njdep - njgs - geologic map series gms 06-4, bedrock ......47 kwb 78 kmv 30-9721 46 kwb 72 kmv...
TRANSCRIPT
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B'
Kp3
Kmg
Kmg
Kmv
Kmv
Kp3
Kmg
Kmv
Kwb
Kwb
Kwb
Kmv
Kmg
Kmv
Ket
Ket
Kmt
Kmt Kw
Kw
Kmt
Kw
Kml
KmlKmt
Ket
Ket
Kwb
Kmv
Kmg
Kwb
Kmv
Kp3
Kmg
Kp3
Kmg
Kmg
Kmv
Kmv
Kwb
Ket
Kmt Kw
Kmt
Ket
Kw
Kml
Kml
Tkw
Tvt
Tht
Tvt
Tht
Kns
ThtKns
Tht
TvtKns
Kns
TvtTht
Tht
Tvt
Tkw
Tkw
Kns
Kns
TkwTvt
Kml
Kml
Kw
Kmt
Kw
Kmt
Ket
KetKmv
Kwb
Kwb
Kmv
Kmg
C'
A'
CD'B
D
A
30-7693Kp3
30-8433Kp3
PG-13Kp3
30-10134Kp3
30-963Kp3
PG-12Kmg
Penns Grove well 230-467Kp3
30-8119Kp3
30-3381Kp3
30-6723Kp3
30-10762Kmg
30-9600Kmg
30-5768Kmg
30-1772Kmg
30-8393Kmg
30-5842Kmg30-9483
Kmg
30-7118Kmg
30-4708Kmg
30-8177Kmv
30-9028Kwb
30-9449Kmg
30-4403Kmg
30-4308Kwb
30-6602Kwb
30-2656Kwb
PG-15Kwb-Ket
30-5726Kmt
30-860453 Kwb72 Kmv
30-5189Kwb
30-826045 Kwb75 Kmv
30-5063Kwb
30-9881Kwb
PG-7Kwb
30-345415 Ket65 Kwb100 Kmv
30-9378Ket
30-463485 Ket-Kwb103 Kmv
30-1842Ket
30-9041Kwb
30-781323 Kwb52 Kmv
30-9374Kmg
30-4771Kmg30-6522
Kmg30-4661Kmg30-10374
Kp3 30-8768Kmg
30-6729Kmg
30-244KmgPG-6Kmg
30-8530Kmg
30-8017Kp3 30-8261
Kp3
30-9872Kmg
30-10635Kmg
30-527Kp3 30-529
Kp330-563Kp3
30-3535Kp3
30-5310Kp330-526
Kp3
30-8511Kp3
30-5441Kmg
30-266Kmg
30-8149Kp330-1143
Kp333-343
30-8061Kp3
30-620Kp3
30-5287Kp3
30-618Kp3
30-5204Kp3
33-328
30-9191Kp330-9727Kp3
30-9595Kp330-8835
Kp3
30-8190Kp3
30-7608Kmg
30-5339Kmg
30-9165Kmg
33-332Kmg 30-1815
Kmg
30-1113Kmg
30-7104Kmg
30-1064250 Kwb69 Kmv
30-618447 Kwb78 Kmv
30-972146 Kwb72 Kmv
30-7532Kwb
30-2177Kwb
30-8564Kwb
30-754387 Kwb96 Kmv30-8946
70 Kwb115 Kmv
30-522870 Ket-Kwb105 Kmv
30-2747Ket
30-391850Ket95 Kwb129 Kmv
30-76Kwb
30-916961 Kwb70 Kmv
30-899595 Kwb108 Kmv
30-917064 Kwb100 Kmv
30-3858Ket-Kwb
PG-8Kmt
30-852955 Kmt-Ket121 Kwb146 Kmv
30-7065Ket
30-6604110 Kmt-Ket-Kwb145 Kmv
30-5924Kmt-Ket
30-1017967 Ket-kwb105 Kmv
30-759197 Ket-Kwb106 Kmv
30-453270 Ket-Kwb111 Kmv
30-196110 Kmt-Ket-Kwb140 Kmv
30-66Kmt-Ket
30-6642Kmt-Ket
33-69, 30-67
30-9810Kmt-Ket
30-229, 33-70
30-10493Kw
30-6472Kw
30-7833Kw
30-246615 Kml65 Kw 30-6512
55 Kml-Kw85 Kmt125 Ket175 Kwb-Kmv
PG-9Kw
30-866639 Kmt
30-6360Kmt-Ket
30-8365Kmt-Ket
30-3734Kmt-Ket
30-6359120 Ket-Kwb145 Kmv
30-5964Ket-Kwb
30-193183 Ket-Kwb114 Kmv30-3691
105 Ket-Kwb135 Kmv
30-924878 Ket-Kwb102 Kmv
30-929057 Ket-Kwb88 Kmv
30-10745Ket-Kwb
30-9639Ket-Kwb30-9751
Ket-Kwb
30-2564Ket
30-2741Kwb
30-2455Kwb
30-425268 Kwb80 Kmv
30-9633Kwb
30-861Kwb
30-975Kmv30-10348
Kmv
33-398
30-8179Kp3
33-337Kp3
30-5600Kp3
33-397Kp3
30-9697Kmg
30-7960Kmg
30-8231Kmg
30-5266Kmg
30-9807Kmg
30-11001Kmg
30-8739Kmg
30-8729Kmg
30-8109Kmg
30-10684Kmg
30-8615Kmg
30-8207Kmg
30-6517Kmg
30-5289Kmg
30-8783Kmg
30-6520Kmg
30-10124Kmg 30-3378
Kmg
30-1063Kp3
30-514, 33-311
30-513, 33-308
well 45B
30-7979Kp3
30-2640Kp3
30-1080, 33-126
30-1234Kp3
30-8099Kp3
30-3439Kp3
30-3438Kp3
30-1049, 33-139
30-3368Kp3
30-1046254 Kp3497 Kp2517 OCzu
30-2251
30-3545Kp3
33-136Kp3
30-4667Kp330-987Kp330-492
Kp3
30-698Kp3
30-2580Kp3
30-6661Kp3
33-321Kp3
30-18Kmg
30-8848Kp330-16
Kmg
30-6210Kmg
30-6469Kmg
30-6716Kmv 30-6717
30-7941Kmv
30-476Kp3
30-3013Kp3
30-10918Kp3
30-462Kmv30-451, 33-115
30-8856Kmg
30-469, 33-114
30-9179Kmg
30-7460Kmg
30-515270 Kwb88 Kmv
PG-14Kwb
30-9268Kwb
PG-1150 Kw
33-30550 Ket90 Kwb110 Kmv180 Kmg
33-303
30-1076, 33-395Ket
30-1065, 30-1081, 33-67
30-1086, 33-64
30-948430 Kw80 Kmt-Ket150 Kwb-Kmv
30-1386440 Kmt100 Ket170 Kwb-Kmv210 Kmg
30-1386260 Kw80 Kmt125 Ket185 Kwb-Kmv
30-146743 Kml117 Kw-Kmt-Ket143 Kwb
30-515036 Kml98 Kw-Kmt126 Ket
PG-213 Kns
PG-36Tkw
30-8779Kml
30-443435 Tht-Kns
PG-5Kns
30-87555 Tkw15 Tvt53 Tht-Kns90 Kml
30-7430
30-873140 Kw60 Kmt
30-5337Kw
30-4489Kw
30-5427Kmt
30-7734Kw
30-9829Kwb
PG-13Ket-Kwb
30-1253, 33-111
30-204830-2049Kwb
33-93Kwb
30-1659Kwb
28-10466, 33-360
30-132265 Kwb90 Kmv
30-1797Kmv
30-1010, 33-393
30-1033, 33-112
30-1261Kwb
30-9167Kwb
30-964Kp3
27'30" 25' 75o22'30"39o45'
42'30"
40'
39o37'30"75o22'30"25'27'30"75o30'32'30"39o37'30"
75o30'39o45'
7000 FEET1000 10000 2000 3000 4000 5000 6000
.5 1 KILOMETER1 0
SCALE 1:24 0001/ 21 0 1 MILEM
AG
NE
TIC
NO
RT
H
APPROXIMATE MEANDECLINATION, 1993
TR
UE
NO
RT
H
�
LOCATION IN NEW JERSEY
11.5O
CONTOUR INTERVAL 5 FEET
NATIONAL GEODETIC VERTICAL DATUM OF 1929
MARCUS HOOK
WO
OD
STO
WN
SALEMDELAWARE CITY
BEDROCK GEOLOGY OF THE PENNS GROVE AND WILMINGTON SOUTH QUADRANGLES,
SALEM AND GLOUCESTER COUNTIES, NEW JERSEY
byScott D. Stanford and Peter J. Sugarman
2006
Geology mapped 2003-2004Cartography by Scott Stanford and Michael Girard
Reviewed by John Jengo, Karl Muessig, Lloyd Mullikin, Kelvin Ramsey
Base from U. S. Geological Survey Penns Grove (1995) and Wilmington South (1997) quadrangles
Research supported by the U. S. Geological Survey, National Cooperative Geologic Mapping Program,under USGS award number 03HQAG0091. The views and conclusions contained in this document are
those of the authors and should not be interpreted as necessarily representing the official policies,either expressed or implied, of the U. S. Government.
DEPARTMENT OF ENVIRONMENTAL PROTECTIONLAND USE MANAGEMENTNEW JERSEY GEOLOGICAL SURVEY
Prepared in cooperation with theU. S. GEOLOGICAL SURVEY
NATIONAL GEOLOGIC MAPPING PROGRAM
BEDROCK GEOLOGY OF THE PENNS GROVE AND WILMINGTON SOUTH QUADRANGLES,SALEM AND GLOUCESTER COUNTIES, NEW JERSEY
GEOLOGIC MAP SERIES GMS 06-4
200
0
-200
-400
-600
-800
EL
EVA
TIO
N (
feet
)
VERTICAL EXAGGERATION 10X
surficialdeposits
Kp3
Kp2
OCZu
A
DE
LA
WA
RE
RIV
ER
US
RO
UT
E 1
30
SE
CT
ION
BB
'
33-13930-1050
E, G 30-225133-31130-514
E
33-30830-513 IN
TE
RS
TAT
E R
OU
TE
295
NJ
TU
RN
PIK
E
surficial deposits
SA
LE
M R
IVE
R
Kp3
Kp2
OCZu
BE
ND
INS
EC
TIO
N
surficial depositsKet
Kwb
Kmv
Kmg
Kp3
Kp2
OCZu
30-1065
PO
INT
ER
S-A
UB
UR
N R
D
33-6430-1086
E, G
SE
CT
ION
CC
'
Tkw Tkw
Tvt TvtThtKnsKml
KwKmt
Ket
Kwb
Kmv
Kmg
Kp3
Kp2
PO
INT
ER
S-
SW
ED
ES
BO
RO
RD
A'200
0
-200
-400
-600
-800
200 0
-200
-400
-600
-800
ELEVATION (feet)
C
HAINES NECK RD
surf
icia
l dep
osi
ts
Km
lK
wK
mt
Ket
Kw
b
Km
v
Km
g
Kp
3
Kp
2
OC
Zu
VE
RT
ICA
L E
XA
GG
ER
AT
ION
10X
BEND IN SECTIONSECTION AA'
BEND IN SECTION
BEND INSECTION
POINTERS-AUBURN RD
SALEM RIVER
30-7
430
33-6
430
-108
6E
, G33
-67
30-1
081
E33
-395
30-1
076
G
33-3
03G
surf
icia
l dep
osi
ts
US ROUTE 40
Kw
Km
tK
et
Kw
b
Km
v
Km
g
Kp
3
Kp
2
OC
Zu
TWO PENNY RUN
BEND INSECTION
33-6
930
-67
G
33-7
030
-229
Gsu
rfic
ial d
epo
sits
Km
l
Kw
Km
tK
et
Kw
b
Km
v
Km
g
Kp
3
OC
Zu
C' 20
0
0 -200
-400
-600
-800
D20
0 0
-200
-400
-600
-800
ELEVATION (feet)
surf
icia
l dep
osi
ts
DELAWARERIVER
DELAWARE DRIVE
Kp
3
Kp
2
OC
Zu
VE
RT
ICA
L E
XA
GG
ER
AT
ION
10X
SALEM DRIVE
FORT MOTT RD
NJ ROUTE 49
BEND INSECTION,SECTION BB'
BEND INSECTION
BEND INSECTION
33-1
1230
-103
330
-101
0E
, G
33-3
6028
-104
66E
Kw
b
Km
v
Km
g
Kp
3
Kp
2
surf
icia
ld
epo
sits
MAHONEY RD
COUNTY ROUTE 551
30-2
048
E, G
33-1
1130
-125
3G
Kw
Km
tK
et
Kw
bK
mv
Km
g
Kp
3
Kp
2
D' 20
0
0 -200
-400
-600
-800
Kml
Kw
Kmt
Ket
Kwb
Kmv
Kmg
Kp3
OCZu
UNCONFORMITY
UNCONFORMITY
UNCONFORMITY
UNCONFORMITY
Campanian
Late Cretaceous
Turonian-Coniacian
Cenomanian
Late Proterozoic-early Paleozoic
CORRELATION OF MAP UNITS
Kp2 Albian Early Cretaceous
UNCONFORMITY?
UNCONFORMITY
UNCONFORMITY
UNCONFORMITY
UNCONFORMITY
Tkw
Tvt
Tht
Kns Maastrichtian
Paleocene
Miocene
Tertiary
INTRODUCTION
Bedrock of the Penns Grove and Wilmington South quadrangles includes unconsolidated Coastal Plain formations that overlie metamorphic and igneous basement rocks. The Coastal Plain formations include sand, clay, and glauconite clay laid down in coastal, nearshore marine, and continental-shelf settings between 110 and 20 million years ago (Ma). The underlying metamorphic rocks are much older and were originally laid down as sediments, or intruded as magma, between 700 and 420 million years ago, and compressed and deformed several times. The lithology and age of the formations are provided in the Description of Map Units. Age relations are also summarized in the Correlation of Map Units. Four cross sections show the subsurface geometry of the formations along the line of section. Further details on the regional stratigraphy of the Coastal Plain formations are provided by Owens and others (1998). Surficial deposits of Pliocene and Quaternary age overlie the bedrock formations in most of the map area. The surficial deposits are mapped by Stanford (2006).
DESCRIPTION OF MAP UNITS
KIRKWOOD FORMATION--Silty clay to silty, very fine sand. Yellow, reddish-yellow, white, light gray. As much as 30 feet thick. The Kirkwood sediments in the map area are within the informal lower member of the Kirkwood Formation (Owens and others, 1998), also known as the Alloway Clay in outcrop in this area (Isphording and Lodding, 1969). The lower member is of early Miocene age (22-21 Ma) based on strontium stable-isotope ratios (Sugarman and others, 1993). Unconformably overlies the Vincentown, Hornerstown, and Navesink formations.
VINCENTOWN FORMATION--Glauconitic clayey quartz sand, medium grained. Locally calcareous and fossiliferous, with foraminifera and bryozoan detritus. Glauconite occurs primarily in soft grains of medium sand size. Yellowish-brown, olive, light gray. As much as 40 feet thick. Late Paleocene in age, based on foraminifera (Olsson and Wise, 1997). Unconformably overlies the Hornerstown Formation.
HORNERSTOWN FORMATION--Glauconite clay. Olive, green, black where unweathered, olive brown with brown to reddish-brown mottles where weathered. Glauconite occurs primarily in soft grains of fine-to-medium sand size, with botryoidal and accordion shapes. Quartz, mica, feldspar, and phostphatic material also occur as minor constituents. Between 20 and 25 feet thick. Early Paleocene in age based on foraminifera (Olsson and Wise, 1997). Unconformably overlies the Navesink Formation.
NAVESINK FORMATION--Glauconite clay to sandy clay. Locally fossiliferous, with calcareous shell beds. Olive, green, black where unweathered; olive brown to olive yellow where weathered. As much as 15 feet thick. Glauconite occurs primarily in soft grains of medium-to-coarse sand size, with botryoidal form. Quartz sand, medium grained, is the principal accessory. Pyrite, mica, and phosphatic material are minor constituents. The basal few feet of the Navesink contain a glauconitic quartz sand with granules and black phosphate pebbles. Late Cretaceous (Maastrichtian) in age based on foraminifera (Olsson, 1964). Strontium stable-isotope age estimates for the Navesink range between 69-67 Ma (Sugarman and others, 1995). Unconformably overlies the Mount Laurel Formation.
MOUNT LAUREL FORMATION--Quartz sand, slightly glauconitic, medium grained. Yellowish-brown to reddish-yellow where weathered, gray where unweathered. As much as 70 feet thick in map area. Contains traces of feldspar, mica, and phosphate pebbles. The upper several feet are a coarse sand with granules and pebbles; this interval also contains glauconite from the overlying Navesink Formation concentrated in burrows. Late Cretaceous (late Campanian) in age based on nannoplankton (Sugarman and others, 1995). Grades downward into the Wenonah Formation.
WENONAH FORMATION--Quartz sand, micaceous, slightly glauconitic, fine- to very fine-grained. Yellow to very pale brown where weathered, gray to pale olive where unweathered. As much as 40 feet thick. Late Cretaceous (late Campanian) in age based on pollen (Wolfe, 1976) and ammonite fossils (Kennedy and Cobban, 1994). Grades downward into the Marshalltown Formation.
MARSHALLTOWN FORMATION--Glauconitic clayey quartz sand, fine- to medium-grained. Olive to dark gray where unweathered, brown to olive brown where weathered. As much as 20 feet thick. Late Cretaceous (middle Campanian) in age, based on nannoplankton (Sugarman and others, 1995). Unconformably overlies the Englishtown Formation.
ENGLISHTOWN FORMATION--Quartz sand, fine- to medium-grained, with thin beds of clay and silt. Sand is white, yellow, and light gray where weathered, gray where unweathered. Silt and clay are light gray to brown where weathered, dark gray to black where unweathered. As much as 40 feet thick. Sand contains some lignite and mica and minor amounts of glauconite; silt and clay contain some mica and lignite. Late Cretaceous (early Campanian) in age, based on pollen (Wolfe, 1976). Grades downward into the Woodbury Formation.
WOODBURY FORMATION--Clay with minor thin beds of very fine quartz sand. Dark gray and black where unweathered, yellowish brown to brown where weathered. As much as 50 feet thick. Clay is micaceous, with some pyrite and lignite and traces of glauconite. Late Cretaceous (early Campanian) in age based on pollen (Wolfe, 1976). Grades downward into the Merchantville Formation. Minard (1965) includes this clay in the Merchantville or Englishtown formations in the adjacent Woodstown quadrangle. It is mapped separately here because the general absence of sand beds distinguishes it from the overlying Englishtown Formation and the absence of glauconite distinguishes it from the underlying Merchantville Formation.
MERCHANTVILLE FORMATION--Glauconitic fine-sandy silty clay to clayey silt. Olive, dark gray, black where unweathered, olive brown to yellowish brown where weathered. As much as 30 feet thick. Glauconite occurs primarily as soft grains of fine-to-medium sand size. Sand fraction is chiefly quartz; feldspar, mica, and pyrite are minor constituents. Iron cementation is common. Late Cretaceous (early Campanian) in age based on ammonite fossils (Owens and others, 1977). Unconformably overlies the Magothy Formation.
MAGOTHY FORMATION--Quartz sand, fine- to very coarse-grained, and clay and silt, thin-bedded. Sand is white, yellow, light gray where weathered, gray where unweathered. Clay and silt are white, yellow, brown, rarely reddish-yellow where weathered, gray to black where unweathered. Gray colors are dominant. Sand includes some lignite, pyrite, and minor feldspar and mica. Silt and clay beds include abundant mica and lignite. Late Cretaceous (Turonian-Coniacian) in age based on pollen (Christopher, 1979, 1982; Miller and others, 2004). Unconformably overlies the Potomac Formation. Contact with Potomac Formation placed at change from predominantly gray clay and silt in Magothy Formation to red clay in the Potomac, as reported in well or boring logs, or at increased gamma-ray intensity, decreased electrical resistance, and increased spontaneous potential on geophysical logs, recording the thicker clays in the Potomac. Thickness ranges from 40 to 50 feet over most of the map area, to 150 feet in the northeast corner of the Penns Grove quadrangle. This thickening is due, in part, to erosion of the Potomac Formation before the Magothy was deposited. Regionally, the Magothy thickens, and the Potomac correspondingly thins and pinches out, northeastward along strike in New Jersey (Owens and others, 1998). The upper 10 to 15 feet of the Magothy Formation as mapped here may include the Cheesequake Formation, which has been identified biostratigraphically in coreholes in this region (Miller and others, 2004; Sugarman and others, 2004) but, as a largely non-glauconitic silt, cannot be lithically distinguished from the Magothy based on outcrop and well data in the map area.
POTOMAC FORMATION--Quartz sand, fine- to very coarse-grained, and clay and silt, thin- to thick-bedded; minor pebble-to-cobble gravel. Sand is white, yellow, light gray where weathered, gray where unweathered. Clay and silt are white, yellow, brown, reddish-yellow, red where weathered, gray where unweathered. Clay beds are as much as 10 feet thick, sand beds are as much as 50 feet thick. Clay beds are more abundant than sand beds. Total thickness of formation as much as 650 feet in map area. The Potomac Formation in the map area is divided into two informal subunits (Kp3, Kp2) based on pollen zonations (Doyle and Robbins, 1977), although it is not known if the
boundary between the units is an unconformity. Unit 3 (Kp3) is of Late Cretaceous (early Cenomanian) age. Unit 2 (Kp2) is present in the subsurface only, and is mapped based on a regionally traceable 30-to-50-foot thick sand at the base of unit 3, as identified in geophysical and lithologic well logs (McKenna and others, 2004; Sugarman and others, 2004). Unit 2 is of Early Cretaceous (Albian) age (Doyle and Robbins, 1977; Owens and others, 1998). The Potomac Formation unconformably overlies Late Proterozoic and early Paleozoic bedrock.
LATE PROTEROZOIC AND EARLY PALEOZOIC METAMORPHIC AND IGNEOUS ROCKS--Gray schist and gneiss. Upper 5 to 50 feet is commonly weathered to a brown, red, gray, or greenish gray micaceous sandy clayey saprolite. Of Late Proterozoic and early Paleozoic age. Includes the Wissahickon Formation and related rocks of the Potomac-Philadelphia-Hartland terrane of Late Proterozoic, Cambrian, and Ordovician age (Volkert and others, 1996; Schenck and others, 2000). In subsurface only.
MAP SYMBOLS
Contact--Approximately located.
Formation observed in outcrop, excavation, or hand-auger hole.
Well or boring, location accurate to within 200 feet--Number followed by map-unit symbol is depth, in feet below land surface, of base of unit (or total depth of well, if within unit OCZu) as inferred from driller's log or geophysical log (for wells not shown on sections). Map-unit symbol without a depth indicates uppermost formation as inferred from driller's log; for these wells, underlying formations cannot be positively identified. Identifiers of the form 33-xxx are U. S. Geological Survey Ground Water Site Inventory numbers. Identifiers of the form 30-xxxx are N. J. Department of Environmental Protection well permit numbers. Identifiers of the form PG-xx are auger borings drilled by D. S. Powars and J. P. Owens of the U. S. Geological Survey. Well 45B (section BB') is from Leggette, Brashears, and Graham, Inc. (1979). Penns Grove well 2 (section BB') is from Woolman (1902, p. 92).
Well or boring, location accurate to within 500 feet--Identifiers and symbols as above.
Geophysical log--On sections. "G" indicates gamma-ray log, shown in red, intensity increasing to right. "E" indicates electric log, shown in blue, with spontaneous potential shown on left-hand curve (voltage increasing to right) and resistance shown on right-hand curve (resistance increasing to right).
Surficial deposits--On sections, shown where more than 10 feet thick.
REFERENCES
Christopher, R.A., 1979, Normapolles and triporate pollen assemblages from the Raritan and Magothy Formations (Upper Cretaceous) of New Jersey: Palynology, v. 3, p. 73-121.
Christopher, R. A., 1982, The occurrence of the Complexiopollis-Atlantopollis Zone (palynomorphs) in the Eagle Ford Group (Upper Cretaceous) of Texas: Journal of Paleontology, v. 25, p. 525-541.
Doyle, J.A., and Robbins, E.I., 1977, Angiosperm pollen zonation of the Cretaceous of the Atlantic Coastal Plain and its application to deep wells in the Salisbury embayment: Palynology, v.1, p. 43-78.
Isphording, W. C., and Lodding, W., 1969, Facies changes in sediments of Miocene age in New Jersey, in Subitzky, S., ed., Geology of selected areas in New Jersey and eastern Pennsylvania and guidebook of excursions: New Brunswick, N. J., Rutgers University Press, p. 7-13.
Kennedy, W. J., and Cobban, W. A., 1994, Ammonite fauna from the Wenonah Formation (Upper Cretaceous) of New Jersey: Journal of Paleontology, v. 68, no. 1, p. 95-110.
Leggette, Brashears, and Graham, Inc., 1979, Progress report of contaminated ground-water recovery system at E. I. DuPont de Nemours and Co., Inc., Chambers Works, Deepwater, N. J.
McKenna, T. E., McLaughlin, P. P., and Benson, R. N., 2004, Characterization of the Potomac aquifer, an extremely heterogeneous fluvial system in the Atlantic coastal plain of Delaware: Delaware Geological Survey Open File Report 45, 1 p., 3 plates.
Miller, K. W., Sugarman, P. J., Browning, J. V., Kominz, M. A., Olsson, R. K., Feigenson, M. D., and Hernandez, J. C., 2004, Upper Cretaceous sequences and sea-level history, New Jersey Coastal Plain: Geological Society of America Bulletin, v. 116, no. 3-4, p. 368-393.
Minard, J. P., 1965, Geologic map of the Woodstown quadrangle, Gloucester and Salem counties, New Jersey: U. S. Geological Survey Geologic Quadrangle Map GQ-404, scale 1:24,000.
Olsson, R. K., 1964, Late Cretaceous planktonic foraminifera from New Jersey and Delaware: Micropaleontology, v. 10, no. 2, p. 157-188.
Olsson, R. K., and Wise, S. W., Jr., 1987, Upper Maestrichtian to middle Eocene stratigraphy of the New Jersey slope and coastal plain: Initial reports of the Deep Sea Drilling Project, volume XCII, Washington, D. C., p. 1343-1365.
Owens, J. P., Sohl, N. F., and Minard, J. P., 1977, A field guide to Cretaceous and lower Tertiary beds of the Raritan and Salisbury embayments, New Jersey, Delaware, and Maryland: American Association of Petroleum Geologists and Society of Economic Paleontologists and Mineralogists, 113 p.
Owens, J. P., Sugarman, P. J., Sohl, N. F., Parker, R. A., Houghton, H. F., Volkert, R. A., Drake, A. A., Jr., Orndorff, R. C., 1998, Bedrock geologic map of central and southern New Jersey: U. S. Geological Survey Miscellaneous Investigations Series Map I-2540-B, scale 1:100,000.
Schenck, W. S., Plank, M. O., and Srogi, L., 2000, Bedrock geologic map of the Piedmont of Delaware and adjacent Pennsylvania: Delaware Geological Survey Geologic Map Series 10, scale 1:24,000.
Stanford, S. D., 2006, Surficial geology of the Penns Grove and Wilmington South quadrangles, Salem and Gloucester counties, New Jersey: N. J. Geological Survey Geologic Map Series GMS 06-5, scale 1:24,000.
Sugarman, P. J., Miller, K. G., Burky, D., and Feigenson, M. D., 1995, Uppermost Campanian-Maestrichtian strontium isotopic, biostratigraphic, and sequence stratigraphic framework of the New Jersey Coastal Plain: Geological Society of America Bulletin, v. 107, p. 19-37.
Sugarman, P. J., Miller, K. G., Owens, J. P., and Feigenson, M. D., 1993, Strontium isotope and sequence stratigraphy of the Miocene Kirkwood Formation, southern New Jersey: Geological Society of America Bulletin, v. 105, no. 4, p. 423-436.
Sugarman, P. J., Miller, K. G., McLaughlin, P. P., Jr., Browning, J. V., Hernandez, J., Monteverde, D., Uptegrove, J., Baxter, S. J., McKenna, T. E., Andres, A. S., Benson, R. N., Ramsey, K. W., Feigenson, M. D., Olsson, R. K., Brenner, G., and Cobbs, G., III, 2004, Fort Mott site, in Miller, K. G., , Sugarman, P. J., Browning, J. V., and others, eds., Proceedings of the Ocean Drilling Program, Initial Reports, v. 174AX, p. 1-50.
Volkert, R. A., Drake, A. A., Jr., Sugarman, P. J., 1996, Geology, geochemistry, and tectonostratigraphic relations of the crystalline basement beneath the Coastal Plain of New Jersey and contiguous areas: U. S. Geological Survey Professional Paper 1565-B, 48 p.
Wolfe, J. A., 1976, Stratigraphic distribution of some pollen types from the Campanian and lower Maestrichtian rocks (upper Cretaceous) of the Middle Atlantic States: U.S. Geological Survey Professional Paper 977, 18p., 4 pls.
Woolman, Lewis, 1902, Artesian wells: N. J. Geological Survey, Annual Report of the State Geologist for the Year 1901, p. 53-129.
Tkw
Tvt
Tht
Kns
Kml
Kw
Kmt
Ket
Kwb
Kmv
Kmg
Kp3
Kp2
OCZu
30-924778 Ket102 Kwb
30-474873 Ket107 Kwb
E, G
B200
0
-200
-400
-600
-800
EL
EVA
TIO
N (
feet
)
VERTICAL EXAGGERATION 10X
33-11230-1033
E, G
SE
CT
ION
DD
'
IND
US
TR
IAL
RD
surficial deposits
KwbKmvKmg
Kp3
Kp2
NJ
RO
UT
E 4
9
NJ
RO
UT
E 4
9
BE
ND
INS
EC
TIO
N
BE
ND
INS
EC
TIO
N
33-11430-476
E
33-11530-451
E30-6717
G
surficial deposits
Kp3
Kp2
OCZu
33--12630-1080
E30-2440
INT
ER
STA
TE
R
OU
TE
295
SA
LE
M C
AN
AL
BE
ND
INS
EC
TIO
N
SE
CT
ION
AA
'
well 458E 33-328
E33-398
E
BE
ND
INS
EC
TIO
N
WH
OO
PIN
G J
OH
N C
RE
EK
HE
NB
Y C
RE
EK
BE
ND
INS
EC
TIO
N
WA
LK
ER
AV
E
33-343E
Kp3
Kp2
OCZu
surficial deposits
Penns Grovewell 2
MA
IN S
T
BR
OA
D S
T
Kp3
OCZu
B'200
0
-200
-400
-600
-800