was rapidly transferred to the adja-
cent slope below the strandline (Figure 82A). The
high and rapidly varying rate of sediment input and
short distance to the upper slope would have been
capable of generating stratified sequences of muds,
sands, and gravels, but would not have been capable
72 SMITHSONIAN CONTRIBUTIONS TO THE EARTH SCIENCES
?C
?
*Q J3
?s
CO
O
NUMBER 8 73
ACTIVE SEDIMENT
MOVEMENT ,
ACTIVE SEDIMENT
TRANSPORT
DEPOSITION
FIGURE 81?Interpretation of bottom circulation pattern on Sable Island Bank showing areas
of dominant sediment transport and deposition (after James and Stanley 1968).
of effecting large-scale horizontal size fractionation on
the slope. The resulting heterogeneous sediment pile,
precariously poised on a relatively steep submarine
slope, would have been prone to fail by slumping.
That mass-gravity processes have been in large part
responsible for the scalloped topography of the region
south of Sable Island Bank has been shown by bottom
profiles (Pratt 1967) and subbottom profiles (Uchupi
1969, Emery et al. 1970) which reveal large slide
blocks on the lower slope and rise. These studies indi-
cate that most of the dissected topography presently
observed is clearly of relict origin. When slumping
actually began is not clearly established, but seismic
studies show that gravitational sliding was effective
during much of the Tertiary, and has certainly ante-
dated the glacial stages. However, it is reasonable to
suspect that in this region, as elsewhere, the rate and
scale of slumping must have become considerably ac-
celerated during the Pleistocene, especially during
those periods when low sea-level stands resulted in the
exposure of much of the shelf (Stanley and Silverberg
1969). The relatively nondissected slope south of
Western Bank (Figure 6) may not have received as
much sediment as in regions to the east (south of what
is now Sable Island) and, consequently, may have
been less prone to slumping.
During this time of heightened sedimentation, mass
gravity processes were also intensified in canyon heads.
The attack of open ocean storm waves on the uncon-
solidated emerging coastline would have released large
volumes of sand and gravel to littoral drift systems
intercepted by canyon heads. Periodic flushing of these
depressions would have further contributed to slope
and rise sedimentation as attested by the presence of
sand layers in rise and abyssal plain cores. Turbidity
currents or turbid-layer flows (Moore 1969) channel-
ized by the canyon system would have had a higher
probability of reaching base-of-slope environments.
Such far-traveled material would indeed have the op-
portunity to undergo horizontal size sorting as indi-
cated by the general decrease in grain size between
74 SMITHSONIAN CONTRIBUTIONS TO THE EARTH SCIENCES
NNW SABLE ISLAND
6ULLV THOUGH BANK
OUTWASH PLAIN 66 WTH0M TERRACE
? SUSPENDED SEDIMENT
SSE
Maximum late-Wisconsin
Low stand of sea level
20,000 to 18,000 years aP
PRO-GLACIAL
SUBMERGENCE STREAMS CUT OFF
OF BANK BEGINS Jf
GLACIER RETREAT
Rapid rise in sea level during perio
approx. 17,000-15,000 years B. P.
HOLOCENE (GREY-GREEN) SEDIMENTS
Climatic change at approx.
11,000 years B.R
SPILL-OVER SABLE ISLAND
SEDIMENTS \ SEDIMENTS
HEMI PELAGIC WEDGE
FIGURE 82.?Interpretation of late Quaternary to recent sedimentary progradation on the Nova
Scotian continental margin south of Sable Island Bank (Stanley and Silverberg (1969).
NUMBER 8 75
cores HUD-13 and HUD-11, respectively, on the up-
per and lower rise.
In addition to mass gravity movement on the bot-
tom, the seaward diffusion of fines (clay, silt, and pos-
sibly fine sand) would have been a second major
process during this time of heightened periglacial sed-
imentation. The meltwater runoff was heavily loaded
with fines, and received in addition material resuspen-
ded by wave attack on the coast. The intensified "estu-
arine" circulation of the coastal water mass would
have carried turbid surficial water far out to sea so
that the suspended fines would have rained out over
the slope and rise, perhaps even over the Sohm Abys-
sal Plain. Such fine sediment fallout on the upper
slope may have generated near-bottom, nepheloid,
suspension-rich layers which, in turn, would have set-
tled seaward across the rise.
In addition to the general seaward movement of
suspended sediment entrained in surficial meltwater,
masses of coarse material were carried seaward by floe
ice and calving glacier ice. This is attested by the pres-
ence of pebble clusters within cores from the brown
facies, and gravel patches seen in sea-floor photographs
(Brundage et al. 1967).
Gray Sediment Time
As the sea level rose over the banks and the bank sedi-
ment dispersal system shifted from a subaerial glacial
regime to a regime of submarine reworking, the char-
acter of sediment accumulating on the slope and rise
underwent a change (Figure 82B) . The mineral suites
of slope and rise sediments accumulating during this
transition remained qualitatively constant, although
the relative proportions shifted in some cases. An ob-
vious difference, however, was the color of material
accumulating during and subsequent to submergence
of the banks. This study has shown that color change
does not reflect a change in provenance, but simply
a change in the rate of sedimentation, such that sedi-
ment passed through the sediment-water interface
sufficiently slowly that it was reduced (Hinze and
Meischner 1968). This slower rate of sediment accu-
mulation is also demonstrated by the greater intensity
of bioturbation and increase in benthonic Foramini-
fera as noted in cores of this facies.
Most processes of sediment dispersal discussed for
brown sediment time continued, but at reduced rates.
Contorted stratification in cores, and local exposure of
Pleistocene strata normally under gray sediment, sug-
gests that slumping continued as a dominant process
on the slope in gray sediment time. The presence of
interbedded, brecciated, reddish-brown Pleistocene
and younger gray sediment in the upper sections of
cores is evidence that slumping has, in fact, continued
to the present time. Is the triggering mechanism tec-
tonic or sedimentological in origin? This continental
margin is generally considered to be a relatively stable
one, although recent earthquake activity is known to
have affected the outer continental margin east of
Sable Island Bank, particularly off Newfoundland
(Heezen and Drake 1964). Although earthquakes or
other movements could thus effectively trigger the
sudden downslope movement of sediment, the sedi-
ment regime in this environment is sufficient in itself
to account for slumping. The rate of sedimentation on
the upper and mid sectors of the slope, for instance,
though reduced, has continued to be relatively high
since the beginning of the post-Pleistocene rise in sea
level. Estimated average rates, based on an evaluation
of the total thickness of the olive gray facies (1 to
over 5 m total thickness), range from 5 to 25 cm per
1000 years.
With the retreat of the ice, outwash was no longer
supplied but littoral sands concentrated by coastal
erosion were still available for redistribution. Initially,
their volume does not appear to have been as great as
during the preceding brown sediment period. These
sands continued to be trapped in canyon heads and
depressions on the upper slope and discharged from
these lows as turbidity currents.
Suspended fines were no longer provided by melt-
water, but surf and sea floor erosion of the outer banks
provided an alternate source. In addition, far-traveled
fines were now being bypassed from recently sub-
merged portions of the central shelf landward of the
outer banks (Curray 1965, his figure 3) and trans-
ported onto the slope. Ice-rafting would have pro-
gressively diminished throughout gray sediment time
as the ice sheet withdrew from the Maritimes.
Because of the diminished input of sediment and
also because of the reduction in freshwater runoff with
concomitant reduction of "estuarine" circulation, sus-
pended sediment settled primarily on the slope. Such
material as has bypassed the slope by means of tur-
bidity currents (Erickson et al. 1952 and 1961, Gors-
line et al. 1968, Piper 1970), turbid layer flows (Moore
1969), and/or nepheloid layers (Stanley 1970) accu-
76 SMITHSONIAN CONTRIBUTIONS TO THE EARTH SCIENCES
mulated beyond the base of the slope. Biogenic mate-
rials primarily in the form of planktonic foraminiferal
tests sedimented in parts from the overlying Gulf
Stream formed a prominent admixture of this terri-
genous influx. The resulting hemipelagic wedge ap-
pears to thicken seaward within the area of study. Its
light tan color is more a consequence of slow trans-
port and attendant oxidation as in the case of abyssal
red clays, rather than an inherited pigment as in the
case of the brown sediment type. The sands of this
facies may be diverted into two populations on the
basis of sedimentary structures and textural paramet-
ers. One group displaying graded bedding is distin-
guished as the "typical" turbidite unit, the other non-
graded in origin may have been deposited by rework-
ing of turbidite sediments by marine currents.
Between the thin gray sediment prism of the slope
and seaward thickening wedge of tan hemipelagic
sediments on the lower rise there is a window through
which is exposed the older brown sediments. This sec-
tor may be a one of nondeposition as a consequence
of the southwestward flowing Western Boundary Un-
dercurrent (Heezen et al. 1966, Schneider et al. 1967).
These authors have suggested that the red sediments
of the rise are a modern rather than a relict facies;
that they are eroded from the St. Lawrence region and
swept south parallel to the contours. However, our
cores (HUD-30-11 and 13) are anomalously coarse
and contain pebbly horizons within the uppermost 10
cm. Since modern icebergs only rarely proceed south
to Newfoundland, such pebbles were most probably
transported by Pleistocene ice.
The change in microfauna noted within the olive
gray facies, also noted by others in this region (Ericson
et al. 1961), coincides with a change in climate at
about 11,000 to 10,000 years B.P. as recorded elsewhere
in the North Atlantic (Broeker et al. 1960, Ericson
et al. 1964). See c, figure 82.
Surftcial Sand Time
As the banks continued to submerge and the develop-
ment of the blanket of winnowed sand and sandy
gravel approached completion, less and less fines were
generated by littoral and sea floor erosion on the
banks. Rates of fine sediment deposition on the ad-
jacent slope decreased yet further, and spillover sands,
emplaced during occasional storms, became a pro-
gressively more prominent part of the upper- to mid-
slope section (Figure 82D.) A number of the slope
(Sc) cores are capped by relatively clean sands of this
type that may have been emplaced in historic times.
Shelf sands draped thus over gullies and depressions
of the upper slope appear to be intermittently acti-
vated as turbidity currents, which may bypass the slope
and appear as coarse horizons within the top of base-
of-slope facies (see Lamont-Doherty cores, Figure 17,
and hypothetical core d, Figure 83). Channelizing in
canyons appears to be one important method of by-
passing as attested by the presence of sand in The
Gully Canyon axis (Stanley 1967) and levees border-
ing submarine valleys (Hurley 1964, Pratt 1968).
As early as 1952 Ericson and coworkers called at-
tention to sands of shallow water origin on the ocean
floor of the Western North Atlantic and attributed
their presence to turbidity current action. More recent
studies of the textures of Atlantic deep-sea sands (Hu-
bert 1964) and of ocean floor current indicators (Hee-
zen et al. 1966, Schneider et al. 1967) have suggested
that ocean bottom currents may also be of primary
importance in the transport of deep-sea sands. Al-
though many of these deep-sea sand layers are, in fact,
current laminated and display a low clay content, it is
believed that most sands were nonetheless originally
emplaced by turbidity currents (Kuenen 1967) and
subsequently received their secondary structure and
texture through reworking by bottom currents (Stan-
ley 1970, his figure 12). Our study supports the conten-
tion of others (Hubert and Neal 1967, and others) that
mineralogic dispersal patterns formed during Quater-
nary progradation of the western North Atlantic con-
tinental margin reflect predominantly a downslope
movement of sediment normal to the continental mar-
gin with a minor contour-parallel component.
Acknowledgments
This study, like most modern oceanographic investi-
gations, is the result of a multi-author cooperative ven-
ture. We are indebted to a number of organizations
for their generous backing, including financial aid,
ship-time, materials, and facilities provided, which
made this investigation possible: Bedford Institute of
Oceanography, Dalhousie University (Institute of
Oceanography), Lamont-Doherty Geological Obser-
vatory of Columbia University, and the Smithsonian
Institution. Sampling was conducted on the CSS
Hudson, CSS Kapuskasing, and CNAV Sackville: the
NUMBER 8 77
=0 Wave- and tide-generated currents on Sable Island Bank.
>> Postulated dominant bottom current activity on rise.
????*- Resedimentation processes (mass gravity
creep,etc.) on slope andjji
(Vertical scale greatly exaggerated)
Holocene :Reworked relict (fluvio-glacial) relatively clean
sediments on Sable Island Bank; spill-over sandy
units on slope and rise.
Holocene:Gray-green silty clay prograding on slope.
Largely Holocene:lightgray-brown(hemipelagic) silty-clayon rise.
Largely Pleistocene: Brown-reddish brown pebble-sand-
silt-clay admixture (glacio-marine) prograding on slope arise.
Pre-quaternary units.
FIGURE 83.?Interpretation of late Quaternary sedimentary fades distribution on the Nova
Scotian continental margin south of Sable Island Bank. This schema of the upper sediment
sections on the slope and rise also shows postulated dispersal patterns and stratigraphy as based on
observations made in this study.
Captains; officers, and men of these ships are thanked
for support so efficiently given in the work at sea.
We acknowledge with gratitude the many persons
with whom we have had an opportunity to discuss the
various problems raised in this study and, in particular,
our many colleagues who have made special contribu-
tions to this undertaking: Dr. A. E. Gok, Adelphi
University, and Mr. G. Drapeau, Bedford Institute,
with whom we shared pleasant and productive hours
at sea and in the laboratory. Dr. Cok kindly identi-
fied heavy minerals from slope cores. We are also
indebted to Dr. T. T. Davies, University of South
Carolina, who kindly provided data on selected clay
mineral suites in slope and rise cores, Dr. J. I. Mar-
lowe, Miami Dade Junior College (formerly with
Bedford Institute of Oceanography), for generously
sharing his Gully Canyon cores with us, and Dr. F.
Medioli, Dalhousie University, for identifying Fora-
minifera in selected slope and rise cores collected off
Sable Island Bank. We thank Mrs. A. E. Cok and Mr.
H. Sheng for help in processing core and rise samples,
and Mr. L. Isham for drafting and modifying a num-
ber of figures. Drs. A. E. Cok and J. I. Marlowe crit-
ically read the manuscript.
Support for continued coordination of this project,
including travel and preparation of the manuscript,
has been provided to one of us (D.J.S.) by the Smith-
sonian Institution Research Foundation grants No.
235320 (FY 1970) and No. 436330 (FY 1971).
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Appendix
Description of Cores Collected South of the Nova Scotian Shelf by the Lamont-
Doherty Geological Observatory of Columbia University (locality number refers
to core locations shown in Figure 17)
Locality No. 1
Lamont No. Al64-46
Depth: 2610 fm (4773m;
Unit Position(cm)
Lat. 41? 20'N
Long. 59? 00' W
Core Length: 245 cm
Description
9
10
11
12
13
14
0-9
9-18
18-33
33-42
42-48
48-66
66-95
95-101
101-120
120-128
128-145
145-170
170-221
221-245
Gray lutite with silt laminae
Gray foram lutite grading down to pink
lutite at base
Gray foram sand
Red silty lutite
Brown silt
Interbedded red lutite and brown silt
Grayish red lutite grading down to red
lutite at base. Mottling 80-90 cm
Red lutite with gray mottling
Red lutite with silt laminae
Brownish gray lutite grading down to
pale red lutite at base
Interbedded red lutite and brown silt
Brownish gray lutite grading down to
mottled red lutite at base
Interbedded red lutite and laminated
silts
Mottled gray silty lutite with gray silt
at base
Locality No. 2
Lamont No. A164-47
Depth: 2580 fm (4718m)
Unit
1
2
3
4
5
6
7
8
Position (cm)
0-3
3-4
4-19
19-31
31-37
37-43
43-48
48-49
Lat. 49? 45' N
Long. 59? 00' W
Core Length: 70 cm
Description
Gray lutite
Brown silt
Gray lutite grading down to pale pink
mottled lutite at base
Brown silt grading down to foram-rich
sand
Gray foram-rich lutite grading down to
red-gray laminated lutite
Brown silt
Red lutite
Gray, silty lutite
Locality No. 2
9 49-52
10
11
52-58
58-70
Red lutite with 3 mm light gray lutite
at base
Interbedded brown silt and red silty
lutite
Interbedded silt and brownish gray silty
lutite (flowage)
Locality No. 3
Lamont No. A164-48
Depth: 2530 fm (4627m)
Unit
1
2
3
4
5
6
7
8
Position(cm)
0-15
15-18
18-40
40-230
230-250
258-272
272-400
400-450
Lat. 41 ? 30' N
Long. 59? 50' W
Core Length: 490 cm
Description
450-490
Gray silty lutite grading down to red
mottled silty lutite
Brown foram-rich silt, laminated at top
Gray silty lutite grading down to red
mottled lutite. Forams abundant
Brown silt interbedded with red and
gray lutites
Gray silty lutite grading down to red
silty lutite with brown silt at base
Red lutite
Red lutite with brown silt laminae
Gray lutite grading down to red lutite
with silt laminae
Red lutite (flowage)
Locality No. 4
Lamont No. A164-49
Depth: 510 fm (933m]
Unit Position (cm)
0-146
Lat. 42? 50'N
Long. 61? 35' W
Core Length: 473 cm
Description
1
146-148
148-160
160-267
267-473
Brown silty lutite with forams. Faint
mottling at 40 cm; sand at 60 cm
and large burrows at 65-70 cm
Pale red silty lutite
Brown silty lutite with silt at 151-153 cm
Pale red silty lutite with sand 163-165 cm
Brown silty lutite with pebbles at 305
cm and 340 cm
82
NUMBER 8 83
Locality No. 5
Lamont No. A164-54
Depth: 1230 fm (2250m)
Unit Position(cm)
Lat. 42? 05'N
Long. 63? 25' W
Core Length: 441 cm
Description
1 0-70 Pale brown silty lutite
2 70-170 Brown silty lutite. Mottled 90-120 cm
Burrows 130-170 cm
3 170-441 Pink silty lutite with pebbles throughout
Locality No. 6
Lamont No. A164-55
Depth: 1820 fm (3329m;
Unit Position(cm)
1 0-47
47-203
203-325
Lat. 41?45'N
Long. 63? 00' W
Core Length: 325 cm
Description
Pale brown silty lutite with forams and
burrows
Brown pebbly lutite
Pale brown lutite with a few silt laminae
Locality No. 7
Lamont No. A173-8
Depth: 1490 fm (2725m)
Unit Position(cm)
0-60
60-510
510-615
615-1025
Lat. 43? 40'N
Long. 58? 45' W
Core Length: 1025 cm
Description
Gray, laminated, silty lutite
Grayish brown silty lutite interbedded
with silt and fine-grained sand
Gray sand
Interbedded gray sand and brownish
gray laminated silty lutite
Locality No. 8
Lamont No. A173-9
Depth: 1775 fm (3246m)
Unit Position(cm)
Lat. 43? 30'N
Long. 58? 30' W
Core Length: 374 cm
Description
0-12
12-16
16-315
315-374
Reddish gray sandy silt
Reddish gray silty lutite
Interbedded gray sandy silt and brown-
ish gray laminated silty lutite
Fine-grained bedded sand. No grading
noted
Locality No. 9
Lamont No. A173-10
Depth: 900 fm (1646m)
Lat. 43? 15'N
Long. 60? 30' W
Core Length: 440 cm
Unit Position (cm) Description
1 0-90 Brown silty lutite with beds of red peb-
bly lutite at 16-20 cm
Locality No. 9
2 90-440 Pale red silty lutite with thin beds of
dark gray silty lutite
Locality No. 10
Lamont No. A173-11
Depth: 1426 fm (2608m)
Unit Position(cm)
Lat. 40? 00' N
Long. 60? 30' W
Core Length: 188 cm
Description
0-30
30-34
34-188
Interbedded red and gray lutite
Gray clayey silt
Gray silty lutite
Locality No. 11
Lamont No. A173-12
Depth: 1150 fm (2103m)
Unit Position(cm)
0-135
135-212
212-870
Lat. 42? 15'N
Long. 63? 30' W
Sore Lenth: 870 cm
Description
Brown silty lutite with forams
Pale red silty lutite. Bright red blebs in
upper 5 cm
Brown silty lutite with a few pebbles,
granules and forams
Locality No. 12
Lamont No. A173-13
Depth: 1600 fm (2926m)
Unit Position(cm)
0-76
76-90
90-128
128-185
185-450
Lat. 42? 15'N
Long. 63? 25' W
Core Length: 450 cm
Description
Pale pinkish brown silty lutite with
forams
Pink silty and sandy lutite with gray
mottling
Brown silty lutite with forams, sand, and
granules
Pink lutite
Brown silty lutite with scattered granules
and pebbles
Locality No. 13
Lamont No. Al 73-14
Depth: 1410 fm (2578m)
Lat. 41? 55'N
Long. 64? 35' W
Core Length: 370 cm
Unit
1
2
3
4
Position(cm)
0-22
22-26
26-40
40-65
Brownish
age)
Pale red
Interlami
lutite
Pale red
Description
gray sandy lutite
silty lutite
nated brown and
silty lutite
(some
gray
flow-
silty
84
Locality No. 13
5 65-110 Same as 26-40 cm
6 110-123 Same as 40-65 cm
7 123-245 Interlaminated red and gray silty lutite
8 245-370 Flowage
SMITHSONIAN CONTRIBUTIONS TO THE EARTH SCIENCES
Locality No. 14
Lamont No. G25-10
Depth: 910 fm (1664m)
Lat.43?50'N
Long. 59? 00' W
Core Length: 30 cm
Unit Position (cm) Description
1 0-30 Brown silty lutite. No bedding noted
Locality No. 18
Lamont No. KM 1-7
Depth: 450 fm (823m)
Lat. 43?35'N
Long. 60? 05' W
Core Length: 310 cm
Unit
1
2
3
4
5
Position (cm)
0-78
78-121
121-150
150-250
250-310
Description
Gray silty lutite. Pebbles and shells at
72 cm
Brown clayey silt with scattered shell
fragments
Interbedded brownish gray silty lutite
and silt
Gray silty lutite grading to brownish
gray clayey silt at base
Reddish brown clayey silt
Locality No. 15
Lamont No. KM 1-2
Depth: 750 fm (1372m)
Unit Position(cm)
1 0-475
Lat. 43? 10' N
Long. 60? 15' W
Core Length: 475 cm
Description
Brownish gray clayey and sandy silt.
Forams rare; pelecypod valves in up-
per 10 cm.
Locality No. 16
Lamont No. KM 1-5
Depth: 136 fm (249m)
Unit Position(cm)
Lat. 43? 35'N
Long. 59? 20' W
Core Length: 122 cm
Description
1 0-122 Brown silty sand with fragments of red
silt scattered throughout
Locality No. 17
Lamont No. KM 1-6
Depth: 310 fm (567m)
Unit
1
2
3
4
5
6
7
8
Position(cm)
0-53
53-65
65-123
123-147
147-151
151-158
158-164
164-300
Lat. 43? 35' N
Long. 59? 30'W
Core Length: 300 cm
Description
Brown clayey silt with fragments of red
lutite
Interbedded gray silt and laminated
lutite
Interbedded pink and brownish gray,
clayey, granular silt (some flowage)
Brown silt
Brown silt interbedded with gray and
pink lutite
Brown silt
Same as 147-151 cm
Brown granular lutite grading down to
a brown clayey, pebbly silt
Locality No. 19
Lamont No. SP 12-1
Depth: 700 fm (1280m)
Unit
1
2
3
4
5
6
Position (cm)
0-55
55-72
72-126
126-135
135-155
155-345
Lat. 43? 20'N
Long. 59? 55' W
Core Length: 345 cm
Description
Brownish gray silty lutite. Burrows 36-45
cm
Pink to brownish gray pebbly lutite (some
flowage)
Interbedded pink and brown silty lutite
with a few burrows and granules
Brownish gray silty lutite
Interbedded pink and brown silty lutite
Red pebbly lutite
Locality No. 20
Lamont No. SP 12-2
Depth: 680 fm (1244m)
Unit Position(cm)
1 0-95
2 95-240
Lat. 43? 20'N
Long. 60? 15' W
Core Length: 240 cm
Description
Gray silty lutite grading down to brown-
ish red granular silt at bottom. Bur-
rows abundant.
Pale red granular lutite. Bedding faint
but distinct. Granules at 98-110 cm
and 205-40 cm
Locality No. 21
Lamont No. SP 12-3
Depth: 1300 fm (2377m)
Unit Position(cm)
1 0-75
Lat. 43? 05' N
Long. 59? 55' W
Core Length: 215 cm
Description
Pale brownish gray silty lutite grading
down to brownish red lutite at base.
Burrows 15-60 cm
NUMBER 8
Locality No. 21
2 75-215 Interbedded pale red and brown silty
lutite
3 below 215 Brown silty lutite (flowage)
Locality No. 22
LamontNo. SP12-4
Depth: 1310 fm (2395m)
Locality No. 25
Lamont No. V7-63
Depth: 220 fm (402m)
Lat. 43? 10'N
Long. 59? 45' W
Gore Length: 360 cm
Unit
1
2
3
4
Position(cm)
0-78
78-172
172-182
182-210
85
Lat. 43? 00'N
Long. 61? 55'W
Core Length: 210 cm
Description
Brownish gray silty lutite grading to
clayey silt at base
Brownish gray silty lutite (some flowage)
Gray fine-grained silt
Light brown silty clay (flowage)
Unit Position(cm) Description
1 0-303
303-308
308-350
350-360
Pale brown lutite grading down to red-
dish brown silty lutite at base. Bur-
rows at 76 cm; pebbles at 85 cm;
forams in upper 40 cms
Red clayey silt
Brown granular lutite with a few forams
Pale red silty lutite
Locality No. 23
Lamont No. V 2-4
Depth: 2000 (?) fm (3658m)
Unit Position(cm)
Lat. 43? 15' N
Long. 56? 00' W
Core Length: 390 cm
Description
0-53
53-390
Red silty lutite
Red lutite with widely spaced silt lam-
inae. No flowage
Locality No. 24
Lamont No. V7-38
Depth: 2508 fm (4587m)
Unit Position(cm)
Lat. 39? 30'N
Long. 64? 55' W
Core Length: 490 cm
Description
0-8
8-11
11-40
4 40-80
5 80-84
6 84-130
9
10
11
12
13
14
15
16
17
130-140
140-142
142-158
158-160
160-195
195-300
300-400
400-415
415-435
435-447
447-490
Gray silty lutite with forams
Red lutite with fragments of gray silt
Gray silty lutite grading down to red
silty lutite
Brown silty lutite
Gray silt
Two beds of gray lutite grading down to
red lutite with silt at base of each
Gray lutite
Silt
Gray lutite grading down to pink lutite
Silt
Brownish gray lutite
Silt interbedded with gray silty lutites
Brown silty lutite
Red lutite with beds of granules
Light brown silty lutite
Foram sand
Silts interbedded with brown silty lutite^
Locality No. 26
Lamont No. V7-68
Depth: 2143 fm (4102m)
Unit Position(cm)
Lat. 40? 45'N
Long. 64? 40'W
Core Length: 245 cm
Description
1
2
3
0-1717-54
54-245
Brown silty sand with forams
Pink mottled lutite with forams
Sand grading to granules at 60 cm, grad-
ing to pebbles with cobbles at base.
Reversal of grading at 210 cm
Locality No. 27
Lamont No. V7-69
Depth: 1600 fm (2926m)
Unit Position(cm)
Lat. 40? 55' N
Long. 65? 35'W
Core Length: 612 cm
Description
1 0-20
20-110
110-127
127-186
186-210
210-260
7 260-345
8 345-450
9 450-612
Brownish gray clayey foram silt grading
down to red silt at base. Mottling in
lower part
Brownish gray clayey silt with sand and
granules
Red lutite and brown silt (flowage)
Brownish gray clayey silt grading down
to red silty clay. Isolated pebbles
throughout
Brownish gray clayey silt
Red and brown clayey silt interbedded
with silt laminae
Brownish gray clayey silt with granules
Same as 210-260 cm
Silt interbedded with brownish gray silty
lutite
Locality No. 28
Lamont No. V7-7O
Depth: 700 fm (1280m)
Lat. 41? 55'N
Long. 64? 30' W
Core Length: 560 cm
Unit Position(cm) Description
1 0?60 Brown sandy and clayey silt with burrows
86 SMITHSONIAN CONTRIBUTIONS TO THE EARTH SCIENCES
Locality No. 28
2
3
4
5
6
7
8
9
10
11
60-67
67-162
162-167
167-190
190-194
194-285
285-290
290-320
320-330
330-560
Red sandy and clayey silt with foram
laminae
Brown granular, clayey silt interbedded
with layers of shells and granules
Red sandy silt
Brown sandy, clayey silt grading down to
reddish brown silt at base
Laminated silt
Reddish brown granular, clayey silt with
scattered small pebbles
Red sandy silt
Brown sandy, clayey silt
Sand laminae
Brown sandy, clayey silt with thin beds
of sand and gravel
Locality No. 29
LamontNo. V16-213
Depth: 2065 fm (3777m)
Lat.41?40'N
Long. 62?55'W
Gore Length: 980 cm
Unit Position(cm) Description
1 0?40 Light brown foram lutite
Locality No. 29
2 40-280
3 280-409
4 409-870
5 870-980
Lutite, pale red to red at base, with
silt laminae
Light brown silty lutite interbedded with
light brown silt
Interbedded red lutite, brownish gray
lutite and silt
Flow-in
Locality No. 30
LamontNo. VI7-209
Depth: 2453 fm (4486m)
Unit Position (cm)
Lat. 40? 25' N
Long. 63? 15' W
Core Length: 415 cm
Description
1
2
3
4
5
0-38
38-140
140-209
209-244
244-415
Light brown silty foram lutite
Brown silty lutite with laminated silt
beds
Graded bed with silt at top, sand
throughout except for granular bed at
base
Red lutite
Interbedded light brown lutite and lam-
inated silt
Index
Abrasions, 33, 54
Banquereau Bank,
physiography, 3
sediments, 31, 37, 40, 43
Bioturbate structures, 19-22, 66, 75
Boulder concentration, 12, 14
Brown sediment facies,
cores in, 17
Foraminifera, 62-65
mineralogical composition, 49, 51, 57-59
on rise, 65
on slope, 31, 32, 65
structures, 21, 22
Browns Bank, 3
Canyon heads as bays, 68
Channelized transportation in canyons, 73, 75, 76
Circulating sand cell, 68, 70
Clay minerals, 37, 56-62
Clean sand facies,
cores in, 17
mineralogical composition, 49
on slope, 31, 66
structures, 19
Color of sediments,
changes in time, 75
green, 37
red, 37, 51
tan, 75
Current-produced structures, 19, 23, 24, 33
Diamictite, 12
Emerald Bank, 3
Facies on outer margin, 17-19, 65-67
Glacial erosion, 1, 9, 14
Glacial moraines, 12
Gulf Stream, 76
Gully Trough,
sediments on, 26, 36-40
topography, 3, 6
Heavy mineral suites,
Banquereau Bank, 41
Gully Trough, 38, 40
Nova Scotian Rise, 55, 56
Nova Scotian Slope, 49, 50
Sable Island Bank, 33, 55
The Gully Canyon, 41-43
Ice flow, 13, 14, 16, 75
Ice rafting, 14, 16, 19, 65, 75
Ice transport, Nova Scotian Shelf, 9, 14, 67
Kapuskasing Canyon, 7
Le Have Bank, 3
Lag deposits, 38, 70
Laurentian Channel, 2, 53
Lower rise hemipelagic facies, 67
Microfaunal changes, 76
Middle Bank, 3, 38
Nepheloid layers, 75
Northeast Channel, 2
Nova Scotian Rise,
composition of sediments, 50-56, 59-62
cores on, 17
facies, 17, 32, 33
Nova Scotian Shelf,
ice cover, 9
lakes on, 9
physiographic provinces, 3
physiography, 2, 3
rock outcrops, 14, 36
previous studies, 1
sediment composition, 13-16
Nova Scotian Slope,
cores collected on, 16, 17
facies, 17, 31, 32
mineralogical composition, 43-50, 57-62
sediment distribution, 31
topography, 6-9
Olive gray sediment facies,
cores in, 17
Foraminifera, 62-65
mineralogical composition, 49, 57-59
on rise, 32, 65
on slope, 31, 32, 65
structures, 19, 21
Organic structures in cores, 19-22
Palimpsest sediments, 2, 68, 70
Planktonic: benthonic foraminiferal ratio, 63, 64
Pleistocene-Holocene boundary, 66, 68
Progradation on Nova Scotian margin,
brown sediment facies, 71-75
clean sand facies, 76
Holocene time, 75
modern time, 76
olive gray sediment facies, 75, 76
Wisconsin time, 71
Provenance, 13, 14, 36, 38, 43, 51, 53, 62, 65
Quartz,
clear, 37, 50
green-stained, 37
stained, 14, 33, 37, 40, 43, 50
Relict sediments, 2, 10, 38, 40, 68, 76
Reworking of sediments, 11, 38, 40, 54
87
88 SMITHSONIAN CONTRIBUTIONS TO THE EARTH SCIENCES
Ripple marks, 68
Rise (see Nova Scotian Rise)
Sable Island, 2, 3, 25, 68
Sable Island Bank,
as barrier to ice, 9
as source of sediments, 9
Sable Island Bank,
circulating sand cell, 68, 69, 70
outwash plain, 67, 75
physiography, 3
sediments on, 24-26, 33, 36
surface gradients, 3
Sable Island Canyon, 7, 68
Sackville Canyon, 7
Sand waves, 68
Sea level oscillations, 1, 9, 11, 67, 68, 73, 75
Sediment dispersal, 2
Sediment distribution, Nova Scotian Shelf, 9-13
Sediment-water interface, 75
Sedimentary structures, 19-22
Sedimentation rates, 22, 65, 67, 75
Shelf (see Nova Scotian Shelf)
Shelfbreak, 6, 7, 67, 68, 70
Slope (see Nova Scotian Slope)
Slumping, 9, 33, 68, 73, 75
Sohm Abyssal Plain,
sediment sequences, 22-24
topography, 7
Sorting, 11, 12
Spillover, 67, 69-70, 76
Stable terrigenous assemblage, 65-66
Stratigraphy,
based on Foraminifera, 62-65
based on sedimentary sequence, 65-67
Submarine valleys, 7, 76
Suspension, 73, 75
Tan-light brown facies,
composition, 65
cores in, 17
on rise, 33
Terraces, 9, 67
Textural facies, Nova Scotian Shelf, 9-13
The Gully Canyon,
rock outcrops, 43
sediment distribution, 28, 31, 40-43
sediment facies, 17
topography, 3-4
Till, 13, 53
Till texture, 10
Turbidites, 19, 23, 33, 67, 76
Turbidity currents, 23, 73, 75, 76
Unstable terrigenous assemblage, 65
Weathering, 38, 43
Western Bank, 3, 9, 73
Western Boundary Undercurrent, 76
Winnowing, 11, 76
X-radiography, 19
* U.S. GOVERNMENT PRINTING OFFICE: 1972- 184- 3ia/3