HARVARD UNIVERSITY

Pel ee

LIBRARY
OF THE

Museum of Comparative Zoology

6lé

MEMOIRS

uae

MUSEUM OF COMPARATIVE ZOOLOGY
HARVARD COLLEGE

“ VOL. LIT

- CAMBRIDGE, MASS, U.S. A.
Printed for the ayuseum _

ae

1934

MEMOIRS

OF THE

MUSEUM OF COMPARATIVE ZOOLOGY

HARVARD COLLEGE

VOL. LIT

CAMBRIDGE, MASG., U.S. A.

Printed for the ADuseum
1934

Memoirs of the Museum of Comparative Zodlogy
AT HARVARD COLLEGE

Vou. LIT

GEOGRAPHY AND GEOLOGY OF THE REGION INCLUDING
CAPE COD, THE ELIZABETH ISLANDS, NANTUCKET,
MARTHAS VINEYARD, NO MANS LAND AND BLOCK
ISLAND

BY

J. B. WOODWORTH ann EDWARD WIGGLESWORTH

Le
Wir Turrty-£1cHt Plates

CAMBRIDGE, MASS., U.S. A.:
Printed for the Museum
1934

CONTENTS

Geography and geology of the region including Cape Cod, the Elizabeth Islands, Nan-
tucket, Marthas Vineyard, No Mans Land and Block Island. By J. B. Woop-
WoRTH and EpwarD WIGGLESWORTH. i-xvi plus 322 pp., 38 plates. July, 1934.

CONTENTS

Part I. OurLine oF THE GEOGRAPHY AND GEOLOGY oF THE Recion, By J. B. WoopwortH

PAGE

Introduction : : : : : . : : : : : : : : 3
Topography : : : : 5 : : : : : : : : : 3
General geology : : : : : : : : : : : : 9
re: Unebineots paccincat : : : : : : : : . : : 9
Cretaceous system : : : : : : 5 : : : : 13
Tertiary system . : : : : : : : : 15
: Eocene and Otic series . : : . : . : . : : 15
Miocene series . : . : : : : : : : : 17
Earlier stations : : : : : : : : = 2 17
Character of the deposits : : : : : j : 19
Gastroliths in the greensand at Cae Head : : : . : : 19
Greensand at Duxbury and Marshfield . : : : ; : : 20

Origin of the greensand . : : : : . : : 21
Chemical analyses of the ec : : : : 23

Fossils from the greensand at Gay Head and ee ; : : 24

Fossils from the greensand at Marshfield and as : : . 27

Miocene fossils from other deposits : : 5 : . 27
Phosphatic nodules in the greensand : : : : : : 28
Eastward extension of the Miocene deposits . : : : : : 29

Pliocene series : : : ; : : : : : : : ; 30
Quaternary system : : : 5 . : : : : : : 32
Pleistocene series . : . : : : : : : : : 32
Early sevestinions : : 32
Classification of the Plesingeae deposile wdopied in Fee report : : 30
Aquinnah conglomerate (osseous conglomerate) . : = 36

First stage of glaciation : . : : . 38

Dukes boulder bed (first eed substage) ; : : : . 39

Weyquosque formation os : : : : : . 40

Sankaty sand (marine) . . : : : . : : 41

Mannetto formation (glacial) . ; . : : : : i 45

Folding at Gay Head. : : : : : : : : 45
Post-Manetto -ietheal stage. : : : : : : : 46

Jameco stage of glaciation . : : : : : : . : 47

Jameco formation . : : : : : : : 47

Ferruginous boulder oe : : . : : : : 47

Coarse gravel of Jameco type . i : : : : : 47

Moshup till member : : : : : : 5 : 48

Gardiners interglacial stage. : : : : : . : 48
Gardiners clay c : : : : : . 48

Distribution and graces : : : : : : 48

Fossils and origin. : : 5 : : : . ; 49

Jacob transitional stage : : : : ; : : : : 51

Jacob sand. : : : : : ‘ : : : . 51

vi CONTENTS
PAGE
Manhasset stage of glaciation : : : : : : : : 52
Manhasset formation : : : : : : : : 52
Character and odes : ; : : . : : 52
Herod gravel member : : - : : : : ; 53
Montauk till member : : : : : : : : 53
Hempstead gravel member : : : : : : 55
Vineyard interglacial stage . : : : : : S : : 56
Wisconsin stage of glaciation : : : . : ; : : 58
General relations. : : : : : : : : : 58
Nantucket moraine : : : : : : : : : 59
Falmouth moraine . oe : : : : : : ' 61
Interlobate moraines : : : : : : : : : 62
Certain glacial features of the district . : C : S 64
Deformation and dislocation of beds by slack hivist : : 65
Tentative correlation of the glacial deposits and Be secs : 68
Classification of the glacial deposits : : : : : : 72
The larger glacial erratics of the district : ; : : : 74,
Postglacial changes : : . : : : : : : ‘ 76
Swamps and marshes : 76
Wind action and dunes . : : : : : : : : ‘ 77
Changes in the shore line : : : : A : s 3 : 79
Summary of the geological history of the region : : : : ' : : 83
Mineral resources ; 87
Part II. Grotocy or ParticutaR AREAS

Chapter I, Geology of Nantucket and eee islands, oe J. B. Woodworth . : 93
Nantucket . 5 : : 93
Geography : i ; 5 : : 93
Geology : 94
Comelnton of fonui tions : : : : : : ; : : 94
Pleistocene epoch . : . . : : : . : S ; 95
Sankaty sand . : . : : : 95
Fossil shells under ihe elie of the lead : : : : : 98
Coarse gravel : ; : : : : : 99
Sections along the cortl shore’ : : : : : : : 99
Wisconsin stage of glaciation . : : : : : : 101
The outwash plain . . : : : : : : : . 101
The fosse : : : : : : ; : ; ; = 102
Nantucket moraine 102

Hypothetical core of ‘the Sorake Nantucket moraine
back of the fosse : : : : : : : : . 104
Postglacial or Recent epoch . : : : : ; : : 2 105
Natural changes. : : : : ; : : ; . 105
Artificial changes. : : ; : : : : = 110
Changes made by white men . : : : : : - 110
Indian shell heaps. 110

= of shell heaps or Goher mde to Poe sad oe

tra : : :
oe pebbles or gy pelts. : ; ‘ : : : 7 ii

CONTENTS vil

PAGE

Tuckernuck : : : : : : : : : : : : . 1122

Muskeget . : : : ‘ : : : . 112

Bibliography of the ee of hanes : : : : ; : — iia
Chapter II.— Geology of Marthas ee ae Edward ae with notes De

J. B. Woodworth 117

Geography : : : : : : ; : : : — U7

General ine ; . : : ; : : ‘ : : . = Ali

Topographic divisions . : : : : : : : ; : _ Ats

he western area . : : : : : : : . : . us

The northeastern area. : : : : : : _ - 119

The great plain. : ; : : : : : : - 119

Notable topographic fous : : : : : : : . 119

Geologic significance of the a : ; : : : : - 120

Salient geologic features : : : ; : ‘ : : . 121

Effects of the Wisconsin ice i oe : : : : : _ 122

Form of the island : : . : : ‘ : . 123

Influence of the alder bonomeaphe: : : : : ; : 124

The Buzzards Bay lobe of the ice sheet : : : ; : ~ 124

The Cape Cod — lobe : : ; . : : : ~ 125

Moraines : ; : : : : : . : ~ = 126

Satie moraines : : : : ; : : : - 126

Till moraines . : : : : : : : : : - 126

Kettles . : : : : : ; ; : : : ; . 127

Older valleys . : ; : : : : : : : : - 2 127

Outwash features . : : : : 5 : : . 5 . 129

The outwash plain . : : : : : : : : . 129

Ice contacts. : : ‘ ‘ : : : : : - 129

Kettles. : : : : : 3 : : : : 7 131

Channels : : : : : : : : : ; - 132

Shore features : : : : : : F : ise

Constructive ection” : : : : : . : : . 133

Destructive action . . : : ; : : : : . 184

Landslides : : : : : : ; : : ; . 136

Stratigraphic geology . : : : : : : ; : : : = 136

Introduction . : : : : : : : : : ; - 136

Difficulties of mapping . : : : : : : : : 5 Ss

Nature of the deposits. : : : ‘ ; i : . 1386

The topographic map : : : ; : : : 7 186

The Wisconsin drift : : : : : : : : . 136

Sections in the cliffs : : : : : : : : . 17

Sections in the interior . : : : s 137

Lithological similarity of the Pease depots : oe _ 7

Lack of borings : : : : ~. 138

Nature and age of the ee dened: : : : : - 138

Nature and age of the Pleistocene deposits .. : . 1389

Probable nature and depth of the pre-Cretaceous bactinent . : . 139

Cretaceous system : : : : : : : : . . 140

Names of the ne . ; : : ; : : : : . 140

Subdivisions . : : : : : : 5 Z : - 140

vill CONTENTS

PAGE
Character of the deposits ; : : 7 : : «141
Source of materials : : : : : . 141
Relation of the Cetacum to oli Jove : : : : : . 148
Structure : : : : ‘ : : : : ~ 143
Conditions during deposition : : ; : : : : - 145
Distribution . : : : : : : : 5 : . 146
Gay Head : : : : : . : . 146
Clay pit near Sinead Pood : : : : : : . , 146
Menemsha cree : : : : . : : . 146
Squibnocket . : : : : . : : ; : 2 147
Nashaquitsa cliffs. : : : : : : : . . 147
Peaked Hill, pitno.1 . : : : : ; : : = 147
Roaring Brook : ; : : : : : : : 2 Ay
Peaked Hill, pitno.2 . : : : SoG : _ 147
North Road ae : : : : ; : . : . 147
: Makonikey . : : : : : : : : . 148
Form of the surface : : : : : : . : : . 148
Age as shown by fossils : : : : : : : : . 148
The Matawan marine fauna. : 149

Report on collections of Upper Cretaonus ee fossils from
Marthas Vineyard, by L. W. piles : : 150
Fossil plants. : : : : = 155
Plants described by Hollick : 155

Report on Upper Cretaceous flora of Mares » Vineyard by
Edward W. Berry : : 157.
Tertiary system, by J. B. Woodworth . . : . : : » 15/
sence of early Tertiary formations . : : : : . _ 107
Miocene series : : : : : : : . 5 . 158
The greensand : : ; : : . 4 : - 158
Character : : : : : : : . : . 158
Oxidation : : : : . . : : : . 158
Thickness : : : . 159
fa loouble coufack ok dotcom ie : : : ; iog
Fossils. : : : : . : : : : : = 159
Pliocene series . : : : - 160
Aquinnah Cainer es Piestocene). : : : : . 160
Quaternary system, by Edward Wigglesworth : : : : ; ~ 162
Pleistocene series. : : . 162
arly Pleistocene dooce oe Gur ines iGhiatons) i 5 = 162
Gay Head cliffs section. : : : ; . - 163
Aquinnah conglomerate. : : ; : : = 2103
Dukes boulder bed. : : - : : ~ 163
Mannetto formation : : : ; _ l64
Evidence of pre-Gardiners age of (Gane : : . 164
The post-Mannetto ae of a, : : : . 164
Nashaquitsa cliffs. : : : . 165
Weyquosque oe ae : 165

Moshup till member of Fac Sen ud | overlying

beds :

Nortons Point : : : : : : : ; 2 167

CONTENTS ix

PAGE
Other exposures : : : : : : : : 167
Gardiners clay : : : . : : : : : . 167

Name : : ; : . : 5 : ‘ : > loz
Character = . : : : : : g : . — 168

Thickness : : : : : : : 2 : . 168
Source of materials : ; : : ; ; : - 268
Relation to older deposits : : : : : : _ 169
Structure : : ‘ : : . 169
Date of folding of Sanding oe : . : : : - 170
Conditions during deposition . : : : : : - 170
Distribution . : : : : : : : : _ 170
Outcrops . : : : : ; . : : -- Ail
Form of ale : : : : : : : : . 12
Fossils and age : : : : : : : : - AG
Jacob sand. : : : : : : : : 174
Name : : : : : ; : : : : . 14
Character : : : A : . : : : oe e:
Source of materials . : : : : : : : . iA
Structure : : : : : : Ao
Conditions oe ae : : : : : : ~ 1s
Distribution and exposure : : : : ; : - 1d
Form of surface : : : : : : : 176
Fossils and age : : : ; : : : : ~ 177
Manhasset formation . : ; : 5 : ; : 2 Ar.
Name : : : : : : : : : . A
Soba ie : : : : : : : : . is
General disgsbusiod : — : : : : . 16
Hered gravel member = cl
Name : : : : : : : : : . 18
Character . : : : : : : : : . 1%
Thickness . : : : : : : : ; = 179
Structure . : : : ; : : : 149
Source of ee : : : : : . : . 180
Relation to other deposits : ; : : : . 180
Conditions during deposition. : : : : . 181
Distribution : : : : : : : : . ISl
AGE: : : : ; ; : : ‘ : . 182
Montauk till member : : : : ; . : 7 182
Name : : : : ; : : : : 182
Character . : ; : : : : ; : _ 182
Thickness . : : ; : : : ; . 183
Source of ce : : : : : : < 183
Relation to other aoe : : : : : . 183
Structure . ; : : : : . 184
Conditions ee de ala : : : : : . 184
Distribution . : : : ; ; . 184
ge. : ; : : 186
Hempstead gravel member. . ; : : ~ 186
Name : : : : : : : : : _ 186

Character . : : “ : : : : ; - 187

x CONTENTS

Thickness .

Source of pee tals

Relation to other oot
Structure

Conditions ganne ood
Distribution and outcrops

Age : :
Vineyard interglacial stage
Wisconsin drift

Subdivisions
The till sheet

Character

Source of materials

Relation to earlier deopaite

Distribution

Nantucket moraine .
Origin and Siucler
Distribution
Outwash deposits .
Bibliography of the geology of Marthas Vineyard

Chapter III.—Geology of No Mans Land, a J. B. Woodworth.

Location ;

Geographical foxes :

Descriptive geology
Earlier investigations
Pre-Wisconsin deposits
Wisconsin drift
Marine action

Chapter IV.—Geology of Block Island, a J. B. Woodworth
History and geography : :
Geology

Pre- Cremccoue oe
Upper Cretaceous deposits
Character and distribution
The white clay
The lignitic clay
Fossil flora :
Tertiary material in Pickanesae paca drift
iocene boulder
Eocene material in pecene ie
Pleistocene formations
Classification ;
Character of the fonniiions ; :
Basal Pleistocene of Clay Head section .
Vineyard interglacial stage
Nantucket moraine
Character and extent
Glacial boulders.
Direction of drift shown by foulders

CONTENTS xi

PAGE

Cumberlandite boulders . : : : : : : - 224

Upper Cambrian quartzite pebble: : : . . : -— 225

Agates. : : : : : : : : : : 225

Chiastolite schist pebbles j . : : : . : - 220

Absence of kames and eskers : : : _ : . 220
Post-glacial or recent deposits : : : : : : : 2 220
Freshwater swamps and peat a : : : : : : a 220

Marine marshes. : : : : : : : 22d

Wave and current sedon : : : : : : : : - 22

Dunes and wind action . : : : : : : ; : 2 228

Black iron sand or magnetite : : : : : : : , 229

Great Salt Pond. : : : : : : : : - - 229
Economic geology : : : : ‘ : , 200
Bibliography of jokey of Block eee ‘ : : : : : : 5 231

Part III. Grotocy or Carpe Cop AND THE ELizABETH IsLANpDs. By J. B. WoopworRTH

Chapter I—Geology of ue Cod. . : : : : : : : 231
eography . : : : : : : : : : 23d
Location and area : : : : : : . : : : ~ 237
Topography 238
Hydrography : . : : . : : : : 239
Lakes and nels : : : : : : : : : : = 209
Harbors and creeks : : : : : : : : : . 240
Cartography . : : : : : : : : : : _ 242
Descriptive cenleny : : : 3 : : 5 : : : . 243
Earlier reports . : : : : : : : : : . 243

The bed rock basement . : : : : : : : : . 247
Pre-Pleistocene formations. . : : : : : : . 248
Pleistocene formations . : : : : : : : : . 248
re-Wisconsin deposits. : : : ; : : . . 249

Sankaty sand . : : : : E : 5 : . 249

Jameco (?) gravel. ; : : ; : . ; — 202

Gardiners (?) clay. : : : : : ; : — 205

Jacob (?) sand : i : : : : : 259

Manhasset foros @.. : . : : : ; — og

Herod gravel member (?) . : . : : : ~ 209

Montauk till member (?) . : : ; : : _ 259

Hempstead gravel member (?) . : : : ; = 260

Summary . : : : : : : : : ~ 200

Vineyard interglacial stage : : : : : : . 261

Erosion phenomena. : ; : : : : : — 20k

Wellfleet plain . é : : : : : : : - 261

Chatham plain . : : : : : : : ; - 262

North Truro plain. : : : ; : : : «263

Wisconsin glacial deposits ; : : : : : : . 264
Nantucket substage . : : : : : : : . 264

Falmouth substage . : : . : : ; : 269

‘almouth moraine. : : : : : : 209

The outwash plain. : : : : : : _ ail

xii CONTENTS

The interlobate morainal area .
Eastham plain
North Truro plain
Wellfieet plain :
Plymouth interlobate moraine .
Postglacial or Recent changes
Changes in the shore line
Webb’s Island . :
The Provincelands Geok
Barnstable Beac
The south shore of the ape
Land-tied islands
Work of the wind on Cape Cod
Deflation of the glacial gravels
Erosion of cliffs by winds
Dunes formed from beaches
Dunes of the Provincelands
Dunes of Barnstable
Dunes of Monomoy .
Swamps and marshes
Freshwater swamps
Chamaecyparis bore near Woods Hole
Submerged tree stumps
Marine marshes
Peat deposits .
Postglacial changes of level

Chapter II.—Geology of the Elizabeth or Gosnold Islands .
Introduction :
Naushon Island

Salient features

Cretaceous deposits

Miocene greensand *

Pleistocene sections

Later Wisconsin or Funets moraine

Frontal moraine
Kettle holes
Glacial erratics
Agate 25 :

Pasque Island : :
Nashawena Island
Cuttyhunk Island

Geologic Structure .

Sow and Pigs Reef

Penikese and W: cle: Isles

Penikese Island

Gull Island

Woepecket Isles

Woepecket Rock
Ribbon Reef

Figure

a

oo

o

bo
oO

LIST OF TEXT FIGURES

Sketch map of southern New England showing maximum extension
ot glaciers during the Pleistoceneepoch. =... =

Map of Miocene boundary from Massachusetts southward........

Sketch map of glacially dislocated terrane off south coast of New

Outline map of Marthas Vineyard showing three topographic areas
Map showing position of lobes of the Wisconsin ice sheet on

Marthas Vineyard... 2.
Generalized profile of the northeastern area and the great plain... .
Generalized profile of the western area and the great plain........
Map showing location of pre-Wisconsin valleys on Marthas Vine-

Profile showing relation of bouldery moraine and outwash plain,
where an ice-contact slope and fosse exist....................
Profile showing relation of bouldery moraine and outwash plain
without fosse and ice-contact slope.........................
Generalized profile of channels or creases showing relative steepness
of Cast and west banks. = lr
Profile of Watcha Pond channel; an extreme case..............
Cross section of geological structure at Gay Head...............
Geological section of Nashaquitsa Cliffs............. oe
Section expoced ai Norton 5 Pomt. =
Section exposed northeast of Roarine Brook... .==«si“‘(‘é ww;*é*é~*~S
Section exposed one mile south of Cedar Tree Neck..............
Section exposed at Stonewall Beach clifis.....-......
Section exposed southwest of Cedar Tree Neck.................
section exposed in Clilis at Squibnocke,.
Contorted Pleistocene beds on east coast of No Mans Land ......
Cross section of Clay Headim 1916...
Section of Pleistocene formations at Highland Light in North Truro
Section of Falmouth frontal moraine and outwash plain, showing
old ice blocks in sites of glacial lakelets ......................
Cross section of Cape Cod interlobate axis, Cape Cod Bay, and the
Plymouth interlobate axis showing relations of the Wisconsin ice
sheet at Falmouth substage ...........
Outline map of Cape Cod and Cape Cod Bay showing the long-shore
drift indicated by the chief shore features....................

sili

Page

EDITORIAL FOREWORD

Tue publication of this memoir on the geology of Cape Cod and the New
England islands would have been a source of great satisfaction to Prof. Wood-
worth had he lived. It is a summation of the results of long continued study by
him, which was begun many years ago in association with Prof. Nathaniel S.
Shaler. In a letter to the junior author at the time he received the request from
the United States Geological Survey to write the report, Prof. Woodworth stated,
“The long awaited and oft expected has occurred,’”’ and suggested the glacial
geology of Marthas Vineyard as the subject for a doctor’s thesis which could
later be revised as part of the report. The present volume is a fitting memorial to
Prof. Woodworth in that it is the culmination of his work in one of the lines of
study in which he was most interested.

The field work and preparation of the manuscript was originally done for
the Section of Coastal Plain Investigations, U. 8. Geological Survey, T. W.
Vaughan, Geologist in charge. Early in 1920 the manuscript was transferred to
the Section of Glacial Geology, Wm. C. Alden, Geologist in charge, by whom it
was revised, and preparation for publication was begun. For various reasons,
which need not be detailed here, preparation for publication was not completed
when Prof. Woodworth died, August 4, 1925.

In 1926, Mr. Samuel Henshaw, Director of the Museum of Comparative
Zoology and a long time friend of Prof. Woodworth, suggested to me that he
would be glad to publish the report, in memory of Prof. Woodworth, as one of the
Museum’s memoirs, and a proposal was made to the Director of the Federal Sur-
vey. Permission to do this was granted by the Director, Mr. George Otis Smith,
and the manuscript was turned over to Mr. Henshaw, with the assurance of
assistance by the Survey in further preparation. Work on editing and preparation
of the plates was commenced at once, but again was not completed at the time of
Mr. Henshaw’s resignation as director of the Museum. After some delay, owing
largely to the fact that certain funds expected for publication were no longer
available, the present Director of the Museum, Dr. Thomas Barbour, arranged
to have the manuscript reduced in volume and to be further edited by the late
George M. Wood, retired editor of the Federal Survey. To the services of Mr.
Wood is due in large measure the excellence of the text of the memoir as now is-

XV

xvi EDITORIAL FOREWORD

sued. To obtain necessary funds to complete the publication, an appeal was made
for a grant from the Penrose Fund of the Geological Society of America, which
was generously given, thus removing the last obstacle in the way of printing.

In addition to the several changes of plan and the many hands through
which the manuscript has passed, there has been the additional difficulty of putting
it through the press without the help of the chief author. The finished result,
therefore, is not what it otherwise might have been, and more particularly copy
for a number of Prof. Woodworth’s plates could not be located, a fact which ac-
counts for the incongruous lack of sequence in the plate and map numbers, and
their order of appearance. In fairness to Prof. Woodworth it should also be stated
that a large amount of valuable material had to be omitted in order to reduce the
cost of the report, and the effect of this will be much more obvious than if the
original author had been able to adapt the rest of the memoir to these omissions.

Acknowledgement is made to the U.S. Geological Survey for transfers of
the engraved topographic maps, and to C. A. Weckerly, Chief of the Section of
Illustrations of the Federal survey, who with assistance by O. W. Goodloe, pre-
pared the geologic maps and drawings at the expense of the Museum of Compara-
tive Zoology. Valuable assistance was also rendered at various times by Wm. C.
Alden, of the Survey, in getting text, maps and illustrations ready for publication,
but owing to pressure of other duties Mr. Alden did not have the opportunity to
reexamine the manuscript after the revision by Mr. Wood. He did, however,
read the entire galley proof, making numerous helpful suggestions, and Dr. L. W.
Stephenson, the author of the section, “Collections of Upper Cretaceous Fossils”’
(of Marthas Vineyard), read and corrected this part of the memoir. The U. 8.
Coast and Geodetic Survey, R. 8. Patton, Director, was so kind as to permit re-
production of certain plates published in their reports to illustrate this memoir.
Also thanks are due to Professors Kirtley F. Mather and Kirk Bryan, who very
kindly read the whole manuscript in an effort to eliminate any errors, and who
made many valuable suggestions. Finally, very sincere thanks are due to Mr.
Ludlow Griscom of the museum, for preparing the report for the printer and

reading all proof.
-Epwarp WIGGLESWORTH

PART I
OUTLINE OF THE GEOGRAPHY AND GEOLOGY
OF THE REGION

OUTLINE OF THE GEOGRAPHY AND GEOLOGY
OF THE REGION

By J. B. WoopwortH

INTRODUCTION

The first part of this report presents a general view of the district surveyed
and summarizes the palaeontologic data; the second part describes in detail each
particular area considered. Although this method of treatment involves some
repetition, it has been employed in order to adapt the matter to the use of the
general reader on the one hand, and of the reader who may be interested in a
particular area or island on the other.

The field work on which the report is primarily based was done in the sum-
mers of 1914 and 1915. Assistance in the field was received from Mr. Gilbert
Hart, who deserves particular mention for his work on the Elizabeth Islands,
west of Naushon. Many observations that have been utilized were made by me
during visits to Cape Cod and the islands, either in connection with the work of
the United States Geological Survey or as instructor in geology at Harvard Uni-
versity.

Dr. Wigglesworth studied the geology of Marthas Vineyard at his own
expense under my direction, and his original manuscript, of which the accompany-
ing account of the geology of that island is an abstract, was filed in the archives
of Harvard University in part fulfillment of the requirements for a doctorate.

Thanks are due to Dr. T. W. Vaughan and to Dr. W. C. Alden for advice
and personal consultation in the field concerning some mooted points in the
Pleistocene history of the district, and especially to Dr. W. H. Dall for the iden-
tification of the marine fossils.

TOPOGRAPHY

Cape Cod is a peninsula composed of gravel, sand, and clay, which extends
from southeastern Massachusetts into the sea in the form of a bent arm that
encloses Cape Cod Bay. South of Cape Cod there is a group of islands, some-
times called ‘‘the New England Islands,’’ which includes Nantucket, Marthas
Vineyard, No Mans Land, Block Island, and the Elizabeth Islands. These islands
are separated from the mainland and from Cape Cod by navigable sounds. Al-

4 CAPE COD GEOLOGY

though Cape Cod at first sight appears to be quite unlike the islands, a close exami-
nation shows that it has certain features in common with Marthas Vineyard and
Nantucket, and that it is composed of deposits of similar character and origin. The
islands and sounds were formed by glacial action in Pleistocene time, when beds
of unconsolidated gravel, sand, and clay were laid down by the continental glacier,
which then advanced over this region from the north, and by the erosive work of
streams. The outer shores of Cape Cod and of Nantucket show where the great
frontal moraines of that glacier pass seaward to the submerged fishing banks off
the coast. The maximum extension of the great sheets of ice that produced these
features is shown in Figure 1.

Some of the formations belonging to the older part of the Pleistocene series
are greatly disturbed, and the work of Veatch! and of Fuller? on Long Island
first made known the sequence and the geologic age of certain beds of blue clay
in the New England Islands, which can now be separated from beds of dark
Cretaceous clay, so that the older Pleistocene deposits can be correlated. In this
report Dr. Wigglesworth has made the proper correlation of these beds of clay
and the associated beds of sand on Marthas Vineyard. Except for local breaks
in their basal part, the Pleistocene beds extend almost continuously from
Long Island eastward to Marthas Vineyard.

The topography of Cape Cod and of the New England Islands is predomi-
nantly glacial, but some tracts display forms shaped by the action of running
water on unconsolidated clay and sand and modified by the action of moving ice.
Certain plains and high tracts or ridges, both on Cape Cod and on the islands,
present a morainal configuration, but much of the general form of Marthas

Vineyard is not distinctly morainal. At many places morainal features are
imposed upon an older surface that was not shaped by glacial or stream action.
The appearance of morainal origin is due in part to the numerous ice-borne
boulders that strew the surface.

Throughout large tracts on Block Island and No Mans Land and in the
northern part of Nantucket there is a pseudo-morainal topography due to the
kneading and deformation of old stratified glacial deposits by the last ice sheet.
No geologic sections are available to show the relation of the form of the surface
to the details of the structure beneath, and it is therefore difficult to decide
whether the configuration at many places is due to morainal accumulations
laid down by the last ice sheet or to the form of older deposits that are covered

1 Veatch, A. C., and others, Underground water resources of Long Island, N. Y., U. 8. Geol. Survey
Prof. Paper 44, 1906.
2 Fuller, M. L., The geology of Long Island, N. Y., U. 8. Geol. Survey Prof. Paper 82, 1914.

ore

1 nn ya
|

v }
TERMINAL MORAINE DIRECTION OF ICE MOVEMENT
(GENERALIZED)

Fig. 1.— Sketch map of southern New England showing the maximum extension of the continental ice during the
Pleistocene epoch

—

6 CAPE COD GEOLOGY

by glacial drift and boulders. It is mainly in the recognition of this wrinkle-
moraine or pseudo-moraine and its significance as to the age of the deposits
forming the mounds, which are scattered over the surface, that this report
represents an advance in the interpretation of the structure and origin of a
large part of the morainal belt on the outer islands.

The nearly flat plains on Marthas Vineyard, Nantucket, and Cape Cod,
generally underlain by gravel and sand, consist of deposits laid down by streams
that flowed out from the ice front, but the plains in certain areas were leveled
by running water that flowed over old glacial deposits. Cliffs shaped by the
erosive action of sea waves in sand, gravel, clay, and till are common. The long-
est stretches of these cliffs are found on the east side of Cape Cod, where they
extend from Highland Light southward beyond Chatham. Other well-marked
lines of cliffs stand along the south side of Marthas Vineyard, in Chilmark; at the
west end of that island, at Gay Head; on the south side of No Mans Land; and
on the south side of Block Island. The southward-facing cliffs are composed
mainly of dark clays and old boulder beds.

The relief of the district is generally low, in common with that of the Atlantic
coastal plain, of which it forms a peculiar part. The land about Cape Cod Bay
and on the islands rises slightly more than 300 feet above mean sea level at
three points: Manomet Hill, in Plymouth (altitude about 390 feet); Peaked
Hill, on Marthas Vineyard (altitude 311 feet); and Prospect Hill, near Peaked
Hill (altitude 308 feet). Manomet Hill is wholly of glacial origin, and the two
highest points on Marthas Vineyard are drift-capped hills formed by the erosion
of deformed Cretaceous and early Pleistocene beds. The highest point on Nan-
tucket is a rounded knob of deformed drift, 100 feet high, in the morainal belt.
No Mans Land has one similar high point, which stands at an altitude of 110 feet.
One point on Block Island has an altitude of 211 feet, and a small area in the
northern part of that island and a large area in its southern part rise above 100
feet.

The topography of the upland and of the till-covered tracts in the northern
part of Nantucket, the northern and western parts of Marthas Vineyard, and the
whole of No Mans Land and Block Island is the net result of the following
processes:

1. Deposition of beds of boulders, gravel, sand, and clay on the sand and
clay of the coastal plain.

2. Deformation, dislocation, and overthrust by ice during the two or three

stages of glaciation prior to the last.

CAPE COD GEOLOGY ri

3. Sculpturing of the surface during times when it was exposed to stream
erosion.

4. Slight erosion and mantling by thin sheets of drift of the last glacial
incursion.

The nearly flat outwash plains that border the moraines rise from near sea
level to an altitude of about 100 feet on Marthas Vineyard and about 60 feet
on Nantucket. Their gentle southward slopes bear well-defined creases, which
become deeper and wider southward, suggesting channels that were once occu-
pied by running streams.

The relief of Cape Cod is due in part to action similar to that shown on
Nantucket and Marthas Vineyard, and the beds that stand above sea level have
been exposed to the action of the same agents of deposition and erosion that were
in operation on these islands. A belt of morainal topography of the knob and
basin type, without bordering outwash plains, is seen in the Elizabeth Islands.
This morainal belt is traceable on the mainland from the southwestern heel of
Cape Cod, at Wood’s Hole, north-northeastward to the Cape Cod Canal, from
which it extends eastward in the form of a rounded, hilly ridge along the south
shore of Cape Cod Bay, gradually declining in elevation until, near the east
coast, its features merge into those of glacial plains. South of this morainal belt
a glacial outwash plain forms most of the surface, the striking features of which
are numerous pits and glacial lakes. This outwash plain rises toward the north-
west in an interlobate angle between the morainal belts in the form of a large
outwash fan, which reaches an altitude of 220 feet above the sea at its junction
with the line of glacial deposits that were laid down directly at the front of the
ice sheet.

The surface of Cape Cod from the vicinity of Orleans northward may be
divided into three tracts, which include glacial plains, though in the middle tract
deep kettles and the glacial channels known as ‘‘hollows”’ mask the features of
the plain. The northern and the southern tracts stand 60 to 70 feet above sea
level and decline gently westward, toward Cape Cod Bay. The middle tract,
which rises toward the outer coast, exceeds 100 feet in altitude in much of its
area, reaching at some places an altitude of 140 feet. It forms the wildest and
most picturesque part of the outer shore of the Cape, which presents to the storms
of the Atlantic high bluffs of yellowish gravel and sand.

The outstanding projections in the surface of the Cape and of the islands
south of it mark the sites of great terminal moraines, which are traceable west-

ward to New York City and eastward to the coast of New England. Nantucket

8 CAPE COD GEOLOGY

and Cape Cod extend into the sea to points reached by the ice sheets, whose
fronts were aligned from east to west. The great submarine banks off the east
coast represent similar features, but their surfaces have been highly modified by
the action of waves and current.

In broad outline, the region here considered is formed of two great series of
lobate frontal moraines, between the inner and outer lines of which lie Nantucket
and Vineyard sounds, and back of the inner line of which, in depressions like those
of the sounds in origin, lie Buzzard’s and Cape Cod bays. In this festooned dis-
tribution of the land the moraines define the outer border of lobes of the ice
sheet, formed along paths of the most rapid motion of the ice, the maximum rate
of flow of which in each lobe occurred along a line that was directed southward
and that lay near the central axis of the lobe. The interlobate moraines, repre-
sented by the arm of Cape Cod in Wellfleet and Truro on the one hand and by
the Plymouth moraine on the other, were places of minimum rate of flow of the
ice, and therefore of heavy deposition. These interlobate lines or axes point west
of north, toward obstructions to the flow of the glacier. The direction of the
glacial striae on the mainland show that the lobe lying in Buzzard’s Bay and in
the country somewhat west of it moved along the Merrimac Valley in New
Hampshire, and that the lobe lying in Cape Cod Bay moved along a line east of
the Mount Washington range, which, together with the Blue Hills of Milton,
appears to have been the chief cause of the slack ice motion represented by the
Plymouth interlobate moraine. A like relation is traceable in the Wellfleet inter-
lobate axis to Mount Bigelow, in Maine. Still farther east another interlobate
axis is faintly suggested in George’s Bank, which lies beneath the sea nearly in
line with Mount Desert and Mount Katahdin, in northern Maine. The outline
of the Cape and of the islands shaped by glacial action is thus a geographic reflex
of lines of depression and elevation in the country to the north.

Cape Cod and the outer islands south of it contain few streams, because the
porous gravel and sand permit rain water to sink nearly if not quite to sea level.
The height of the water table in the plains is shown by the surface of numerous
lakes and ponds. An extensive seepage of the water takes place along the coast
at points between the levels of high and low tide.

The streams of the islands are limited to areas where deposits of clay occur,
as in the upland, western part of Marthas Vineyard. On the south side of the
Cape, in Barnstable, the overflow of lakes forms small brooks, which, however,
flow in channels cut by the much larger streams that were fed by the melting ice
during the last stages of the glacial epoch. Mashpee River is the largest stream of

this class.

CAPE COD GEOLOGY 9

The lakes or natural ponds on Cape Cod lie in depressions left in glacial
deposits by the melting out of large blocks of ice. From their shapes, dimensions,
and alignment it is possible to restore a picture of the ice as the glacier ap-
proached its final stage. These ponds are particularly numerous in the plains
on the south side of the morainal belt on Cape Cod. They are enclosed by steep-
sided banks of sand and form great natural wells in the enclosing glacial material.
Numerous shallower depressions of like origin also occur in the region, but these
are dry, because their bottoms stand above the level of ground water. The
depth of the deepest of these ponds, as shown by soundings, is 81 feet. Many
small, shallow ponds that formerly appeared on maps have been drained or
filled and converted into cranberry bogs.

The coast line of Cape Cod and of the islands has for long stretches been
straightened by the attack of the sea, but some of the indentations of the coast
near headlands have been protected from such attack by the natural construction
of offshore bars and beaches, which are attached at one end to the cliffs that
afford the gravel and sand for their construction and maintenance. The indenta-
tions of the coast line, the larger of which form small harbors or ports of refuge
against certain winds, are nearly all of glacial origin.

Along most parts of the Atlantic coast tidal currents sweep away rapidly
the gravel, sand, and clay that are loosened from the cliffs by the waves of storms.
The shoals about Nantucket and southeast of Cape Cod are famous for their
ever-shifting sand.

GENERAL GEOLOGY

Some account of the geologic formations of the mainland of Massachusetts
and Rhode Island is necessary to show the source of the boulders and other
glacial erratics that are so widely distributed on the islands off the south coast of
these states. For the same reason the boulders on Cape Cod require an account
of the geology of the east coast of Massachusetts and the country farther north-
east. Much of the gravel, sand, and clay that constitute the deeper formations
of the islands and of Cape Cod has been derived from the rocks of the mainland.
The geological formations underlying the Upper Cretaceous beds that form the
lowest stratum found on the islands and on Cape Cod are here called the pre-
Cretaceous basement.

PrE-CRETACEOUS BASEMENT

Throughout the mainland of southern New England the geologic formations

that lie beneath the glacial drift and beneath a few exceptional areas of soft

10 CAPE COD GEOLOGY

beds of Miocene age, such as those at Gay Head and in the town of Marshfield,
Mass., are ancient deformed and displaced sediments into which magmas that
formed granite and other eruptive rocks have been thrust by several intrusions.
The last cycle of geologic change, the effects of which are still evident, was char-
acterized by erosion which produced widespread base leveling of the hard ancient
rocks of this part of the continent. The best defined surface formed by this
erosion is the beveled slope of the harder rocks in this region, whose extension
beneath the New England Islands forms the floor upon which the later beds rest
in this part of the Atlantic coastal plain. This surface was formed, locally, at
least, before the Upper Cretaceous deposits were laid down. The dissected
remnants of this surface along the south coast of Massachusetts, Rhode Island,
and Connecticut have a seaward mean dip of about 50 feet to the mile between the
100-foot contour line and the 300-foot or 400-foot contour line. The dip increases
from the southern coast of Massachusetts progressively westward to the southern

coast of western Connecticut, as shown below:

100-foot Dip in feet
Quadrangle contour to per mile

MassacHUSETTS

New Bedford ; : : : : : : : 200 227

Fall River. ; : : : ; : : : 300 20?
RuopE IstanD

Newport : : : : : : : : — a

Charlestown . : : : : : ; : : 300 Bo)
CoNNECTICUT

Stonington : : : : : : : : 300 33

New London . ; : ; : : : : : 400 33

Saybrook ; ; : ; : : : : ; — —

Guilford : : : : : : ; : : “ —

New Haven . ; : : : : : . : 400 50

Bridgeport. : ; : : : : : : 400 60

Norwalk : ; : : : : : é ; 300 60

Stamford : : : ; : ; ; : : 500E 45

Stamford : : : ; ; ; : ; 500W IGE

The space between the shore and the mean position of the restored 100-foot
contour line is too much obscured by morainal deposits or by inlets of the sea
to be considered in estimating the slope of rock surface in the greater part of
the district. The increasing inclination toward the west of part of the theoretical
old floor on which the Upper Cretaceous beds are believed to have overlapped
upon the mainland for at least from 5 to 10 miles inside of the present shore
line indicates a steepening warp of the old surface westward. The inclination
on the east is nearly that at which strata are laid down on a plain. Farther

CAPE COD GEOLOGY 11

inland, above the mean position of the outermost points on the land having an
elevation of 500 feet, the slope varies widely from the angles indicated by the
measurements given, being steeper along certain lines and less steep along others.
Thus from central-western Rhode Island the restored contours reveal a steep
slope between the 500 and 700 foot contours which extends northward through
the Kent, Burrillville, Blackstone, Marlboro, and Groton quadrangles in Massa-
chusetts into New Hampshire. The southeastern versant of the upland west of
this slope, which declines southward from the high ground about Worcester,
has an altitude of 800 feet in the southwest corner of the Burrillville quadrangle,
in Rhode Island. The slope from this point southward to the position of the
100-foot contour is about 22 feet to the mile; thence northward over the upland
the land rises at about half that rate to the base of the monadnocks on the Wor-
cester plateau.

From the eastern halves of the Groton, Marlboro, Blackstone, Burrillville,
and Kent quadrangles or, in general terms, east of meridian 71° 35 W., no rocky
summits rise above 500 feet, except Nobska Hill in the Franklin quadrangle,
and the Blue Hills of Milton, south of Boston, in the Dedham quadrangle. Rem-
nants of an old eroded surface that stood between 400 and 500 feet above sea
level extend eastward across the Franklin quadrangle and include small areas
in the southwestern part of the Framingham quadrangle, in the northwestern
part of the Providence quadrangle, and in the Dedham quadrangle. The gabbro
hills of Sharon and the Blue Hills of Milton are residual masses that mark the
outer limits of this old surface. One small point of rock in the northeastern part
of the Franklin quadrangle, near Concord, is also a remnant of this surface.
Northeast and southeast of the 400-foot generalized contour there is a broad
extension of the coastal lowland of Massachusetts in which the summits rise to
300 feet in the Salem quadrangle and in the Fall River quadrangle. Between the
traces of this 300-foot line and the present shore line the descent is much steeper
than it is between the 400-foot line and the 300-foot line.

The topographic features of the mainland west of Cape Cod have been
described by Davis! and later by Keith, who states that it falls into four plateau-
like surfaces which become successively lower towards the east, and each group
forms bays projecting westward into the higher ones. As a whole they are im-
mense steps or platforms ascending to the central upland. The highest group

1 Davis, W. M., Nat. Geog. Mon. No. 9, pp. 269-304, 1895. See p. 273, where the lowland about
Boston appears to be regarded as the Cretaceous peneplain sloping eastward toward the sea rather than
as a surface produced by erosion below the Cretaceous level.

2 Keith, Arthur, U. 8. Geol. Survey Water Supply Paper 415, pp. 8-23, 1916.

12 CAPE COD GEOLOGY

forms a north-south belt across the state next to the upland. It has a fairly uni-
form width of 6 to 15 miles, and its hilltops range between 540 and 650 feet in
altitude. Far from this group, but rising to its level, are the Blue Hills of Quincy
and Milton, 500 to 640 feet, and Moose Hill, in Sharon, 560 feet.

The next group forms a very irregular belt of hills between 320 and 380 feet
above the sea. These are to be seen mainly around the margins of the river val-
leys and in the two hill belts northeast of Wrentham and Weston. Next below
them is a group of hills, between 220 and 260 feet above the sea, which are scat-
tered over much of the state east of the two higher groups and almost reach the
sea in Lynn. On the hills of this group in Lynn and Waltham there is scarcely
any glacial drift....The summits of the lowest group range between 110 and
160 feet, and their areas form an irregular network along the coast and up the
river valleys.

Across this terraced surface the Buzzard’s Bay lobe of the ice sheet swept
to Marthas Vineyard in its first advance and to the Elizabeth islands in its second
stage. The Cape Cod Bay lobe and the South Channel lobe passed southward
outside of the site of Boston Harbor, where the ancient rock surface lies below
the platforms above described. A remarkable feature of the sea floor in that
region is a depression 99 fathoms deep, which shows that at a distance not more
than about 35 miles east of Salem the sea floor drops to a depth of more than
800 feet below the platform (220 to 260 feet) which approaches the sea at Lynn.
Thus a strong topographic break outlines the eastern rock-bound coast of the
state, the interpretation of which is bound up with that of the platforms of the
eastern lowland, the date of whose origin is not clearly known. Both of these
areas formed the inner margin of the glacially altered coastal plain on the south.
Cape Cod and Nantucket belong mainly to the submarine tract, and the islands
to the west belong to the eastern lowland.

The eastern lowland cannot be a down-warped part of the surface of the
upland, for the south coast, whose intersection with the sea is formed by the
mid-Cretaceous erosion plain, has no corresponding offset to the north along the
line of flexure which would have been thus introduced. The lowland appears to
have been well opened out by Miocene time, for offshore deposits of this age occur
at Gay Head and on the borders of the lowland at Marshfield, and the Miocene
deposits contain no débris that would have been laid down on the sea floor by the
erosion of the surface from the higher to the present level. The surface therefore
appears to have been produced between the end of the Cretaceous period and
the local beginning of Miocene deposition. An Oligocene date appears most

probable.

CAPE COD GEOLOGY 13

CRETACEOUS SYSTEM
(See Plate 4)

The beds of lignitic clay and the associated beds of white and mottled clay
on Marthas Vineyard were assigned to the Cretaceous system in 1890 by David
White, who identified certain fossil plants found in them at Gay Head, in the
western part of that island. He states that ‘‘the flora indicated an age certainly
Cretaceous, and probably middle Cretaceous, for the terrane in which it was
deposited.” !

Just before White identified these plants Shaler ? announced the discovery,
in the eastern part of Marthas Vineyard, of angular fragments of a coarse sand-
stone, which were at many places embedded in the morainal deposits and which
had apparently not been transported more than a few hundred feet. Moreover,
near Indian Hill blocks of sandstone were associated with tilted beds of uncon-
solidated sand that were regarded by Shaler as of the same age. In his opinion
the Cretaceous beds were limited to a small area that was surrounded by beds
of Tertiary clay. Fossils found in the sandstone indicated that the beds con-
taining them were not later than middle Cretaceous.

The fossil plants identified by White had before been regarded as possibly
Tertiary in age, and in view of the restriction of the recognizable Tertiary beds
(Miocene and Pliocene) at Gay Head to a few feet of greensand and other sand,
it became evident in 1889 that the beds of white sand and the associated beds of
clay, of various colors, as well as the beds of lignite at Gay Head and elsewhere
on Marthas Vineyard, are members of the series of Cretaceous deposits exposed
at Perth Amboy and other places on the Atlantic coastal plain.

Dr. Arthur Hollick, continuing the investigation of the leaf-bearing clay beds
begun by White, discovered an extension of these beds on Nonamesset Island *
and correlated these leaf-bearing beds with beds found farther west, on Long
Island and Staten Island As a result of later studies at Gay Head, Hollick °
writes:

The stratigraphic relations of the various beds represented in this section are too uncertain
for definite conclusions on account of the tilting and distortion to which they have been sub-
jected; but inasmuch as 103 species of fossil plants, a large majority of them representing
well-known Cretaceous types, have been identified from this locality alone, the age of the beds

from which they came cannot be questioned. Both the Raritan and the Cliffwood (Magothy)
formations are represented in these species.

1 Am. Jour. Sci., 3d ser., 39, pp. 93-101, pl. 2, 1890. Also Bull. Geol. Soc. Amer., 1, pp. 554-555, 1890.
2 Bull. Mus. Cae Zo8l., 16, pp. 89-97, pls. 1, 2, 1889.
5 Annals New York Aca a 13, pp. 387-418 (apeculls p. 394), 1901.
‘The Cretaceous flora of poate New York and New England, U.S. Geol. Survey Mon. 50, pp.
27-28, 1906
© Op. cit, p. 27.

14 CAPE COD GEOLOGY

The flora of the Cretaceous beds of Marthas Vineyard was still later diag-
nosed by Berry,’ who referred the leaf-bearing beds to the Magothy formation
in the following terms:

The upper Cretaceous flora of Marthas Vineyard is extensive, comprising 117 recorded
species and coming from three localities (Chappaquiddick, Nashaquitsa, and Gay Head),
the bulk of the material coming from Gay Head. This flora has been elaborated by David
White and Arthur Hollick. The latter author considered it equivalent to the Raritan forma- |
tion of New Jersey, but it is obviously younger and equivalent to the Magothy formation.
Fifteen of the recorded species are confined to Marthas Vineyard. Of those having an outside
distribution, 67 are not found in the Raritan, and of the 35 forms that occur in the Raritan,
29 are also common to the overlying Magothy, leaving six peculiar forms, and these are all
vague or unique specimens (Carpolithus, Williamsonia, Tricarpellites, Tricalycites), Nearly
all of the Marthas Vineyard plants that occur outside of that area are common to the Magothy ;
of New Jersey or Maryland or to post-Raritan formations elsewhere. Thus 44 species occur
in the Magothy and 20 are peculiar to Marthas Vineyard and known Magothy, so that I have
no hesitation in correlating the leaf-bearing Cretaceous of Marthas Vineyard with the
Magothy formation.

The classification of the Cretaceous beds of the Atlantic coastal plain in
areas where they have been undisturbed by glacial action has been fairly well
determined, and the geologic relations of the plant-bearing beds in the New
England Islands can be stated in terms of the formations discriminated in New
Jersey and Maryland. In the gulf region the Lower Cretaceous or Comanche
series is represented by marine deposits, but on the Atlantic coast it is represented

i a ee

by nonmarine deposits, the northeastern beds of which belong to somewhat later
stages of deposition. Thus the Lower Cretaceous deposits of Maryland, com-

prising the Patuxent, Arundel, and Patapsco formations, here named in ascending
order, disappear northward through the gradual transgression of the Arundel
and the Patuxent by the unconformably overlying Patapsco formation, and this

in turn disappears beneath the Magothy formation, which locally lies at the base
of the Upper Cretaceous series in the New England Islands.

The most continuous exposure of the Upper Cretaceous series in the area
here considered is that seen in the cliffs at Gay Head (see plate 14) ; but even there,
owing to the complex of overturned folds and thrust faults, neither the number,
the exact order, nor the thickness of the beds can be exactly determined except
for a small part of the section. The following section may be seen in the cliffs at
Gay Head, in front of the lighthouse:

Section of Upper Cretaceous Beds Exposed at Gay Head

Quartz-bearing kaolinite at top, bleached white, alternating with a bed of white clay
about four feet thick and merging into cross-bedded quartz gravel below. The cast of a pele-

1 Jour. Geology, 23, pp. 608-618, 1915.

CAPE COD GEOLOGY 15

eypod (cf. Pholadomya sp.) was found in a “quadrangular fold” in the kaolinite at the top
of the series. Probably marine in its upper part.

White clay, in places stained deep red. Carbonized leaves of fossil plants found here
and there above the underlying bed of lignite. Same flora found in nodules at places where the
lignite has been forced over the clay, which has there become brownish from infiltrated iron
stains. Nonmarine.

Lignitic clay and lignite at bottom; exposed only in close anticlinal folds. Contains broken
trunks of trees and fragments of coniferous wood (Brachyphyllum, Prepinus viticetensis
Jeffrey),! and amber. Nonmarine.

The total thickness of the beds in this section probably does not exceed 150
feet. On the south side of the cliffs there is a long exposure of overturned beds of
clay, mottled white and red, having an apparent thickness of several hundred
feet, but the beds are undoubtedly repeated by folding. The narrow, squeezed
masses of white Cretaceous clay in closely folded beds at Ball’s Point, on Block
Island, as well as most sections of the clay that are not associated with lignite
or that contain no fossil leaves afford little clue to their stratigraphic position.

Marine fossils found near Indian Hill by Shaler in somewhat drifted blocks
of sandstone, an indurated part of one of the Cretaceous beds, show that the
marine division of the Upper Cretaceous system probably occurs on Marthas
Vineyard. Shaler regarded these fossils as not later than middle Cretaceous.
They probably belong at a horizon above the lignitic beds at Gay Head. Several
members of the United States Geological Survey have collected Cretaceous in-
vertebrate fossils in drifted argillaceous boulders on Marthas Vineyard. Accord-
ing to L. W. Stephenson, most of the species are nearly identical with those found
in the poorly preserved material collected by Shaler. The wide distribution of
these boulders over the island indicates that marine upper Cretaceous beds once
covered this district, and extended inland northward and northwestward.

Stephenson regards the deposit on Marthas Vineyard as of Matawan age
and states that if Hxogyra ponderosa has been correctly identified among the
fossils from the island, the fauna certainly falls within the zone of Exogyra pon-
derosa in the Matawan?

TERTIARY SYSTEM
EOCENE AND OLIGOCENE SERIES
The Tertiary system is divided into the Eocene, Oligocene, Miocene, and
Pliocene series, which are here named in ascending order. The Eocene and the
Oligocene series are not represented by any known deposits that stand above

1 Jeffrey, E. C., Annals of botany, 20, No. 80, pp. 383-394, pl. 28, 1906. Also Proc. Boston Soe. Nat.
Hist., 34, pp. 333-338, pl. 33, 1910.
2 Report on collections of Upper Cretaceous invertebrate fossils from Marthas Vineyard, Mass.

16 CAPE COD GEOLOGY

sea level in southeastern Massachusetts and Rhode Island. Fragments of an
Eocene fossiliferous limestone have been recognized by W. O. Crosby in the glacial
drift near the top of the bluff at Highland Light, on Cape Cod, and fragments of
a reddish friable sandstone containing Eocene fossils have been found in glacial
deposits on Chappaquiddick Island. These fragments may have been dragged by
glaciers from the bottom of the Bay of Maine, where, possibly, Eocene beds still
exist, but they afford scant evidence that the Eocene sea encroached upon the
lowland of southeastern Massachusetts inside the present shore line.

The Eocene rock found by Crosby! in the glacial gravel at Highland Light
was described by him as occurring about half a mile south of the lighthouse up
to a height of 125 feet and for 20 to 30 rods along the face of the cliff. It is a firm,
massive white, calcareous sandstone, which effervesces freely with acid, and yet
to the eye is composed principally of rounded grains of transparent quartz.
It contains also minute grains of glauconite, vestiges of lignite, and grains of
iron oxide. The fossils, which are in the form of molds or internal casts, are only
fragments. Crosby’s list and notes are given below:

Eocene Fossils Found in Fragments of Limestone in Drift at Highland Light, Cape Cod

Venericardia planicosta Lamarck. Found also
in lower Eocene of Virginia

V. parva Lea?

V. alticosta Conrad?

Casts of fragments of two other species of
Venericardia

Ostrea divaricata Lea. Possibly O. sellaeformis
Conrad. Found also in the lower Eocene of
Alabama

O. virginvanae?

Ostrea sp. A large thick shell

Plicatula filamentosa Conrad, or a form very
near this species

Camptonectes clavatus Conrad. Found also in
middle Eocene in South Carolina

Azinaea staminea Conrad? Fragmentary
shells, difficult to determine

Cardium sp.

Yoldia or Nuculana sp.

Corbula sp.

Turritella sp.

Natica sp.

Cidaris sp.

Galaxea sp.

Crosby inferred that these fossil-bearing boulders were derived from an

Eocene bed somewhere north of Cape Cod, in the region of the floor of Massa-
chusetts Bay, but more recent investigations indicate that the boulders brought
to that part of the Cape by the ice were moved west of south. These Eocene
boulders were evidently found in drift that had been shifted and worn by the
action of water after they had been released from the ice. If the clay of the so-
called ‘‘clay pound” at Highland Light is of the same age as the Gardiners clay,

1 Proc. Boston Soc. Nat. Hist., 20, pp. 136-140, 1879. ,

CAPE COD GEOLOGY 17

found farther southwest, the beds of gravel containing these boulders are of
Jameco age; they were laid down in the third stage of the glacial epoch.

Of the Oligocene series no trace has been found in the district. The Oligocene
epoch appears to have been a time of erosion, in which at least the coastal border
of the lowland was reduced to its present relief, but as the overlying marine de-
posits are not the earliest of that epoch, the erosion may have begun before Oligo-

cene time and continued after its end.

MIOCENE SERIES

The Miocene series is represented in this region by remnants of deposits
of greensand, which are seen at Gay Head, on the west coast of Marthas Vine-
yard; on Nonamesset Island; and at Marshfield and Duxbury, Mass., on the
mainland, about six miles north of Plymouth (see Pl. 4). There was formerly
a small deposit of this greensand, carrying much clay, in the Nashaquitsa cliffs,
but it was carried away several years ago by the retreat of the cliffs.

EARLY INVESTIGATIONS

Locally, at Gay Head, the greensand appears to be underlain by a deep blue
clay containing the same assemblage of fossils as the greensand bed. The green-
sand, with its fossil crabs, shark teeth, and casts of mollusks, found during the
first geological survey of the state at Gay Head, on the west end of Marthas
Vineyard, and in Marshfield on the mainland, wwere identified as of Miocene age
by Lyell at the time of his visit to Gay Head in April, 1842. Lyell also assigned
to the Miocene series the plant-bearing beds on Marthas Vineyard, but he greatly
overestimated the thickness of the beds. Shaler adopted his estimates in his
first report on the geology of Marthas Vineyard but modified it later. At Marsh-
field the Miocene beds are exposed in wells and are apparently about 30 feet
thick and undisturbed. At Gay Head the entire Miocene section, which varies
greatly in constitution as well as in thickness as seen in the cliffs, is probably
nowhere more than 10 feet thick.

In 1895 Dall attempted to correlate the Miocene of this region with the
Miocene formations in the Atlantic coastal plain south of New York. After
examining the fossils collected at Gay Head and Marshfield and visiting the
Gay Head section he referred the greensand and the associated osseous conglom-
erate of President Hitchcock’s report to the Chesapeake or ‘‘newer Miocene,”
which along the Atlantic coast contains a colder water fauna than that of the

‘‘older Miocene.”’

18 CAPE COD GEOLOGY

In 1889! in a geologic section illustrating Shaler’s paper on the “Tertiary
and Cretaceous deposits of Massachusetts,” I divided the Miocene at Gay Head
into two parts, described in descending order as follows:

5. Greensand beds and boulders of No. 4
4. Osseous or quartz pebble conglomerate

The osseous conglomerate was represented as resting on eroded Cretaceous
beds, the age of which had been determined by means of White’s work on the
fossil flora found at Gay Head. The beds of granitic gravel, sand, and boulders
that overlie the greensand were referred to an interglacial and preglacial stage.

In 1897, in a paper on the unconformities of this part of the coastal plain,?
I stated that the Miocene at Gay Head is made up of two well-defined lithological
divisions, and probably a third, which might be Pliocene. Dall later gave reasons
for so regarding it. The Miocene divisions were identified as the osseous con-
glomerate of Hitchcock, which was regarded as a basal member, and the supposed
later greensand, or foraminiferal bed. Rolled fragments of the osseous conglom-
erate were described as occurring in the basal part of the greensand bed, which
is found east of those parts of the cliff in which unbroken osseous conglomerate
is seen in place. The determination of the sequence of the deposits was based on
the occurrence of small boulders of the osseous conglomerate in the position in-
dicated. Up to this time no doubt had been expressed that the osseous con-
glomerate bed is a member of the Miocene series, as Lyell thought in 1842 and
Dall in 1895.

In 1900 I published a notice of the finding of the astragalus of a fossil horse
in the osseous conglomerate at Gay Head in May, 1889.* H. F. Osborn, to whom
the bone was submitted for examination in 1900, expressed the opinion that the
bone was that of a Pleistocene type of horse, and the question arose whether it
was found in the osseous conglomerate or in an overlying bed of glacial gravel.
The statement was made that ‘“The bone was broken in extracting it from the
bed, and there can be no doubt about its occurrence as a constituent of the osseous
conglomerate.” * On the same visit during which this bone was found, another
imperfectly preserved mammalian bone was collected from the osseous conglom-
erate in the same place, just east of the ‘‘Devil’s Den,” in the folded beds figured
by Edward Hitchcock in his report of 1841, but this bone was not identified until
1916, when Dr. Glover M. Allen found it among the collections of the Museum

1 Bull. Geol. Soc. America, 3, pp. 4438-452, pl. 9, 1889.

2 See bibliography.

3 Woodworth, J. B., Glacial origin of older Pleistocene in Gay Head cliffs, with note on fossil horse

of that section, Bull. Geol. Soc. America, 11, pp. 459-460, pl. 42, fig. 2, 1900.
4 Op. cit., p. 459.

CAPE COD GEOLOGY 19

of Comparative Zodlogy, and recognized it as a fragment of the skeleton of a
Pliocene camel. It, therefore, appears that the osseous conglomerate is made up
of a mixture of the bones of marine and land animals that ranged in age from
Miocene to earliest Pleistocene and can hardly be regarded as a pre-Pleistocene
deposit. An examination of the section in 1916 threw no further light on the
question. The boulders of conglomerate in the greensand were either derived
from some underlying formation in the Cretaceous system or were thrust into
the greensand from above, as boulders are rolled along and sink in soft mud.

The paleontologic evidence, though scant, is here accepted as sufficient to call
for such a revision of the classification of the Miocene and early Pleistocene
deposits at Gay Head as will remove the conglomerate and its abundant Miocene
fossils to a position at the base of the Pleistocene.

CHARACTER OF THE DEPOSITS

The Miocene deposits of this region consist of beds of greensand, most of
which are brownish red, weathered, somewhat compacted masses of small grains
or nodules, which near the base of the bed, or deeper within the section, become
greenish to bright green, the color of typical greensand. The larger grains are
between 0.5 mm. and 1.5 mm. in diameter, and many of them show the outlines
of the well-known foraminifers of greensand deposits! The presence of these
beds in the Miocene series in this part of the Atlantic coastal plain is somewhat
anomalous, and W. B. Clark and F. J. H. Merrill have raised the question whether
the beds may not have been redeposited from a marine Cretaceous section that
was invaded and partly reworked by the advance of the Miocene sea. The Mio-
cene age of the greensand bed is indicated by the fossil mollusks and vertebrates
it contains. The greensand is relatively pure, but at Gay Head a few rounded,
highly polished quartz pebbles are found in the middle of the bed, and near its
base there are numerous coarse grains of quartz. The bed of greensand exposed
on the southwest side of Nonamesset Island contains a large percentage of coarse
rounded quartz grains, 3 to 4 mm. in diameter, literally a fine gravel.

GASTROLITHS IN THE GREENSAND AT GAY HEAD
The greensand bed at Gay Head contains scattered, smooth, shining quartz
pebbles, the largest 1 inches long. The high polish of these pebbles and their
association with the fossil remains of a supposed seal and a walrus suggest that

‘Cushman, Joseph Augustine, Some Pliocene and Miocene foraminifera of the coastal plain of the
United States, U. 8. Geol. Survey Bull. 676, p. 100, 1918.

20 CAPE COD GEOLOGY

they are the stomach stones or gastroliths of seals. Sir John Murray * states that
both seals and penguins carry to sea in their stomachs large numbers of stones
and pebbles, which sealers call ‘‘ballast.’”” He remarks that ‘‘these animals may,
therefore, to some extent distribute rock fragments to great distances from the
land; should any of them be killed or die at sea their soft parts might be entirely
removed in solution, and even their bony structures might be entirely removed,
while the stones and pebbles contained in their stomachs would remain as a
part of the deposit.”

Moseley 2 too states that ‘‘stones are found in all seal stomachs, apparently

just as in those of penguins.”

GASTROLITHS AT DUXBURY AND MARSHFIELD
The Miocene deposits of the mainland in Duxbury and Marshfield were
first described by Hitchcock in 1833.

Here were found a very perfect shark’s tooth, the case of a small species of Venus, and the
same species of Turbo that occurs at Gay Head. In another specimen of Venus, in the cavity
occupied by the hinge, is a small quantity of greensand, exactly like that at Gay Head, which
proves satisfactorily the identity of the marsh mud and the greensand; and that the greensand
of Gay Head is identical with that in England a comparison of specimens shows.

Hitchcock again visited the greensand area in Marshfield and Duxbury in
1837, when certain wells were open, and found that greensand had been thrown
out from at least three wells.’

A chemical analysis of the greensand from Marshfield by Dr. 8. L. Dana
was published by President Hitchcock in the same report.’

In the Final Report on the Geology of Massachusetts, published in 1841
(page 91-92), Hitchcock reprinted, without additional comment, the statements
concerning the greensand in Duxbury and Marshfield.

In 1850, Dr. Jackson," of Boston, stated, in remarks on the Tertiary deposits -
at Marshfield, that a shark’s tooth, a cetacean vertebra, lignite, and the cast of

1 Report on ne deposits. The Voyage of the Challenger, pp. 323-324. Zodlogy of - eee
Expedition, pt. 8, pp. 126-127; also Turner, Report on Seals, Zool. Challenger Exp., pt.

2 Notes by a naturalist made during the voyage of the Challenger, revised edition, Now BES and
London, 1892, p. 178. Moseley notes that eee are eaten by seals (p. 164); hence seals may not vol-
ae take up pebbles from the shore or the bott:

tehcock, Edward, Report on the geology, eee botany and zodlogy of Massachusetts,
pp. L Amherst, 1833.
4 Hitchcock, Edward, Report on a reéxamination of the economical geology of Massachusetts, p. 76,
Boston, 1838.
5 Hitchcock, Edward, op. cit., p. 7
8 Jackson, ee Proce. oe Soc. Nat. Hist., 3, pp. 328-324, 329, 1851; also Proc. Am. Assoc.
Adv. Sci., 4, 1851, p. 251.

CAPE COD GEOLOGY 21

a Tellina had been found in clay marl over a deposit of greensand at a depth of
30 feet from the surface.

In 1890 Shaler! published a brief report on a geologic examination of the
greensand deposit at Marshfield, made with the help of his assistant, C. P.
Sinnott. Shaler remarks that the area occupied by the greensand, as shown in
excavations, covers more than a square mile. The material consists of layers of
greensand substantially like those at Gay Head. The beds appear to be horizon-
tal. The few molluscan remains found were regarded as possibly of Cretaceous
age.

The greensand collected by Mr. Sinnott contained a few marine fossils —
the casts of two mollusks (see Pl. 5), and fragments of crabs, one like that com-
mon at Gay Head and the other an undescribed form with a very large telson.

Fossils in Greensand at Marshfield, Mass.

Mollusks:

Panopaea sp. cf. P. goldfussi Wagner. Interna] cast of both valves.

Venus sp. cf. V. campechiensis var. mortoni (Conrad). Internal cast of right valve.
Crustacea:

Cancer proavitus Packard.”

The fossil shell that Jackson called Tellina is probably the Macoma lyelli of
Dall, which is common in the greensand bed at Gay Head. The fossils found at
Marshfield and the bed containing them resemble so closely the fossils and the
bed at Gay Head that the two beds probably belong at the same stratigraphic
horizon.

- The deposition of the greensand at Marshfield directly on the granitic
surface, without any remnants of the intervening Cretaceous beds found on
Marthas Vineyard, shows that there is a great gap here between the Upper
Cretaceous and the Miocene, a gap including all of the Eocene and Oligocene
epochs.

ORIGIN OF THE GREENSAND

Late in Miocene time the sea invaded the lowland of Massachusetts and
Rhode Island, as shown by the position of the beds of greensand in Marshfield
and Duxbury, which rest on the granite that then formed the border of the

1 Shaler, N. S., Tertiary and Cretaceous deposits of eastern Massachusetts, Bull. Geol. Soc. America,
1, p. 447, 1890. ae Report on the Atlantic Coast Division, Eleventh Ann. Rept. U. S. Geol. Survey,
pt. 1, p. 63, 1891.

2 Packatd: A.8., A new fossil crab from the Miocene greensand bed of Gay Head, Marthas Vineyard,
Proc. Am. Acad. Ane and Sci., 36, pp. 3-9, pls. 122, 1900. Cushman, J. A., Fossil crabs of the Gay Head
Miocene, Am. Naturalist, 3, ie 381-390, pls. 1, 2, 1905.

22 CAPE COD GEOLOGY

continent. The beds of the same age on Marthas Vineyard, at Gay Head, have
undergone so much deformation and dislocation that their present elevation
above the sea, in the crest of folds, does not indicate that they were laid down
above sea level. The depth below sea level and the distance from shore at which
the beds of greensand and their fossil crabs, fish, and marine mammals were
laid down are not certainly known. The deposits of greensand that are now
being formed on the sea floor lie so far out at sea that relatively little mud and
sand reaches them from the shore. Pure greensand is laid down in water having
a depth as great as 900 fathoms, but it may accumulate in shallower water
at places where mud and sand are excluded from it by the nature of the shore
or by the absence of offshore currents to carry out débris from the land. The
presence of grains of quartz in the Miocene beds at Marshfield and Gay Head
show that those beds were laid down in relatively shallow water. The bed of
greensand at Nonamesset, which lies nearer the theoretical shore line of the
Miocene sea, contains much more quartz and coarser grains of it than the bed at
Gay Head. Conditions for the deposition of greensand containing terrigenous
material would probably be provided by the submergence of the lowland of east-
ern Massachusetts and Rhode Island to a depth that would carry the shore line
in the longitude of Worcester up to the present 500-foot level. Such a shore line
would extend nearly northward, passing through the eastern parts of the Kent,
Burrillville, Blackstone, Marlboro, and Groton quadrangles. The remnants of
the beds of greensand at Marshfield and Gay Head now lie about 45 miles sea-
ward from the 500-foot contour line, and the depth of water over them, under the
conditions here assumed, would have been somewhat more than 450 feet. Most
of the present coast of eastern Massachusetts would then have been submerged.

The casts of mollusks and crustaceans and the bones of cetaceans found at
Gay Head and Marshfield suggest the depth of the water there, but their probable
mode of burial should be considered before conclusions based on them are formed.
The bones of the cetaceans are strewn through the deposits in a way to indicate
that they were laid down at about the same time as the foraminifers that make
up most of the greensand. The remains of crabs found in the greensand were prob-
ably also entombed with the growth of the deposits. Shallow water is preferred
by species closely allied to those found in these beds of greensand. Of the mol-
lusks, particularly the clam-like forms, one of which (Macoma lyellt) is found
with both valves intact, in the attitude of life, in the greensand at Gay Head,
it may be said that they might have lived beneath the surface of the bed of green-
sand after the water above it had become shallower than that in which it was

CAPE COD GEOLOGY 23

deposited. The late Miocene sea, therefore, may not have stood above the up-
land about Worcester, for if it had reached that height the land to the west
would have stood so high that its position could not be harmonized with the
indications of shallow water over the remnants of the Miocene offshore deposits.

The greensand beds give little indication of the conditions near and along
the shore, for they contain no detrital material that can be traced to the Paleozoic
rocks of the inland. The pebbles and grains of quartz in the greensand may have
been derived from the remnants of Cretaceous beds over which the Miocene sea
transgressed after an epoch of Oligocene land. No definite trace of the Miocene
shore has yet been recognized and, as the Miocene beds contain no waste derived
from the ancient rocks, the marine invasion in Miocene time must have been
short and could not have left strongly marked sea cliffs in the crystalline rocks
of the upland.

CHEMICAL ANALYSES OF THE GREENSAND

The greensand in Marshfield and on Gay Head has never been used in agri-
culture, so its chemical analyses are incomplete. Three analyses that have been
published are reprinted below, along with analyses of other greensands.

Chemical Analyses of Greensand

Constituents 1 2 3 4 | 5 | 6
SiO, 56.70 49.23 51.25 50.85
AleOs 13.32 “11 L2D 8.92
Fe,03 20.10 20.89 20.72 21.40
FeO . 3.00 1.66
MnO S tr Ge

CaO 0.65 1.09 1.62 tr. 1.26
MgO - ie 1.18 3.44 5.98 3.13
Na:,O 0.33 0.38 ] 0.11 192 0.25
K,0 4.16 3.87 8.51 6.21 4.21
HO... . <a 1.83 6.49 9.00
HO+ . . S = 4.88

P.O; . . . 0:22 0.48

CO; 2 0.14 0.16

Sources of the Materials Analyzed

1. Material resembling greensand from north end of Gay Head section. Analysis made
in the laboratory of the U. S. Geological Survey and reported to Professor N. S. Shaler by
F. W. Clarke, Seventh Ann. Rept. U.S. Geol. Survey p. 360, 1888.

2. Same as 1. Both 1 and 2 were partial analyses.

24 CAPE COD GEOLOGY

3. Glauconite from Gay Head; analysis by Dana. Dana, J. D., and Brush, J. G., De-
scriptive mineralogy, 9th ed., New York, p. 462, 1889.

. Glauconite from Big Goose Canyon, 15 miles southeast of Sheridan, Wyo. Analysis
by George Steiger (sp. gr. 2. 73). From Analysis of rocks and minerals, U. S. Geol. Survey
Bull. 591, p. 340, 1915.

5. Glauconite from an igneous rock at Mount Baldo; analysis by Delesse, 1848. Dana,
J. D., and Brush, J. G., Descriptive Mineralogy, 9th ed., New York, p. 462, 1889.

6. Glauconite from Station 164B (410 fathoms), No. 85. Report of Challenger Expedi-
tion on deep-sea deposits, p. 387.

For references to important papers on glauconite and additional analyses of materials
from foreign localities, see Clarke, F. W., The data of geochemistry, U. S. Geol. Survey Bull.
330, pp. 489-442, 1908; and Bull. No. 491, pp. 492-494, 1911. On the Cretaceous greensand of
New Jersey and its origin, see Clark, W. B., A preliminary report on the Cretaceous and
Tertiary formations of New Jersey, Ann. Rept. State Geologist for 1892, pp. 218-239, and
Plates 4-6, reproduced from Challenger Expedition report. Analyses of New Jersey green-
sands at p. 230. Clark (p. 220) cites Pourtales as reporting greensand at depths from 50 to 100
fathoms on the present sea floor off the coasts of Georgia and South Carolina.

See also Ashley, G. H., Notes on the greensand deposits of the eastern United States,
U.S. Geol. Survey Bull. 660, pp. 27-49, 1918; Goldman, M. I., The petrography and genesis
of the sediments of the Upper Cretaceous of Maryland, Maryland Geol. Survey, Upper Cre-
taceous, pp. 111-182, 1916; Collet, L. W., Les depdts marins, pp. 132-194, 303-306, Paris,
1908; and Thoulet, M. J., Etude bathylithologique des cétes du golfe de Lion, Inst. océano-
graphique Annales, 4, No. 6, pp. 62 et seq., Paris, 1912.

FOSSILS FROM THE GREENSAND AT GAY HEAD AND NASHAQUITSA
Of the fossils collected from the greensand beds in the Gay Head cliffs in
1889 by Dr. A. F. Foerste and J. B. Woodworth, Dall identified the following

species:
Yoldia limatula Say Venus (Gemma) purpurea Lea
Nucula shalert Dall Mya, probably M. arenaria L.
Area (like A. ponderosa Say) Panope goldfussi Wagner
Angulus sp. Cardium virginianum? Conrad
Macoma lyelli Dall Chrysodomus (cf. C. liratus Martyn)
Lueina sp. Chrysodomus, probably C. stonei Pilsbry
Venus mortont Conrad Pecten (cf. P. irradians Lam.)
Macrocallista? sp. Solen solen (fragment)

Cardium virginianum Conrad, listed with the species found in the greensand
bed, is found on the cliff in the talus just below the outcrop of the osseous con-
glomerate. A specimen was found there by me in 1889, and Professor Charles
Killam of Harvard University picked up a specimen of the same species at about
the same place in my presence in 1917. The casts are composed of a white kaolin-
ite containing grains of quartz, and the bed is apparently identical with that
beneath the Aquinnah! or the osseous conglomerate of Hitchcock, which is

1 Aquinnah, the Indian name for Gay Head, is used in this report for the osseous conglomerate of
Hitchcock.

CAPE COD GEOLOGY 25

usually regarded as of Upper Cretaceous age. In the broken interior of the speci-
men collected in 1917 there is a tooth, about 2 mm. long, of a small fish having
the habit of minute forms referred to Lamna cuspidata Agassiz, which ranges in
New Jersey from the Cretaceous ? through the Eocene into the Miocene. No
specimens having this matrix of white kaolinite have been seen in place at Gay
Head. If a specimen of Cardium virginianuwm should be found in place in the kao-
linite bed below the osseous conglomerate, it would indicate that the Chesapeake
Miocene included beds of white clay and kaolinite older than the osseous con-
glomerate and probably also older than the bed of greensand, but younger than
the beds carrying identifiable remains of Cretaceous plants.

A fragment of the inner cast of the body whorl of a species of Nassa found
in the greensand bed at Gay Head in October, 1917, by Mr. L. G. Darrow, of
Cambridge, Mass., was submitted to Dr. Dall, who remarked its essential agree-
ment in sculpture with the Miocene Nassa trivitattoides of Whitfield, from New
Jersey, a species occurring also in the Miocene of Maryland, and ranging there
from the Calvert formation upward into the Choptank. The species is restricted
to the Miocene.

The species above named were obtained from the greensand beds in: cliffs
at Gay Head between Stations 13 and 35 of the map of Gay Head published in
1897 in volume 8 of the Bulletin of the Geological Society of America as Plate 16.

The fossils collected in 1889, mainly by me, from Nashaquitsa cliffs on what
was known as the Ephraim Mayhew farm, were also reported on by Dall in 1916
as containing the following species:

Macoma lyelli Dall Modiolaria laevigata Gray
Nucula shalert Dall Venus mercenaria L. (young)
Yoldia (cf. Ysapotilla Gould) Solen sp.

Panopea goldfusst Wagner Euspira? sp.

Pecten magellanicus Gmelin Barnacle valve

Acmaea sp.

To these fossils should be added the single mesial dental or plate tooth of a
Species of Miliobates found in the greensand bed at Nashaquitsa in September,
1889, but unfortunately lost in transportation.

The fossil shark teeth and the fish vertebrae found in the greensand, particu-
larly those found in the Aquinnah osseous conglomerate, have not been identified.
Many teeth pertaining to species of Carcharodon, Otodus, Galeocerdo, H. emipristis,
and possibly other genera have been collected.t

1 For illustrations of similar fossil fish teeth see Fowler, H. W., A description of the fossil fish remains

of the Cretaceous, Eocene, and Miocene formations of New Jersey, Bull. Geol. Survey of New Jersey, 4,
p. 192,

26 CAPE COD GEOLOGY

The tooth of a mid-Tertiary rhinoceros and the rib of a walrus were col-
lected from the Miocene greensand bed at Gay Head by Mr. Daniel Vincent of
Chilmark, Mass. These and other vertebrate fossils from the greensand and from
the Aquinnah conglomerate (Hitchcock’s osseous conglomerate) have been ex-
amined and described by Dr. G. M. Allen.

The Aquinnah conglomerate and the greensand bed should be thoroughly
explored for other fossils, particularly the Aquinnah conglomerate, the only
known occurrence of which in place is in the face of Gay Head cliffs.

A few fossils were found at Gay Head under circumstances that make it
doubtful whether they originally came from the horizon of the greensand beds.
Many fossils have been found in the Aquinnah conglomerate, which was once
referred to the Miocene, but which now seems to be made up of débris derived
from beds laid down at the beginning of the Pleistocene epoch, before the glaciers
covered this district.

Edward Hitchcock! described and figured a tooth, which he referred to a
crocodile, found at Gay Head in the ‘‘ferruginous sand,” probably the oxidized
greensand. This tooth is described as silicified, a fact that led him to doubt its
geologic horizon. The specimen cannot now be found.

Lyell? visited Gay Head in April, 1842, and collected some characteristic
fossils, in addition to which he found in the hands of a fisherman a part of the
skull of a walrus differing, as he thought, from the existing species (Trichecus
rosmarus Linn.) in having one more tooth on each side of the upper jaw. The
specimen is said to have been found in the osseous Aquinnah conglomerate.

Lyell also collected from the osseous conglomerate several rolled cetacean
bones, one of which he illustrates under the generic name 1 yperoddon and another
under Delphinus. Large numbers of these bones have been taken from the bed
or picked up on the slopes below it and along the adjacent beach, where they
become blackened on contact with sea water. Some of these have been described
and illustrated by Allen,? who refers certain vertebrae to the finback whale

1 Hitchcock, Edward, Report on the geology [etc.] of Massachusetts, p. 103, Amherst, 1833. Plates
illustrating the geology and scenery of Massachusetts, pl. xl, fig. 16, 1833. Catalogue of specimens, Ap-
pendix p. 655. Specimen No. 103. See also Hitchcock’s Final report on the geology of Massachusetts,
pp. 330-341, pl. 19, fig. 18, 1841. Catalogue of State Collection, p. 803, specimen No. 103. Also in the
collection of rocks, minerals, and fossils in the State Cabinet of the Agricultural Museum at Amherst.
Catalogue of December 1, 1858, p. xvii. Section IV, Miocene Tertiary, specimen No. 48. Sixth annual
report of the secretary of the State Board of Agriculture for 1858. Appendix.

2 Lyell, Charles, Travels in North America, 1, p. 258, pl. v. London, 1845. Also American ed., p. 204,
pl. v, New York, 1845

3 Allen, G. M., The whalebone whales of New England, Memoirs Boston Soc. Nat. Hist., 8, No. 2,

p. 257, pls., 1916. Description based on collections of the Museum of Comparative Zodélogy, Nos. 3742,
9742, 8743, 8744; and the Boston Society of N atural History, No. 9698.

CAPE COD GEOLOGY 27

(Balaenoptera? sursiplana). He states that at least four genera of cetacea are
represented by the collections, among them the tooth of a squalodon (Basilo-
saurus atlanticus), which has also been found at Shiloh, New Jersey.

Crustacea are represented in the greensand by a barnacle (Balanus concavus
Brown) and two genera of crabs (Archaeoplax signifera Stimpson, and Cancer
proavitus Packard) 4

FOSSILS FROM THE GREENSAND AT MARSHFIELD AND DUXBURY

The Miocene greensand and the overlying clay marl at Marshfield and
Duxbury have afforded only a few fossils, some of which are not in existing col-
lections. The list of fossils below summarizes the notes given elsewhere in this
report.

Fossils from the Miocene Greensand and the Overlying Clay Marl at Duxbury and
Marshfield, Mass.

Foraminifera:

Casts of several unidentified species
Gastropods:

Fulgur? sp. (Turbe of Edward Hitchcock)
Pelecypods:

Venus? sp.

Venus sp. cf. campechiensis var. mortont Conrad

Panope sp. cf. P. goldfussi Wagner
Crustacea:

Cancer proavitus Packard

Large claw of a crab (?), poorly preserved
Fishes:

Oxyrhina desorit Agassiz
Mammals:

Cetacean bone (unidentified)

MIOCENE FOSSILS FROM OTHER DEPOSITS

At Nashaquitsa cliffs, on the south side of Marthas Vineyard, a considerable
number of Miocene fossils, most. of them waterworn, have been found in basal
Pleistocene gravel and sand. In 1889, in an hour’s search, I collected 70 fish teeth,
mainly those of sharks, from a bed of coarse sand that is believed to lie below the
Jameco gravel, probably the bed here called Weyquosque Sand.

‘Stimpson, William, On the fossil crab of Gay Head, Boston Jour. Nat. Hist. , 7, pp. 583-589, 1863.
Packard, A. S., A new fossil crab from the Miocene greensand bed of Gay Head, Marthas Vineyard, with
remarks on the phylogeny of the genus Cancer, Proc. Am. Acad. Arts and Sci., 26, pp. 1-9, 1900. Cush-
man, J. A., Fossil crabs of the Gay Head Miocene, Am. Nat., 39, pp. 381-390, pl. 2, 1905, includes a

restoration of Archaeoplax signifera. Collections in the Museum of Comparative Zoélogy and the Bos-
ton Society of Natural History.

28 CAPE COD GEOLOGY

PHOSPHATIC NODULES IN THE GREENSAND
In addition to the nodules containing fossil crabs in the greensand bed at
Gay Head, there are numerous dark nodules having irregular surfaces, which
Lyell spoke of as coprolites. These nodules range in diameter from one to two

/ \
id 4
\
\

at

ee a A

{

{

t

\

i

|
|
i)

4
NN

v4
wee ee

Fig.2 .— Map showing the probable Miocene boundary from Massachusetts southward
to Chesapeake Bay.

inches. An analysis made for Lyell showed that they contain no less than 50
per cent of phosphate of lime, together with fluoride of calcium, chloride of
sodium, and other constituents! Shaler, for whom a partial analysis of similar

1 Lyell, Charles, Travels in North America, 1, p. 257, London, 1845. American edition, 1, p. 204,
New York, 1845; Shaler, N. S., Report on the geology of Marthas Vineyard, Seventh Ann. Rept. U. S.
Geol. Survey, p. 360, 888.

CAPE COD GEOLOGY 29

material from Gay Head was made in the laboratory of the United States Geo-
logical Survey, states that it is made up as follows:

Phosphoric acid €P30;) «2. 2 =. 2 2800
Carbonic acid (CO;) =. «ws tt Cs 20)
lime (CaO)... tt sc tsi—“‘“‘“‘“‘“ (‘Cl
Potash (KO) }

Soda (Na,0) i ec llc CC
Sime (SO) lr —“‘C‘“Ci‘C;™COCSS

Many of the nodules enclose remains of crabs and casts of foraminifers and
of the mollusk Macoma lyelli. This association accords with the statement of
F. W. Clarke that ‘‘the organic remains which contribute to the formation of
phosphorites vary widely as regards richness in phosphates. Bones are the richest;
crustacean remains probably come next; mollusks and corals are the poorest.’ 4
The mode of segregation of the phosphate of lime in the nodules does not indicate
that they are coprolitic, but the shape of some of them countenance this view.?
Most of these concave-convex, lumpy nodules bear no resemblance to the fusi-
form, transversely constricted objects described as coprolites by their discoverer.’
Moreover, the segregations of nodular crust about uncrushed and undigested
carapaces and legs of the fossil crab Archaeoplax signifera in the greensand bed
shows that the nodulation took place through chemical processes after the de-
posit of greensand had been formed.

Penrose 4 mentions the nodules at Gay Head as ‘‘amorphous nodular phos-
phates’ and states that they have a waterworn appearance and have a hardness
of about 3. He states that they give off decayed organic matter when two frag-
ments are rubbed together. He further remarks that the nodules are too widely

scattered in the bed and hence too expensive to mine for commercial use.

EASTWARD EXTENSION OF THE MIOCENE DEPOSITS

Only two patches of Miocene deposits are exposed along this coast, that at
Gay Head and that on Nonamesset Island. In addition, however, there are
covered beds in Marshfield and Duxbury. Beds of Miocene greensand probably
once extended along the coast as a sheet, of which the present patches are rem-

1 Clark, F. W., The data of geochemistry, 2d ed., U. o Geol. Survey Bull. 491, p. 500, 1911.

2 See Buckland, Trans. Geol. Soc. London, 3, —e er., pt. 1, p. 234 et seq., with three plates, 1892;
also same author in Geology and Mineralogy, 4th ed., 1, pp. 164-176, London, 1869, and 2, Atlas, pl. 17,
1870.

5 See Bertrand, E. E., Les coprolithes = eae Memoires Musée Royal d’ Histoire Naturelle de
Belgique, 1, pp. 1-154, ae 1-15, Bruxelles,

oe R. A. E., Nature ae origin a fae of phosphate of lime, U. S. Geol. Survey Bull. 46,
p. 78, 188

i

30 CAPE COD GEOLOGY

nants. Fossils found in glacial drift on Nantucket must have been derived from
Miocene beds. In 1890 I found a Tertiary fossil near Shimmo Point and Miocene
fossils near Polpis Harbor, both on Nantucket. I also found a nodule of green-
sand in the drift 14 miles west of the town of Nantucket, and in 1915 I found a
waterworn tooth of a shark (Megalodon) in a bed of Sankaty sand at Squam Head,
near the east end of Nantucket. The Miocene deposits of Nantucket, like most
of those of Marthas Vineyard, Block Island, and Long Island, were probably
wholly removed by the action of the sea and of the ice at the beginning of Pleisto-
cene time.

The Miocene marine deposit of southeastern Massachusetts affords the
northernmost trace of the Atlantic Ocean on the east coast of North America
in mid-Tertiary time. (Fig. 2, p. 28).

PLIOCENE SERIES

A thin bed of marine sand containing a Pliocene marine fauna was found
by Gratacap near Southampton, Long Island, and fossiliferous sands of Pliocene
age have been recognized by Dall at Gay Head, on Marthas Vineyard.

Dall,;| who examined and identified the marine fossils in a large collection
made at Gay Head, states that, ‘‘On the whole, these specimens indicate a more
recent fauna than the Miocene on Marthas Vineyard and may perhaps be re-
garded as representing the Pliocene.’ These deposits of marine fossiliferous sand
have apparently nothing in common with the so-called ‘‘Lafayette formation”
of the southern coastal plain, though they occupy about the same stratigraphic
position. The results of Dall’s investigations at Gay Head would seem to favor
their reference to an early rather than to a late Pliocene age, and they are, there-
fore, probably somewhat older than the ‘‘Lafayette formation.” ? No apparently
equivalent beds of marine sand of Pliocene age have been recognized on the
coastal plain north of Virginia.

Shell-bearing beds of sand have been found on Long Island, Gardiner’s
Island, Fisher’s Island, at Gay Head, on Marthas Vineyard, and particularly at
Sankaty Head, on Nantucket. Most of the fossil shells are those of species now
living either in adjacent marine waters or along the coast south of New York.
In the upper part of the section at Sankaty Head forms have been found which,
though not now known on the Atlantic coast, are living in the seas of Alaska.
Prior to the discrimination of the several divisions of the Pleistocene deposits in

Dall, W. H., Notes on the Miocene and Pliocene of Gay Head, Marthas Vineyard, Mass., Am.
See 48, p. 300, October, 1894.
2On ye general nature and interpretation of the so-called Lafayette formation, see Shaw, E. W.,
U.S. Geol. Survey Professional Paper 108-H, pp. 128-132, 1918.

CAPE COD GEOLOGY dl

the New England Islands, all these fossiliferous beds were usually referred to a
post-Pliocene date. For a time, indeed, Dana regarded the deposit at Sankaty
Head as postglacial. Recent work has shown that certain deposits of sand con-
tain extinct species as old as Pliocene. One such deposit lies near Southampton,
on Long Island, and one was found in the cliffs at Gay Head, on Marthas Vine-
yard. At both places Miocene mollusks were found and at both the deposits
rested directly on Miocene beds, so this horizon of fossiliferous sands is probably
older Pliocene. The formation contains Macoma lyellt Dall at Gay Head and
Arca limula on Long Island. Gratacap! describes the discovery of Arca (Scaph-
arca) transversa Say, and Arca limula Conrad, in a “light yellow sandy marl,”
at a depth of 8 to 10 feet below the surface on the side of a bare hill in a road
6 miles east of Southampton, Long Island. Neither of these species is mentioned
in the Maryland report on the Miocene (1904). Dall? states that Arca limula
is confined to the Miocene in South Carolina, North Carolina, Maryland, and
New Jersey, to the Pliocene in South Carolina, Georgia and Florida, that it is
now extinct, and that it was probably the ancestor of Arca ponderosa. Gratacap
refers the deposit on Long Island to the Pliocene.

The shell-bearing beds on Nantucket, known as the Sankaty sand in part,
were referred by Dall to a late Pliocene age. In this report the Sankaty sand is
referred to the Pleistocene, as it was by Fuller. There is an unquestioned older
Pliocene horizon on the islands, known only in a fragmentary way, but probably
having a considerable extension as a bed of sand, with or without fossils, beyond
the two localities at which fossils have been discovered. The bed at Southampton,
though not the first discovered nor the most richly fossiliferous, is the only known
deposit that presents the possibility of yielding greater results on further ex-
ploration.

The older Pliocene in the cliffs at Gay Head, here correlated with the Tertiary
beds of sand found at Southampton, was discovered in a small pocket that had
been faulted down into the Miocene greensand bed. The deposit of sand was
almost entirely removed in 1889. According to Dall’* the fauna comprised the

following species:

Venericardia borealis Conrad Macoma lyelli Dall?
Astarte castanea Say Nucula shaleri Dall. var.?
Spisula polynyma Stm. Purpura lapillus L.

Corbicula densata Conrad

1 Gratacap, L. R., Tertiary fossils on Long Island, The Nautilus, 28, pp. 85-86, 1914.
* Contributions to the Tertiary Fauna of Florida, 1898.
3 Dall, W. H., Notes on the Miocene and Pliocene of Gay Head, Am. Jour. Sci., 48, pp. 296-301, 1894.

32 CAPE COD GEOLOGY

Of these shells Dall remarked that Corbula densata had been found in the
Upper Miocene of Virginia, that it occurs in the Pliocene of South Carolina, and
that the Venericardia is one of a recent type rather than the Miocene V. granulata.
The shells in these beds of sand at Gay Head had not been dissolved out, as are
those in the underlying beds, a fact which implies a more recent origin than the
apparently conformable contact of the beds of Pliocene sand in these deeper
water deposits would indicate. The shells are broken as if by pressure exerted
during the dislocation and folding of the beds.

If the beds of Miocene greensand and their shallow-water molluscan remains
indicate the maximum depth and encroachment of the sea upon the Massachu-
setts lowland during the Miocene epoch, the beds of Pliocene sand at South-
ampton may be interpreted as marking a much shallower sea, which presumably
covered the site of the New England Islands.

The deposit at Gay Head was found under the lighthouse at an elevation of
80 feet above the beach, but this elevation has no certain relation to the elevation
of the formation prior to its deformation. The remnant of the formation on
Marthas Vineyard was little more than a foot thick. The deposit on Long Island
is apparently not more than a few feet thick.

The Sankaty sand on Nantucket Island, certain beds of which are by Dall
referred to the newer Pliocene, is described below as a Pleistocene interglacial

marine deposit.

QUATERNARY SYSTEM
PLEISTOCENE SERIES
EARLY INVESTIGATIONS
New England is mantled with deposits of till, gravel, sand, and clay, the
superficial parts of which, at least, were laid down by an ice sheet that came
down southward to a front that extended along the New England Islands from
Nantucket westward across Lond Island. On Cape Cod. and the islands south
of it these glacial deposits have been subject to great disturbance, as well as to
erosion during epochs at least as long as those in which they were laid down
(see PI. 6).

In the earliest surveys of the New England Islands and Cape Cod the older
granitic gravel and sand were usually assigned to the Tertiary system, the de-

posits of which in this region are inextricably intermixed with the Pleistocene
beds by folding, faulting, and commingling. Thus, in the reports of Hitchcock,
Lyell, and Shaler, the older Pleistocene as now determined was not distinguished

CAPE COD GEOLOGY 33

from the latest Tertiary, although the glacial origin of certain beds in the Pleisto-
cene of Marthas Vineyard had been suggested by Shaler in 1888.!

McGee? first recognized the Pleistocene age of certain deposits that are
older than the so-called terminal moraine on the Atlantic slope. After Chamberlin
had made his masterful survey of the drift sheets of the Mississippi Valley, McGee
established the existence on the Atlantic slope of a group of Pleistocene deposits
which he called the Columbia formation. This formation ‘‘underlies and is older
than the moraine-fringed drift sheet of the northeastern United States.” *

In summarizing his work on the Columbia formation, McGee * interpreted it
as representing a first glacial epoch, as passing northward into lower till, and as
separated by a long interglacial epoch from the well-known glacial deposits of
the northern states, the second glacial epoch of his Conspectus, the Wisconsin
glacial drift of current geological nomenclature.

Shaler, in a revision of his own work on the Gay Head section, published in
1890,° reaffirmed his belief in the glacial origin of the infolded conglomerate bed
in the series but remained undecided between a late Tertiary and a Pleistocene
date for the epoch of glaciation. In a section of the Gay Head cliffs prepared by
me under Shaler’s direction, the glacial gravel, sand, and associated material
that lies above the Miocene and unconformably beneath the latest or Wisconsin
drift are called interglacial and preglacial, and are grouped in three divisions, as
follows, in ascending order: |

8. Sands and clays
7. Ferruginous sands
6. Gravel and boulder beds -

In this work it was shown that the glacial series in the Gay Head section, no
matter how much infolded and overthrust by Miocene and Cretaceous beds, are
comparable with the latest drift of the surface moraine and lie stratigraphically
above demonstrable Tertiary beds. A small patch of fossiliferous sand that
overlies the Miocene greensand and that was later referred to the Pliocene system
was not included in the section as drawn. Shaler’s paper showed that, on Marthas
Vineyard, deposits essentially like the Pleistocene glacial deposits had been

_ ‘Shaler, N. S., Geology of Marthas Vineyard, Seventh Ann. Rept. U.S. Geol. Survey, pp 336-337,
1888.

McGee, W. J., Three formations of the middle Atlantic slope, Am. Jour. Sci., 35, pp. 120-148, 328-
330, 367-388, 448- 466, 1888.
McGee, op. cit., p. 461
“McGee, Cunssetus of American Quaternary phenomena, op. cit., p. 462.
> Shaler, N. 8., Tertiary and Cretaceous deposits of eastern Meschiere, Bull. Geol. Soc. America,
1, 1890, pp. 443-452.

34 CAPE COD GEOLOGY

separated from the latest drift of the terminal moraine by long erosion. These
deposits extended downward as a distinct group, separable from the determinable
Miocene and the remnant of what was later shown to be Pliocene by the readily
recognized characteristics of the Columbia formation of McGee.

In 1897, in continuation of field work under the supervision of Shaler, I
made a study and comparison of the sections at Clay Head on Block Island and
at Gay Head on Marthas Vineyard. In a report on this work! I presented evi-
dence of an epoch of erosion prior to the deposition of the earliest Pleistocene on
these islands. All the beds of granitic gravel and sand in the two sections were
referred to the Pleistocene because of their stratigraphic relations to the over-
lying glacial moraines and because of their relatively slight decomposition as
compared with the quartzose and clayey sediments of the determinable Tertiary
and Cretaceous beds in the basal parts of the sections. A further reason for re-
garding the beds of boulders and sand as glacial and Pleistocene was found in
the northern origin of the glacial drift. After examining a section at Sankaty

Head, on Nantucket, I grouped the beds as follows:

Pleistocene Formations, Classification of 1897

Wisconsin frontal moraine. Last glacial epoch.

Vineyard interval of erosion. Last interglacial epoch.

Tisbury beds; clay, sand, and scattered boulders.

Erosion interval and unconformity following the Gay Head diastrophe; now referred
to ice thrust.

Sankaty epoch; granitic gravel and sand in folded beds carrying marine fossils on
Nantucket.

Lower boulder bed; recognized in Gay Head cliffs.

In 1901, subsequent to the work on Marthas Vineyard, I published an ac-
count ” of the glacial deposits of the Oyster Bay and Hempstead quadrangles, on
Long Island, where, below the Wisconsin moraine, an eroded surface was found
representing an interval equivalent to the Vineyard interglacial stage, beneath
which surface lay gravel and sand separated by a bed of till. To the whole of these
deposits the name Manhasset was given, in the belief that it was a local equiva-
lent of the ‘‘Tisbury beds” on Marthas Vineyard. The names Tisbury and
Manhasset were used as local designations, for it was not considered desirable to
extend the use of the names of Pleistocene deposits beyond the states in which
they are found. Below the Manhasset on Long Island there was also found a blue

1 Woodworth, J. B., Unconformities on Marthas Vineyard and Block Island, Bull. Geol. Soc. America,
8, pp. 197-212, 1897.

2 Woodworth, J. B., Pleistocene geology of portions of Nassau County and Borough of Queens,
Bull. New York State Mus., 48, pp. 617-668, with colored geological map, Albany, N. Y., 1901.

CAPE COD GEOLOGY 35

clay, the base of which was not seen. This clay was, with some doubt, regarded
as a basal part of the older Pleistocene, for which McGee’s name Columbia was
retained.

Fuller’s determination of the Pleistocene stratigraphy had fixed the position
of the beds of laminated blue clay not only on Long Island but on Marthas
Vineyard, where their relations to the Pleistocene series had not been clearly
made out. It is true that in certain sections on the north shore of Marthas Vine-
yard I had included them in the ‘“Tisbury beds,” but in our work on the south
side of the island neither I nor Shaler had satisfactorily separated these Pleisto-
cene beds of blue clay from the Tertiary and Cretaceous beds with which they
had been confounded.

Fuller’s determination of the position of the beds of Gardiners clay has made |
it possible to fix the position of other Pleistocene beds immediately above and
below them in the islands east of Long Island, and my associate, Dr. Edward |
Wigglesworth, has found this clay bed a satisfactory horizon marker for the '
older Pleistocene deposits on Marthas Vineyard.

Of the Mannetto gravel of Fuller and the unconformity succeeding it below
the Maneco gravel, it may be said that different deposits are found on Marthas
Vineyard in an apparently equivalent position, as explained beyond, and beneath
them occur deposits that appear to be older than Fuller’s Mannetto gravel. To

these underlying deposits new names are here given.

CLASSIFICATION OF THE PLEISTOCENE DEPOSITS
ADOPTED IN THIS REPORT

All the Quaternary deposits on the New England Islands from Long Island
eastward to Marthas Vineyard and from the Jameco formation upward to the
Wisconsin moraines are easily recognized and singularly persistent, but their
equivalents on Nantucket and Cape Cod have not been certainly determined.
Below the Jameco gravel, and certainly below the unconformity in the sections
at Gay Head cliffs on Marthas Vineyard and at Clay Head on Block Island,
there is a complex series of glacial deposits, mainly stratified gravel and sand,
which appears to occupy, at least in part, the position in the section assigned
to the Mannetto gravel on Long Island by Fuller; but these deposits cannot be
correlated with any lithologic equivalent in Fuller’s Mannetto deposits. The

deposits agree in containing pebbles of feldspar-bearing rocks, such as granite de- |
rived from the mainland. The chert pebbles found in the Mannetto on Long
Island appear to be equivalent to the chert pebbles found in the Aquinnah or

36 CAPE COD GEOLOGY.

osseous conglomerate on Gay Head; but this deposit contains no feldspar-bearing
pebbles, and it carries remains of fossil animals that range in age from Miocene
to early Pleistocene, which have not been found on Long Island. The glacial
deposits on Block Island and Marthas Vineyard below the unconformity men-
tioned may represent the whole of the Mannetto, but they seem to begin with
signs of glaciation in ice-transported boulders, which are followed by gravel and
sand deposited in water long before the epoch of close folding of the preéxisting
beds in those islands at the time of the Mannetto ice advance.

A striking feature of the glacial deposits on these islands is their content of
undecomposed feldspathic minerals, the essential constituents of such rocks as
granite, diorite, and other igneous and metamorphic rocks of the adjacent main-
land on the north, from which they were derived by glaciation. The underlying
deposits, including the Aquinnah conglomerate (here assigned to the oldest
Pleistocene because it contains traces of a horse of that age) and the still older
Miocene and Cretaceous deposits, contain no quartzite pebbles, though quartz
pebbles are abundant, and none of the kinds of rock that make up the bulk of the
glacial series. This lack of feldspathic deposits appears to be due to the weather-
ing, in preglacial time, of certain beds, such as those of kaolinite, which is made
up of grains of quartz and clay, the clay representing decomposed particles of
feldspar.

Excluding the superficial glacial material of the Wisconsin stage, whose
thickness reaches 50 feet in the more massive morainal knobs and in the gravel of
the outwash plains fronting the terminal moraine, the older Pleistocene deposits

have a maximum thickness in the islands of about 250 feet, as follows:
Feet

ae HOMMAUON 2 5
Jacob sand . 10 0 0
Gardiners a :
Jameco and Manustis Pactesd : oD)
Weyquosque formation and Dukes bonider ba SD)

AQUINNAH CONGLOMERATE (OSSEOUS CONGLOMERATE)
The Aquinnah conglomerate (the osseous conglomerate of Hitchcock) is a
local deposit of preglacial age. It is known only on Marthas Vineyard, where it
forms a bed in Gay Head cliffs. It has already been mentioned here because it

contains vertebrate remains ranging in age from Miocene through Pliocene to
early Pleistocene. The bed exposed to view in Gay Head cliffs has been greatly
eroded by the ice in its earlier advances. Scattered boulders of the conglomerate

Classification and Correlation of the Pleistocene Deposits of Cape Cod and the New England Islands
(Oldest formation at bottom, youngest at top)

Stage

Origin | Name, location, and distinctive features

Name ee to deposits on New England
ands and Cape Cod

Mississippi Valley classification
adopted by U. 8S. Geological Survey

Wisconsin Falmouth' or “inner” morain e (=Charlestown moraine

Glacial
: of R. I. and Harbor Hill cane of Hae Island)

Nantucket or ‘‘outer’’ moraine (= Ronkonkoma moraine
of Long Island)

almouth moraine Plymouth interlobate
moraine .

|

Nantucket moraine

VINEYARD Interglacial ree Lane reed by erosion on Block Island,
arthas eyard, Nantucket and Cape Cod, but
accompan yy some marine deposits, ae locally, on

Marthas vec. by some beds of p

Vineyard formation

Wisconsin stage (glacial)

MANHASSET Glacial Hempstead gravel

Montauk till. Long Island to Marthas Vineyard

Herod gravel

|
| Hempstead gravel member

Peorian stage aes)
Iowan stage
Sangamon oe (interglacial)

Manhasset formation
| Montauk till member

JACOB Transitional Sand, transitional, closing the episode of submergence

Episode of submergence, characterized by stratified
marine blue clay of glacial origin

GaRDINERS Interglacial

Jacob sand

Illinoian stage (glacial)

Gardiners clay

Yarmouth stage (interglacial)

JAMECO Glacial

Coarse gravel, the chief Ae a beneath the Gardiners
clay; of typical Jameco t

The Sige al Joe bed on Gay Head and its
mn Block Island at Clay Head.

Moshup till member

Jameco :
tae, Coarse gravel of typical Jameco type

Ferruginous boulder bed

Post-MANNETTO Interglacial Characterized by deep erosion on Long Isl
with on es Vo om

a sharp

Jameco grave

(Not accompanied by deposits)

Kansas stage (glacial)

Aftonian stage (interglacial)

Glacial Traces of glacial ee alee on pie Island ascribed
by Fuller to an he
time at Clay Hi

on Marthas Vibeanid is attributed to thrust by thei ice
ro

MANNETTO

due the stony
Head (a ice-laid till without
boulders) and the overlying gravel be

Mannetto formation

oe sand and gravel on Marthas Met ees and Block

and (Weyquosque formation) and contemporaneous

ae sand of Nantucket and Cue Cod (Sankaty
sand

Interval of glacial re-
cession and marine

invasion

Weyquosque
(elacial f an d Sankaty sand (marine sand)
and g

Glacial. Possibly first saat, boulder deposits of glacial origin; at Gay Head

base eistocene section; boul ~beari ing gravels,
netto stage. .; all known deposits reworked by water. Deposits
largely beneath sea level except at Gay H cliffs,

ea
Clay Head, and possibly a few other localities

Dukes boulder bed

Nebraskan stage (glacial)

(Probably equivalent to Jerseyan drift of
New Jersey)

Preglacial conglomerate bed at Gay Head cliffs, com-
of quartz and chert pebbles, with fossil bones of
i and a Pleistocene

Non-glacial

0.
horse; probably an old stream hae

Aquinnah conglomerate

(No known correlative)

Unconformable on Cretaceous and Miocene.

38 CAPE COD GEOLOGY

have been found at the stratigraphic horizon of the bed elsewhere in the cliffs
and farther east, in the Peaked Hill clay pits, as well as southeast of that point,
near the locality known as ‘‘Long View.”

The paleontological importance of this small remnant of a deposit, which
consists chiefly of vein-quartz pebbles, chert pebbles, and transported teeth of
sharks and bones of cetaceans and higher mammals, without traces of such
feldspathic rocks as are found in the overlying Pleistocene glacial deposits, seems
to warrant its indication by a stratigraphic name. The name Aquinnah con-
glomerate is, therefore, here proposed, Aquinnah being a native Indian name for
Gay Head.

The fossils found in the Aquinnah conglomerate have already been men-
tioned, except those found in certain black or at some places light-grayish chert
pebbles, waterworn and smoothed, and usually not more than an inch in their
largest diameter, for which no source has been found in the New England region.

The occurrence of fossils in these pebbles was announced by me in 1891,
but they were then erroneously referred to the Cambrian system. In a later note,’
they were referred to some horizon as high as Silurian, on the authority of Wal-
cott, who had examined some of the material. The fossils found consist of small
species of bryozoa, tabulate corals, and pieces of crinoids.

A chert pebble found by me in the cliffs at Gay Head in the summer of 1920
was submitted to E. O. Ulrich, who recognized in it a branching species of the
tubulate coral Cladopera. He also recognized a longitudinal section of some
species of Aulopora, some irregular sections of some species of Aulopora, and some
irregular sections of a bifoliate Bryozoan of the genus Cystodictya. He believes
that these fossils may belong to a horizon as high as the lower Middle Devonian
rather than to that of the Lower Devonian (Helderberg), though he notes that
the New Scotland formation carries species comparable to those seen in the
specimen. He suggests that this fossiliferous chert pebble may have been brought
from the region near Hudson Bay or possibly from some place between the south-
ern end of the bay and the St. Lawrence valley.? The suggestion appears to favor
the idea that the pebbles were transported as stomach stones (gastroliths) by

seals.
FIRST STAGE OF GLACIATION

The first events of the glacial epoch in this region are correlated with a.
Nebraskan glacial stage of the Mississippi Valley and with the supposedly con-
1 Woodworth, J. B., Note on the occurrence of erratic oo us in the Neocene gravels of

the island of Marthas Viewyard: Am. Geologist, 9, pp. 243-247, fig. 3, 1
2 Woodworth, J. B. (with Shaler, N. 8. ae ee Aug. F), ae nies Geology of the Narra-

gansett Basin, U. 8. Geol. Survey Mon. 33,
3 Abstract of a letter of J. B. Weolworth see ae 30, 1920.

CAPE COD GEOLOGY 39

temporaneous Jerseyan drift of New Jersey. The deposits of this stage include
the following beds, which are named in ascending order: (1) the Dukes boulder
bed; (2) the marine Sankaty formation and the contemporaneous glacial sand
and gravel here named the Weyquosque formation; and (3) the stony blue clay
and overlying gravel tentatively correlated with the Mannetto gravel of Long
Island.
Dukes BoutpEr Bep! (First GLACIAL SUBSTAGE)
At the base of the glacial deposits in the section at Gay Head cliffs, and ap-
parently at the base in Clay Head, on Block Island, there are lenticular patches |
of boulders and cobbles of glacial origin derived from the mainland on the north.
The deposits have yielded only one striated stone, which was found in
1889 in a huddle of small boulders resting on Cretaceous deposits in the highly |
folded section at Gay Head just east of the quadrangular fold. The same huddle
of boulders contained rolled fragments of the near-by Aquinnah conglomerate,
of earlier Pleistocene age. Elsewhere in the section at Gay Head the basal gravel,
which rests on the Aquinnah conglomerate, carries isolated angular boulders of
granite, many of them deeply disintegrated, and at one place a boulder weighing
about eight tons was seen in 1889.
On Block Island a notable deposit of rounded and waterworn boulders lies
at the base of the Pleistocene section in the overturned folds at Clay Head.
The Dukes boulder bed is evidently a discontinuous deposit of glacial origin,
somewhat rearranged by the action of water. The deposit is of small extent, and
is found only where the upturning of the beds has brought the basal Pleistocene
above sea level. The underlying beds were apparently not disturbed by glacial
thrust at the time these boulders were laid down. Probably the ice sheet did not
invade the district in which the boulders are now seen; otherwise the beds con-
taining them should have been pushed up and folded as they were during later
ice advances.
The ferruginous conglomerate at the southwest end of the Gay Head section,
heretofore referred by me to this horizon, is now regarded, on structural grounds,
as a deposit laid down after the close folding occurred in that cliff.
The Dukes boulder bed is succeeded above by beds of glacial gravel and
sand and, where boulders are absent, these form the base of the Pleistocene de-
posits at Gay Head and Clay Head. This gravel and sand form the next higher

formation, here known as the Weyquosque.

1 Named from the ‘‘county of Duke’s County,” the quaint legal designation of the county comprising
Marthas Vineyard, No Mans Land, and the Elizabeth Islands, so-called in honor of the Duke of York,
to whom the islands were at one time granted.

40 CAPE COD GEOLOGY

WEYQUOSQUE Formation (GLACIAL)

This formation is named from exposures found for the last thirty years at
the east end of Nashaquitsa cliffs, on the south side of Marthas Vineyard, at the
locality known to the inhabitants as Weyquosque. In its more sandy phases
the deposit has a peculiar brownish or greenish shade, its color appearing to
depend upon the presence of glauconite derived from the Miocene greensand bed
at the Gay Head district. The gravelly phases of the deposit contain pebbles of
granite and other undecomposed feldspathic rocks. At Weyquosque (Nasha-
quitsa) the formation rests on a bed of fossiliferous gravel composed of débris
derived from Miocene deposits, or possibly from the Aquinnah conglomerate, and
from lignitic Cretaceous beds, commingled with a few pebbles of granitic and
similar rocks, such as characterize the glacial series. This local basal layer is evi-
dently of later origin than the Aquinnah conglomerate, which is of early Pleisto-
cene age. The upper part of the bed at Nashaquitsa is cross-bedded on a large
scale, and is succeeded unconformably by a bed of boulder clay. Similar deposits,
also tinged with green or brown, occur on Nonamesset Island and at the base of
the Pleistocene on Block Island. In the Gay Head cliffs, beds of gravel and sand
occupying the same basal position give way in places to the basal deposit of coarse
cobbles and boulders called the Dukes boulder bed.

In 1889 about 70 waterworn fish teeth, chiefly those of sharks, were col-
lected at Nashaquitsa. They were evidently redeposited from broken-up beds
of Aquinnah conglomerate or from Miocene fossiliferous deposits.

The beds of Weyquosque glacial sand and gravel lie essentially at the same
horizon as the marine Sankaty sand of Nantucket and Cape Cod.

SANKATY SAND (MaRINgeE)

In 1896 the gravel and sand lying above the Dukes boulder bed at Gay Head
were referred to the horizon of the fossiliferous sand on Nantucket and named
the Sankaty beds, because of the identical structural relations beneath the un-
conformably overlying Wisconsin drift and of the belief then held that the beds
of fossiliferous sand at Sankaty Head are of Pleistocene age. It now appears
probable that the Sankaty beds are a constituent part of the older Pleistocene de-
posits as here defined, and that the beds constitute a marine fossiliferous forma-
tion lying along the east coast of Massachusetts in a position equivalent to the
beds of glacial sand and gravel on Marthas Vineyard and Block Island that are
here named the Weyquosque formation.

In reports on investigations made long ago at Sankaty Head by Verrill and

CAPE COD GEOLOGY 4]

others, a bed of clay was described as lying stratigraphically below the fossilif-
erous sand, and the sand was described as having a pebbly iron-stained basal
layer. The clay below the Sankaty sand is not so clearly described as to enable
one to decide whether it is a continuation of the stratified blue clay of the Gardi-
ners type, essentially free from glacial erratics, or an oxidized stony blue clay such
as crops out at Squam Head and at points farther north on the same coast.
Scudder describes the underlying clay as ‘‘a thick bed of light-brown sandy clay”
and says that the overlying bed of gravel and sand is four feet thick, coarsest in
the upper part and more or less ferruginous, hardening on exposure to a rather
compact conglomerate. This description agrees weil with that of the glacial
conglomerate at or near the base of the Pleistocene series in the eastern islands.
The quartz-pebble conglomerate in the underlying Cretaceous deposits is not
ferruginous. Furthermore, the overlying beds of fossiliferous sand carry small
pebbles and particles of feldspar-bearing rock, a characteristic of the Pleistocene
series as a whole and a feature not observed in beds of unquestioned Pliocene
or older Tertiary sand and gravel in the New England Islands. Shaler? was
“‘disposed to believe that this lower sandy clay .. . represents the upper portion
of the lower till at Nantucket.’”’ Fuller, on physical evidence rather than on the
evidence presented by the fossils in the Sankaty beds, correlated the sand in the
Sankaty type. section with the Jacob sand, which is regarded as transitional
between the Gardiners clay below and the Herod gravel above.

Until recent years the marine fauna of the Sankaty section was invariably
regarded as of post-Tertiary age. At one time J. D. Dana erroneously assumed
that the beds are postglacial and that they form a part of his “Champlain
group,” but Upham showed conclusively that the beds were older than the last
ice advance to the island. A detailed study of the section containing fossil shells
was made during the summer of 1904 by Dr. J. H. Wilson,’ who appears to have
regarded the underlying clay as of glacial origin and “identical with the ‘pre-
Wisconsin till.’” Twenty-one species new to the locality were discovered, of
which a number were identified by Dall. Among the newly found species were
Serripes perousit Deshayes, Macoma incongrua von Martens, and Pandora crassi-
dens Conrad, the first two of which had not been previously found east of Point
Barrow. The form last named is common in the Miocene of Maryland. Dr.
Wilson appears to have assumed that the fauna as a whole lived in Pleistocene

* Woodworth, J. B., The glacial brick clays of Rhode Island and Massachusetts, Seventeenth Ann.
Rept. U. S. Geol. Survey, pt. 1, ch. 2, pp. 976-977, 1896.

* Shaler, N.S., Geology of Nantucket, U. 8. Geol. Survey Bull. 53, pp. 33-84, 1889.

* Wilson, J. Howard, The glacial history of Nantucket and Cape Cod, p. 90. The Columbia Uni-
versity Press, New York, 1906.

42 CAPE COD GEOLOGY

time. He also found a single specimen of the extinct species Chrysodomus stonet
Pilsbry.

The occurrence of a species that is elsewhere unknown above the Miocene
on the Atlantic coast and of a species of older Pleistocene age, so regarded, has
to be taken with much circumspection in determining the age of the deposit. I
found in the beds at Squam Head a shark’s tooth of the type of Charcarodon,
together with triturated shells, showing that the Miocene deposits there had been
worked over into the overlying Sankaty beds. Again at Nashaquitsa cliffs, in
1899, I collected more than seventy fossil Tertiary shark’s teeth from beds of
older Pleistocene gravel, unaccompanied by other traces of organic remains.
The redeposition of organic remains is common in the shore phases of several
fossiliferous beds on this coast. The isolated occurrence in these beds of organic
forms that are elsewhere peculiar to older strata should have little weight in
determining their age.

Dr. Wilson confirms earlier observers in recognizing a lower and an upper
series of layers in the Sankaty sand, characterized by faunal differences. The
lower beds he described as containing prevailingly species of Ostrea, Venus, and
Mya, along with mud crabs, an assemblage indicating shallow water protected
from the open sea. The upper beds carry an Arctic fauna — Macoma incongrua,
Serripes laperousst, and Pandora crassidens. The association of the local newly
identified species Astarte sankatyensis with these species in the upper shell beds
led Dr. Wilson to regard it also as a cold-water form having a northern range or
as one that had become extinct.

In regard to the horizon carrying Macoma incongrua, Dall stated! that he
regarded this species as probably upper Pliocene; but he was under the impres-
sion that the lower beds carry this Arctic fauna, whereas Wilson states that the
Arctic fauna was found in the upper beds. Although the beds at Sankaty Head
are tilted, and although the same beds between that plain and Squam Head,
as observed in 1915, are folded over into a vertical position, nothing has been
found at Sankaty Head to warrant the belief that the beds there are overturned
in such a way as to lead to the supposition that the lower one is of Pleistocene age
and the upper one of upper Pliocene age. Dall wrote as follows: *

There is no particular reason why Macoma incongrua should not be Pleistocene as well
as Pliocene, since it is now living on the Pacific side. I take it that the glacial epoch cut off the

intercommunication between the two sides of the continent; but there is no reason why some
of the Pliocene species should not have lingered on into the Pleistocene on the Atlantic side.

1 Letter to J. B. Woodworth dated November 14, 1916.
2 Letter dated November 9, 1916.

CAPE COD GEOLOGY 43

But I am confident from the association of species that the period of close intercommunica-
tion was Pliocene, because the fauna shows a milder climate than subsequently. This is true
all around the northern hemisphere.

The fauna of the Gardiners clay, as shown by Fuller and Veatch, is that of
an interglacial stage that occurred long after the beginning of the Pleistocene
epoch. In the Long Island region, this clay has afforded the following species,
listed by Fuller: 1

Anomia ephippium Modiola sp.
Bacctum obsoletum Nassa trwittata
Crepidula fornicata Ostrea virginica
Cyprina islandica Purpura lapillus
Mya arenaria Venus mercenaria
Mytilus edulis Solen ensis

Shells of Pecten, fragments of an echinoderm, of Mullinia and Astarte, have
also been either reported or identified.

The Jacob sand, which overlies the Gardiners clay, at least from Gay Head
westward, has yielded no fossils on Block Island or Marthas Vineyard. Fuller 2
refers the Sankaty Head section to this horizon and notes Sanderson Smith,’
in 1867, collected a marine fauna from the Jacob sand on the east side of Gardiners
Island.

The fauna of the Jacob sand in the western part of the New England Islands,
according to Sanderson Smith, is almost entirely molluscan, as follows:

Anthozoa: Pelecypoda:
A small coral Arca transversa Say

Gasteropoda: Arca pexata Say?
Tornatella punctostriata Adams Ostrea borealis Lam.
Bulla canalicula Gould Pecten islandicus Chemn.
Fusus decemcostatus Say Pecten magellanicus Lam.
Purpura lapillus Lam. Cardita borealis Conrad
Nassa trivittata Say Astarte sulcata Fleming
Nassa vibex Lucina radula Gould?
Columbella unata Sowerby Venus mercenaria Linn.
Chemnitzia interrupta Stimpson Mactra lateralis Say
Crepidula unguiformis Lam. Mya arenaria Linn.

Crepidula fornicata Lam.
Natica duplicata Say
Natica heros or triseriata?

Crustacea:
Balanus, fragment

Fuller credits Veach with collecting from the same section the following ad-
ditional species, identified by Dall:

Chrysodomus pygmaeus Gould Cyprina islandica Gmelin
Astarte elliptica Brown Thracia conradt Couthouy

U.S. Geol. me Prof. Paper 82, pp. 104-106.
2 Fuller, M. L., U.S. Geol. Survey Prof. Paper 82, pp. 113-114.
3 Smith, Sanderson, Ann. N. Y. Lyceum Nat. Hist., 8, pp. 149-151, 1867.

44 CAPE COD GEOLOGY

Sanderson Smith recognized the northern aspect of these forms from Gardi-
ners Island, of which Dall recently remarked:

The material appears to be practically identical from both localities and to represent the
fauna now existing in the Gulf of Maine or on the coast north of Cape Cod, a little colder water
being indicated than is now found south of the Cape.

The fauna agrees with that of the upper beds in the Sankaty sand on Nan-
tucket in denoting colder water, and Fuller,! in his report on Long Island, refers
the Sankaty sand to the horizon of the Jacob sand.

Of the species identified by Sanderson Smith and named in the above list
as coming from the Jacob sand, the following have been identified from the San-

katy sand:
Crepidula fornicata Pecten magellanicus
Neverita (Natica) duplicata Venertcardia (Cardita) borealis
Lunatia (Natica) heros or triservata Venus mercenaria
Area transversa Mya arenaria

Aside from Pecten magellanicus and associates of Venericardia (Cardita)
borealis, the peculiar northern fauna of Pacific types in the upper part of the
Sankaty sand is not found in the Jacob sand. As the Jacob sand lies near the
middle of a great series of Pleistocene deposits of glacial origin (either as originally
deposited or through the rehandling of the material during submergence) it should
not be correlated with the Sankaty sand because of a similarity in the marine
fauna brought about by cooler water, for such changes of temperature must have
occurred as many times as ice sheets advanced. Furthermore, the physical evi-
dence on Cape Cod and Nantucket as to the stratigraphic position of the equiva-
lents of the Gardiners clay and Jacob sand indicates that the Sankaty sand under-
lies both these Long Island formations as well as the Jameco gravel. The prob-
able representatives of the Gardiners clay and overlying Jacob sand of Long
Island are, as Fuller first noted, found in the ‘‘clay pounds” of Highland Light
and in the overlying yellow sand beneath the lighthouse. The shell-bearing
Pleistocene beds encountered some 200 feet below sea-level in borings at Province-
town probably belong to a formation lower than the entire section in the outer
cliffs of Cape Cod and are nearly in the position of the Sankaty sand. The San-
katy sand is, therefore, here regarded as a fossiliferous facies of a marine shallow-
water deposit laid down along the east coast of Massachusetts during the first
interglacial stage, in a stratigraphic position equivalent to that of the glacial sand
and gravel of the Weyquosque formation, which contains no contemporaneous
fossils on Marthas Vineyard and Block Island.

1 Fuller, M. L., Geology of Long Island, U. 8. Geol. Survey Prof. Paper 82, p. 114.

CAPE COD GEOLOGY 45

Mannetro ForMATION (GLACIAL)

High up in the folded beds in the cliff at Gay Head, on the sides of the hol-
low called the Devil’s Den, there are exposures of a bed of compact blue clay
containing small, angular fragments of rock and rounded pebbles. The bed is
unstratified, having the massive character of a bed of till, and has not been well
exposed within the last thirty years. In the part of the cliff northeast of the
Devil’s Den it lies above the horizon of the Dukes boulder bed and of the gravel
bed that overlies it. Above the bed of stony blue clay other beds of glacial
gravel form the high point back of the ‘‘quadrangular fold’ of Hitchcock’s
report. The bed of stony blue clay exposed southwest of the Devil’s Den is not
at the same horizon.

At a point on the north shore of Marthas Vineyard near Makoniky, beds of
similar stony blue clay crop out under the stratified Gardiners clay. As beds of
glacial till containing large boulders occur beneath the Gardiners clay on No
Mans Land and at the east end of the Nashaquitsa cliffs, in the district known as
Weyquosque, the beds of stony blue clay at Gay Head probably also lie below
the horizon of the Gardiners clay. Elsewhere beneath the Gardiners clay there is
the bed of coarse glacial gravel that Fuller called the Jameco gravel. The gravel
above the stony blue clay at Gay Head may be of early Jameco age, but in the
good exposures it is separated from the Jameco by an angular unconformity —
that is,it was not deposited when the folding occurred that has given to the section
at Gay Head its puzzling structure. The stony blue clay (till) and the overlying
bed of gravel are infolded in the section at Gay Head and are, therefore, both
referred to the Mannetto glacial stage.

Foupine at Gay Heap

The principal evidence of an advance of the ice at this stage in the forma-
tion of the Pleistocene deposits on Marthas Vineyard is found in the folding and
overturning of all the preceding deposits. On Gay Head the displacement was an
overthrust toward the southwest, which produced isoclinal folds and a conse-
quent northeasterly dip of the beds. The stony blue clays already described indi-
cate the presence of either land ice or floating ice prior to the folding of the glacial
sands and gravels and of an unknown thickness of Tertiary deposits and under-
lying Cretaceous clay. An exactly comparable section may be seen in Clay Head,
on Block Island. It seems probable that a great glacier advanced southward on
to the deposits of the Coastal Plain at this time. This glacial advance appears
to be that which Fuller inferred from the presence of the coarse Jameco gravel, a

46 CAPE COD GEOLOGY

deposit of stratified material, probably formed about the front of the ice sheet
before, during, and after the end of the advance of the ice.

The beds that were at this time thrown into close folds in the high ground at
Gay Head on Marthas Vineyard and at Clay Head on Block Island strike gener-
ally from northeast to southwest, the direction of the main axis of the islands,
except those at Gay Head, which strike more nearly from northwest to southeast,
giving a northeasterly dip to the isoclinal and overturned folds in that area. The
low land between Gay Head and the western part of Marthas Vineyard, east of
Menemsha Pond, occupies an angle between the two local lines of structural
trend and appears to have been a place of maximum forward thrust by the ice.
The general direction of the motion of the ice appears to have been normal to the
general strike. The boulders and small pieces of Cumberland iron ore (peridotite)
found on Gay Head must have been carried about the time of this dislocation
from Iron Mine Hill, in Cumberland, R. I., along a line bearing S. 47° E., a line
more nearly southeast than that followed by the ice of the Wisconsin stage.

The mass of Cretaceous beds on Marthas Vineyard that was then disturbed
by ice was apparently much larger than any mass subsequently disturbed. This
maximum effect might well be expected at the first strong advance of the ice, for
at the subsequent advances the deposits would have been pushed into attitudes
that would not strongly oppose the overriding ice. Nevertheless, the beds of
Gardiners clay and the later Manhasset deposits on the south shore and on Block
Island were notably displaced in more or less broad and open folds produced
either at the time the Montauk till was laid down or much later, beneath the

first Wisconsin ice sheet.

POST-MANNETTO INTERGLACIAL STAGE

Fuller’s term post-Mannetto is here applied to the interval of erosion repre-
sented by the unconformity between the eroded edges of the first folded beds at
Gay Head, on Marthas Vineyard, and at Clay Head, on Block Island, and the
overlying nearly horizontal beds of boulders and gravel at those places. Only
small exposures of this unconformity are seen, such as those in the southern part
of the section at Gay Head. Some of the beds on Block Island were folded after
the larger features of the structure had been developed and overthrust faults on
Gay Head broke the continuity of the plane of the unconformity. It is not known
whether the deformation is due to the continuance of the action of the glacier or

to subsequent action by the water of streams or of the sea. The immediately
overlying bouldery gravel beds at Gay Head and Clay Head were afterward de-

CAPE COD GEOLOGY 47

posited on the eroded surface. The unconformity represents the removal of an
unknown thickness of folded beds of clay, gravel, and sand. The overlying beds
of gravel show no signs of marine action, but they contain rolled fragments of the
Cretaceous and the Miocene deposits of the district, together with hardened nod-
ules of clay such as are laid down on the beds of lignite through secular rain wash.
In most of the region here considered the unconformity now lies below sea level
or is not exposed. In some areas on Gay Head the section including the uncon-
formity was worn away by erosion prior to the deposition of the Wisconsin till.

JAMECO STAGE OF GLACIATION
JAMECO FORMATION

Ferruginous Boulder Bed. The most significant bed of boulders in the older
Pleistocene deposits at Gay Head is exposed on the west side of Gay Head cliffs
from the Devil’s Den southward, where it lies unconformably on eroded and
folded Cretaceous beds and the infolded glacial gravels of the Weyquosque for-
mation. The bed consists mainly of boulders of granite and diorite, 3 or 4 feet
in diameter, but contains a large variety of smaller stones, derived from the bed
rock of southeastern Massachusetts, as well as some cobbles and pebbles of clay
cemented by iron oxide. The iron has penetrated only the outer part of some
of these cobbles, so that when they are broken their central parts wash out, leav-
ing rounded cavities. The boulders and pebbles appear to be waterworn and
show no striations due to glaciation, yet the coarseness of their materials, their
commixture, the direction in which they have been transported, and their associa-
tions indicate that they were brought to their present positions by an ice sheet
that carried them many miles south of their parent ledges. Whether the boulders
and gravel were directly deposited by water that worked over deposits of till in
place, or whether they were washed out of more ancient beds is not known. The
deposit is probably equivalent to a part of the Jameco gravel of Fuller, and it is
so classified in this report. It forms the local base of what appears to be a less
disturbed series of beds deposited about Gay Head in Jameco time, prior to the
deposition of the Gardiners clay. At Clay Head, on Block Island, very similar
boulder beds lie unconformably upon high folded older Pleistocene and Cre-
taceous deposits; but the conglomerate there is less ferruginous than at Gay
Head.

Coarse Gravel of Jameco Type. Typical glacial gravel, usually coarse, and
consisting of a great variety of small erratics derived from the mainland on the
north, is seen in the islands east of Long Island. It resembles the typical Jameco

48 CAPE COD GEOLOGY

gravel of Fuller, the type occurrence of which was stated by him to be on Long
Island, New York. The deposit was interpreted by him as indicating an advance
of the ice, but he reported no till or signs of direct ice action.

Many of the beds are ferruginous, and some have a thickness of twenty feet
or more. This gravel lies beneath the Gardiners clay in Mohegan bluffs, on the
south side of Block Island; on the south side of No Mans Land; and in Nasha-
quitsa cliffs, on the south side of Marthas Vineyard. Probably the gravel beneath
the clay at Highland Light, on Cape Cod, are at this horizon.

The typical Jameco gravel appears to be a stream deposit like those washed
out from glacial fronts in low grounds or near the sea at the present day.

Moshup Till Member. A remarkable upturned bed of boulder clay that was
exposed in Nashaquitsa cliffs, on Marthas Vineyard, for a quarter of a century
prior to 1916, occupies, at least in part, the stratigraphic position that is else-
where held by the Jameco gravel. It lies below the Gardiners blue clay and
above the beds of sand and gravel that are here called the Weyquosque formation.
(See Fig. 12 and Plate 23). On No Mans Land a similar boulder bed was exposed
in 1915 and 1916 beneath the Gardiners clay. These deposits of true boulder clay
confirm an inference drawn by Fuller from the occurrence of the Jameco gravel —
that the deposition of the Gardiners clay was preceded by a glacial invasion and
that the Jameco gravel is a product of that invasion. At one place on the north
shore of Marthas Vineyard, as already noted, a bed of stony blue clay lies be-
neath the Gardiners clay. The exposures showing the position of this bed and of
its supposed correlative beds of stony clay indicate that it replaces locally the
upper part or all of the Jameco gravel and lies immediately below the stratified
Gardiners blue clay. In Nashaquitsa cliffs the bed is less than ten feet thick. It
is decisive evidence of the second stage of glaciation on Marthas Vineyard. Ful-
ler found no equivalent till on Long Island, and it has not been observed on Block
Island. It has not been certainly recognized east of Marthas Vineyard.

In conformity with the example set by Fuller in giving the name Montauk
till member to the bed of boulder clay that divides the Manhasset formation on
Long Island, this bed of till is here called the Moshup till, from the name of a
local god in the aboriginal folklore concerning the origin of Gay Head. Like the
Montauk till, it is not a continuous sheet.

GARDINERS INTERGLACIAL STAGE

GARDINERS CLAY

Distribuivon and character.— Beds of a dark blue clay, which are usually

folded, are exposed at several places on the islands from Marthas Vineyard west-

Saisie ctiemorsaenvnnsersoee

CAPE COD GEOLOGY 49

ward and are seen in the ‘‘clay heads” on Cape Cod. These beds, which are now
correlated with the Gardiners clay, were once regarded as Tertiary or Creta-
ceous, an error due to the occurrence of certain beds of lignitic Cretaceous clay
containing fossil plants in Nashaquitsa cliffs at places where the Gardiners clay
and the glacial gravel below it and the sand above it are now extensively exposed.
Fuller and Veatch showed that this bed of clay lies above a series of beds of gravel
that are not distinguishable from the beds of glacial gravel on Long Island and
elsewhere to the east through the New England Islands wherever the base of
the uppermost bed of blue clay containing no boulders or gravel is visible.

The correlation of the beds of blue clay on Nantucket with the lenticular
beds of blue clay on Cape Cod is doubtful, principally because of the improba-
bility that a series of glacial deposits would persistently maintain parallelism, but
the field study has afforded no ground for a better correlation. The difficulty of
correlation is greatest where the clay occurs as lenses in gravel, as it does at
Highland Light, on Cape Cod, though it may be overlain by a bed of fine sand,
such as is found on the islands to the southwest.

The Gardiners clay is dark blue or, in places on Long Island, blackish; its
color there being due to lignite. It contains some lignite also on Marthas Vine-
yard, derived from underlying Cretaceous beds, which were turned up at the
time of the post-Mannetto folding and erosion. Some of the dried clay has a
whitish cast, due to the presence in it of fine grains of quartz. Although certain
sections contain thin layers the clay is generally massive and was apparently laid
down in quiet water off the shore of a shallow sea.

At a few localities,as on the north coast of Marthas Vineyard east of Menem-
sha Creek, the clay is ‘banded”’ or laminated. Sayles! has presented evidence that
such lamination is due to the changes in the conditions of deposition from winter
to summer. In deposits of clay laid down on the sea floor it might be expected
that the heavier wave action in winter would produce coarser beds in a zone
at a given distance from the shore than those formed in the zone in summer,
and that the round of the seasons would be registered in an alternation of coarse
and fine material, as shown by Baron Gerard de Geer. The banding, however,
is not generally so distinct in marine as in fresh-water deposits.

Fossils and origin.— The marine origin of the Gardiners clay is proved by
fossils found in it at the type locality on Gardiner’s Island.’ According to Fuller’s

1 Sayles, R. W., Seasonal deposition in aqueo-glacial sediments, Memoir Mus. Comp. Zodl., 47, pp.
1-67, pls. 16, February, 1919.
2 Fuller, M. L., Geology of Long Island, U. 8. Geol. Survey Prof. Paper 82, pp. 104-106, 1914.

oh eae

50 CAPE COD GEOLOGY

list the following species are essentially identical with those now living in the

sounds along the same coast:

Gastropods: Mya arenaria
Nassa obsoleta Venus mercenaria
Nassa trivittata Mytilus edulis
Crepidula fornicata Anomia ephippium
Purpura lapillus Cyprina islandica

Pelecypods: Arca cenella
Ostrea virginica Solen ensis

To this list should be added Modiomorpha nigra Gray ? of Dall’s list of fossils
found in Miocene beds on the south side of Marthas Vineyard.! This species
was found in the gray clay now known as the Gardiners clay, of Pleistocene age.
This is the only marine fossil found in the Gardiners clay east of Long Island.

This assemblage of forms indicates the marine origin of the Gardiners clay
under conditions not unlike those which prevail in the shallow water of sounds
or interisland passages off a continental coast that is being rapidly attacked by
waves carrying particles of boulder clay; which is being laid down in successive
offshore zones in the form of sheets of gravel, sand, and clay. Although isolated
cobbles and thin lenses of gravel are found on Block Island and elsewhere in beds
of clay that appear to be members of the Gardiners clay, probably as deposits
from floating ice in winter, that clay was doubtless laid down during an inter-
glacial stage, when glacial action was reduced to a minimum.

Until the Gardiners clay has been definitely correlated with the older glacial
clay in the lower Hudson valley and in the New Haven region, as well as with the
clay in the valleys of the Charles and Mystic Rivers about Boston, the attempt
to determine the depth and extent of the submergence in Gardiners time must
remain uncertain. The folding and the deformation of the beds of clay in the
islands off the south coast preclude the use of the ordinary stratigraphic methods
of estimating the initial dip of the formation and projecting the position of the
shore line. At Highland Light, on Cape Cod, beds of clay that are regarded as
probably of the same age rise about 120 feet above the present sea level and are
only slightly deformed. The submergence at that place may have exceeded 120
feet. The beds of glacial brick clay near Belmont, northwest of Boston, which
are probably older Pleistocene deposits, show an eroded surface at a height of

| about 120 feet above sea level. If the Gardiners clay and the correlative deposits

were laid down in water that was not more than 100 fathoms deep, a reasonable
assumption, there should have been formed at the same time, between them and

1 Dall, W. H., Am. Jour. Sci., 48, p. 297, 1894.

CAPE COD GEOLOGY 51

the shore, a zone of gravel and sand that was swept seaward by the undertow
and by offshore currents. Any such broad zone of gravel and sand laid down
upon the lowland of eastern Massachusetts and southern Rhode Island during
Gardiners time would have been eroded and masked by the action of succeeding
ice sheets, but thick beds of gravel and sand may have been here and there rede-
posited in kames and sand plains at later stages of the ice. A great mass of strati-
fied sand remains on the irregular slope between the upland at Worcester and the
lowland along the coast between the 200-foot and the 400-foot contour line, but
nothing is known to warrant the reference of any part of this sand to the Gardiners
stage. In the Champlain valley, at the end of the last or Wisconsin glacial stage,
beds of marine clay were laid down beneath as much as 400 feet of water, or, if
Fairchild’s estimates are correct, under more than 600 feet. The distribution
of the Gardiners clay indicates that the marine invasion then may have covered
the eastern lowland of Massachusetts as far west as longitude 71° 30’.

Where the Gardiners clay lies between beds of gravel and sand, the fall of
the clay in cliffs where it is undercut by the sea presents for a time a steep escarp-
ment, and landslides carry great masses of clay out over the beach, leaving scars
in the cliff.

JACOB TRANSITIONAL STAGE
JACOB SAND

Upon the Gardiners clay in the New England Islands lie beds of fine sand
that range in thickness from 5 to 50 feet. This sand was derived from granitic
rock and in mineral composition is like the finer wash found at some places on
the mainland, except that here and there it has assumed yellow and orange colors,
due to the decomposition of iron oxides and their redeposition in another form in
lower parts of the bed, particularly just above the impervious Gardiners clay,
where some crusts of iron were formed and are exposed at the edges of the beds
in sea cliffs. The type locality of this deposit, described by Fuller, is at Jacob,
on Long Island. Good sections of it are exposed in Mohegan bluffs, on the south
side of Block Island, as well as on the south shore of No Mans Land and at
Nashaquitsa cliffs, on Marthas Vineyard. Much of the fine sand that lies beneath
the moraines on the island of Naushon may occupy this horizon. The Jacob sand
is exposed also above a small head of Gardiners clay at Sachem Spring, in Sher-
burn bluffs, west of the town of Nantucket. Beds of precisely similar sand overlie
a bed of blue clay, tentatively referred to the Gardiners formation, in the bluffs
at Highland Light, on Cape Cod. On the mainland farther north, in Third Cliff,

52 CAPE COD GEOLOGY

south of Scituate, disturbed beds of orange-colored sand occur above blue clay
that probably belongs to the Gardiners formation.

The Jacob sand, which was laid down during the retreat of the Wisconsin
ice front, lies between the Gardiners clay below and the Herod glacial gravel
above and probably marks the retirement of the sea after its maximum sub-
mergence of the land in Gardiners time. The formation contains no fossils, unless
the marine beds at Sankaty Head, on Nantucket, belong to it. These beds, how-
ever, for reasons given, are here referred to a much lower horizon in the Pleisto-
cene.

The Jacob sand has not been certainly identified on the mainland north
and west of Scituate, but certain beds of fine sand in Boston Harbor encountered
in boring may belong at this horizon. If the beds of glacial brick clay of the
Mystic valley are extensions of the Gardiners clay, the Jacob sand in that region
has been removed by erosion.

Assuming that the altitude of the area at Highland Light, on Cape Cod, has
not been changed with reference to the bed rock of the mainland, the altitude
of the nearly horizontal bed of sand in that area that probably represents the
Jacob sand may indicate its altitude in the New England Islands prior to the
deformation of the beds. ‘The formation at Highland Light ranges from about
120 to 140 feet above present sea level, an altitude which, allowing for a rise of
the sea floor in Jacob time, would carry the formation well on to the lowland
of the eastern counties of Massachusetts south of Boston. The shore line in Jacob
time may, therefore, have lain on the present lowland rather than off the present
coast.

MANHASSET STAGE OF GLACIATION
ManHassET FoRMATION

The deposits of the third stage of glaciation are here grouped under the
name Manhasset formation. They occupy the geological position to which the
‘Tisbury group” on Marthas Vineyard had been assigned, but the ‘‘Tisbury
group” had been defined so as to include certain beds of Gardiners clay and to
exclude others.

Character and subdivisions.— As described by Fuller, the Manhasset forma-
tion consists of the following three members, here arranged in stratigraphic order
from top to bottom:

Hempstead gravel member
Montauk till member
Herod gravel member

CAPE COD GEOLOGY 53

The typical localities of these three beds are on Long Island. The beds are
well exposed in the contorted sections on the south shores of Block Island, No
Mans Land, and Marthas Vineyard, but they have not been identified with
certainty north and east of Marthas Vineyard. Where a series of beds of like
character lies in more or less rhythmic succession, it is uncertain which member
is present, unless a fairly complete section is exposed. From bottom to top the
series consists of deposits made by torrential streams that poured sand and gravel
(the Herod gravel) out from the front of an advancing ice sheet. Upon these beds
were deposited the till laid down by the ice sheet, and finally the beds of out-
washed gravel laid down over the same region during the retreat of the ice front.
Viewed in this light the deposits are the product of a single stage of glaciation
corresponding to the Manhasset of Long Island.

The Manhasset formation has suffered less deformation from ice thrust than.
any of the older divisions of the Pleistocene series in the islands, but in western
Marthas Vineyard and on No Mans Land its beds are strongly folded.

Herod gravel member.— Much of the gravel of the Herod member is coarse,
the largest cobbles measuring 6 inches or more in diameter, but at some places
the deposit is prevailingly sandy. The beds are 5 to 10 feet thick and have not
been disturbed by the deposition of the overlying Montauk till, though that till
and all the underlying beds have been in places much folded by the action of ice
subsequent to the deposition of the Manhasset beds. From analogy with other
beds of glacial gravel, it is presumed that the Herod gravel was laid down in the
open air on plains of the Jacob sand just at or above sea level. On the southwest
coast of Marthas Vineyard and thence westward to places on Long Island the
beds of gravel at this horizon are readily recognized in the sections, where they

lie between the Jacob fine sand and the boulder-bearing beds of the Montauk till.
The beds of sandy gravel seen near the tops of bluffs on Nantucket, overlying a
fine sand taken to be the Jacob sand, may be eastward extensions of the Herod
gravel, but the sections are not well exposed. The bed has not been certainly
identified on Cape Cod, nor has it been recognized about Boston, though certain
thin gravels in Third Cliff, near Scituate, are thought to belong at this horizon.

Montauk till member.— On Long Island a well-defined bed of boulder clay
lies near the middle of the Manhasset gravel and here and there shows a lateral
passage into layers of assorted gravel and small boulders. At Montauk Point,
on Long Island, the till is thicker and was traced to Block Island and Marthas
Vineyard. On western Long Island there is a boulder bed that is at few places
more than 5 feet thick, but farther east, in Mohegan bluffs, on the south coast

|
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E
4
:
q
4

54 CAPE COD GEOLOGY

of Block Island, the till is 30 to 40 feet thick and carries some boulders that
are over 6 feet in diameter. In parts of the cliffs there appear to be two beds,
separated by assorted gravel, indicating two advances of the ice, as at the Wis-
consin stage, but this appearance may prove to be due to repetition of the same
bed by overthrust. Similar beds of boulder till are seen in the bluffs on the south
side of No Mans Land, but in the western part of Marthas Vineyard, owing either
to the poor exposures of the Manhasset or the thinness of the till and the associ-
ated beds of gravel, the deposit is less well defined. North and east of Marthas
Vineyard the till, or boulder bed, has not been recognized, but the reported oc-
currence of boulders in the beds of clay encountered in the Cape Cod Canal
near its east end, and again in the lower part of the beds of clay in West Barn-
stable, on the north side of the lower arm of the Cape, makes it seem probable
that the Montauk till, rather than the lower and older Gardiners clay may occur
there near sea level. The known facts concerning the till between eastern Long
Island and Marthas Vineyard indicate that the ice which produced this de-
posit was in the form of a lobe whose axis lay over Rhode Island and eastern
Connecticut.!

The Montauk till can be distinguished from the Wisconsin till of south-
eastern New England by its large content of blue clay. No similar boulder clay
is found in the Wisconsin drift in southeastern Massachusetts. The great amount
of clay in the Montauk till may be due in part to the erosion of the underlying
Gardiners clay, which probably overlapped far upon the lowland of southern
Massachusetts and Rhode Island and to a less extent upon southern Connecticut,
though not in less thickness in the narrower lowlands of the river valleys and
in the Triassic lowland about New Haven.

The outer limit of the Montauk till is unknown. The ice sheet evidently
extended beyond the site of the outer New England islands, as did also the other
members of the Manhasset formation, but the action of the sea has commingled
on its floor the materials of numerous glacial deposits. The large boulders indi-
cated on old charts of the Nantucket shoals near the site of the modern lightship

1 Woodworth, J. B., Pleistocene geology of the Oyster Bay and Hempstead quadrangles on Long
Island, N. Y. State Mus. Bull. 48, pl. 1, Albany, 1901. Cn use of name ‘Tisbury beds” to include equiva-
lent deposits on Marthas Vineyard, see Woodworth in Seventeenth Annual Report United States Geo-
logical Survey (1895-96), pt. 1, pp. 977-978, 1896, correlation table facing p. 988. As originally defined,
the ‘Tisbury beds” prove to have included formations from the Gardiners clay to the top of the Man-
hasset formation as now defined. References to the Montauk till are made by Fuller, M. L., Probable
pre-Kansan and Iowan deposits on Long Island, N. Y., Am. Geologist, 32, pp. 308-311, 1903; Glacial
stages in southeastern New England and vicinity, Science, 24, pp. 467-469, October 12, 1906; The geology

of Long Island, U. S. Geol. Survey Prof. Paper 82, pp. 132-149, 1914. Also Veatch, A. C., Outlines of the
geology of Long Island, U. 8. Geol. Survey Prof. Paper 44, pp. 41-43, 1906.

i
|
L

CAPE COD GEOLOGY 55

show that one or more of the Pleistocene ice advances reached a latitude nearly
50 miles south of the present south coast of Marthas Vineyard.

The boulders in the Montauk till, which were embedded in impervious clay;
are fairly fresh looking. Many of them are less weathered than the Wisconsin
boulders, but what number of them were wrested from ledges during the Man-
hasset ice invasion and what number were derived from older deposits of till can-
not be determined, for many of the larger boulders in pre-Montauk beds are
but slightly weathered.

The lithologic character of the boulders in the Montauk till is practically
identical with that of the boulders in the Wisconsin drift. The greater part of

the boulders and larger cobbles on the beaches of the south coast of Block Island, -

No Mans Land, and Marthas Vineyard were probably derived from the Mon-
tauk till, and where that till has been folded and its beds have been eroded the
large boulders now found on the surface may be residual blocks that were trans-
ported for short distances and redistributed, especially by the later Wisconsin
ice sheet, into which they would have been incorporated and commingled with
boulders derived from the mainland.

Nothing seen in the Montauk till indicates that the land was then submerged ;
indeed the beds of coarse gravel immediately above and below the till indicate
that the places at which these deposits are found may have stood anywhere from
just at sea level to any elevation above the sea. In other words, the deposition of
the entire series of Manhasset beds appears to have involved no action of the sea.

Hempstead gravel member.— On Long Island deposits of glacial gravel and
sandy gravel lie upon the Montauk till in the gravel pits at Hempstead, and
thinner beds of similar gravel or sandy gravel may be seen here and there above
the Montauk till along the coasts of the islands as far east as Marthas Vineyard.
If the beds of bouldery clay about Barnstable, on the bay side of Cape Cod, are
also of Montauk age, as seems probable, the beds of gravel overlying the de-
posit there are extensions of the Hempstead gravel.

The Hempstead gravel is the natural successor of the boulder bed, for
during the retreat of the ice front across a field of subglacial till streams would
at once flow out upon the surface and deposit the drift washed out from the
melting ice. Farther south sand and still farther out clay might be deposited.

The gravel at this horizon appears to be the last remaining deposit laid down
in this region above sea level before the Wisconsin ice advance; but in the interval
between the disappearance of the Manhasset ice sheet and the advance of the first

Wisconsin ice sheet in the outer islands there was a long period of stream erosion,

56 CAPE COD GEOLOGY

and probably higher beds of the Manhasset formation, such as beds of outwash

glacial sand, were removed.

VINEYARD INTERGLACIAL STAGE

The Vineyard interglacial stage probably covers the time of the following
events in the Mississippi Valley, in chronologic order: Sangamon interglacial
stage of Leverett, Iowan stage of glaciation of Iowa geologists, and Peorian inter-
glacial stage of Leverett.

The Wisconsin drift lies unconformably upon all the Pleistocene and older
formations already described. Shaler appears to have recognized an eroded old
land surface of pre-Wisconsin date in his report on the geology of Marthas Vine-
yard, when he still regarded the pre-Wisconsin drift and the older formations of
the island as Tertiary. He writes: !

The form of the surface of the Tertiary [sic] beds compels me to believe that they retain
in good part the shape which they had before the beginning of the last glacial period. If we
could remove all the glacial waste from this surface we should find that it had a contour closely
resembling that of the chalk downs in southern England. We should see broad, rolling hills
sloping gently down to infrequent valleys, a topography characteristic of a land surface where
rain, frost, and stream had long and steadily acted upon beds of the uniform nature which
characterizes the Vineyard series.

In 1897 Shaler again described this erosion surface, giving additional in-
formation gained from a resurvey of the island. Its date was fixed as later than
that of the deposits here described as the Manhasset formation and earlier than
the Wisconsin stage. He assigned not only the erosion of the valleys in the up-
lands of Marthas Vineyard to pluvial action at this stage but also the excavation
of the neighboring sound; and he estimated that the time indicated by this
erosion was twenty times as long as the interval between the present day and the
disappearance from the island of the last ice sheet.’

In 1897 I presented further evidence relating to the epoch of interglacial
erosion that preceded the Wisconsin moraine, showing the beheadal and capture
of streams and the partial adjustment of streams to the folding of the older beds
on Marthas Vineyard, and I proposed the name Vineyard interval for this epoch.’

In the same paper traces of the Vineyard stage of erosion by running water
were reported to be recognizable beneath the drift and traces of the action of
Wisconsin ice on Block Island. Still later, in 1901, the same erosion surface was

1 ee N. S., Report on the geology of Marthas Vineyard, Seventh Ann. Rept. U. 8. Geol. Survey,
p. 628; |

2 fe N.S., Tertiary and Cretaceous deposits of eastern Massachusetts, Bull. Geol. Soc. America,
1, p. 448, 1890.

3 Woodworth, J. B., Unconformities of Marthas Vineyard and of Block Island, Bull. Geol. Soc.
America, 8, pp. 208-209, "211-212,

CAPE COD GEOLOGY 57

recognized on the north shore of Long Island in the towns of Oyster Bay and
North Hempstead, where a terrace north of the terminal moraine, at an elevation
of about 200 feet, composed of the Manhasset formation, was eaten into on the
north by streams that drained into the sound, whose valleys were later occupied
by the Wisconsin ice sheet.!

Similar topographic features are seen at Vineyard Haven, in the eastern part
of Marthas Vineyard, and in other partly drift-masked valleys on that island, as
well as on the south side of Cape Cod near Chatham. Correlated with these
features in time is a narrow, moraine-covered bench on the north side of Marthas
Vineyard, which is probably a remnant of a terrace that stood at an altitude of
about 150 feet. Remnants of such a surface are recognizable in the southeastern
part of Cape Cod peninsula, beyond the outwash and drift of the Falmouth
moraine, as well as in the highlands of Truro.

Large tracts of glacial and older deposits laid down in the eastern islands
before the Vineyard stage present surfaces about 100 feet above the present sea
level. Such a surface is well displayed at the eastern side of Marthas Vineyard,
where it merges into the ‘‘outwash” plain of the Nantucket substage of the
terminal moraine. Nantucket island appears to have been leveled before or
during the Wisconsin stage, so that now only one point on it attains an altitude
of 100 feet. Southern Cape Cod appears also to have been reduced before Wiscon-
sin time to levels below 100 feet above the present sea level.

After the terraces that now stand at altitudes between 60 and 100 feet were
formed there was an uplift of the land, which was followed by the excavation of
valleys on the north side of the eastern islands of the group. Something like a
common expression is seen in the narrow coves about Hempstead Harbor and
Oyster Bay, on Long Island, and those in Lagoon and Vineyard Haven Harbor
and Chappaquonsett and James Ponds, on Marthas Vineyard. The valleys that
drain into the sounds north of them appear to have been formed just before the
advent of the first Wisconsin ice sheet. On the isostatic hypothesis a depression
of the earth’s crust by a great regional glacier such as covered northeastern North
America should have been compensated in the zone of the ice front by a negative
deleveling ? that increased the effect of the withdrawal of water from the oceans
to form the ice sheets through snowfall.

1 Woodworth, J. B., Pleistocene geology of portions of Nassau County and the Borough of Queens,
N.Y. State Mus. Bull. 48, pp. 634-637, Albany, 1901. With colored geological map, pl. 1.

2 Delevel, to change the level of a body, as of land in relation to sea level, or vice versa. Cf. French
denivellement, for which deleveling is an exact equivalent, defined as a change of level. The terms negative
and positive are used in this connection in the sense proposed by Edouard Suess in “‘La Face de la
Terre,” in accordance with the mode of stating tidal measurements by hydrographers. See note on the
term deleveling in Bull. Mus. Comp. Zodl., geol. ser., 31, p. 100, 1912.

58 CAPE COD GEOLOGY

The geological and biological evidence available in the New England Islands
indicates that the land there was higher than now during the stage of the first
Wisconsin or Nantucket moraine, and that it afterward sank to its present level.
The rise before the end of the Wisconsin stage and the subsequent sinking of the
land are in accordance with glacial theory and the doctrine of isostasy. The tract
submerged during glaciation should be occupied by glacial cover during the re-
treat, when the marine clays of the retreatal stage would be laid down. The
laminated blue clay of the Gardiners stage appear to have been laid down on
such a tract. The marine Sankaty sand, laid down after an early ice invasion, if
correctly understood, bears a similar relation to the margin of the ice sheet, whose
terminal moraine probably lay south of Marthas Vineyard and Nantucket.

The late Pliocene and Pleistocene terraces in Maryland show a progressive
uplift of the continent during the period of their formation. The history of the
terraces on the islands from the late Vineyard stage onward shows that, despite
occasional depression below sea level, uplift has here also prevailed, but the
terraces in Maryland! that stand above the present strand may be of pre-Wis-

consin age.

WISCONSIN STAGE OF GLACIATION
GENERAL RELATIONS

The general position and leading features of the terminal moraines in south-
ern New England have long been known, but recent surveys have considerably
modified the earlier views regarding the western extension of the moraine on
Nantucket and of that on Cape Cod, and have reduced the estimates of the
thickness of the drift laid down by the Wisconsin ice. The estimated thickness
of the Wisconsin drift is here still farther reduced, and certain knob-and-basin
areas that were formerly regarded as Wisconsin moraines of indefinite thick-
ness are here attributed to the deformation of older beds.

The Wisconsin glacial deposits here considered lie in two distinct areas.
The earliest deposit is an ‘‘outer”’ terminal moraine, here named the Nantucket
moraine, seen on Nantucket, Chappaquiddick, Marthas Vineyard, No Mans
Land, and Block Island, and extending westward from Montauk Point, on Long
Island, as the Ronkonkoma moraine of Fuller, nearly to Roslyn, N. Y. There the
low mounds of this moraine are covered and apparently crossed by the second

1Shattuck, G. B., Pliocene and Pleistocene, Maryland Geol. Survey, pp. 66-76, 1906. The author
recognized five terraces, namely, the so-called Lafayette terrace (now regarded as older than the Pleisto-
cene), traceable at elevations above the existing wave-cut terrace of the shore between 260 and 500 feet;
the Sunderland, between 100 and 220 feet; the Wicomico, 45 to 90 feet; the Talbot, 10 to 30 feet.

CAPE COD GEOLOGY 59

or ‘‘inner’’ moraine, the Harbor Hill moraine of Fuller, a belt of frontal deposits
traceable from New York Narrows along the north coast of Long Island to Fishers
Island and along the south coast of Rhode Island, where, at Point Judith, the
moraine, interrupted by the sea, is recognizable by soundings made southwest
of Cuttyhunk, thence northeastward through the Elizabeth Islands to Woods
Hole, and thence along the main arm of Cape Cod peninsula to Orleans. In the
area covered by this report the second moraine is called the Falmouth moraine.

The terms ‘‘outer” and ‘‘inner’’ moraine, formerly and still sometimes ap-
plied to the Nantucket and the Falmouth moraines respectively, are not appro-
priate, for although they occupy these positions from the middle of Long Island
eastward to the east coast, their positions west of Roslyn, on Long Island, are
reversed. This change of alignment of the front may mean that in its second
stage the ice sheet was thinner on the east and thicker on the west than the first
Wisconsin ice sheet, a difference that may have arisen from a shift of the snow
fields inward in the gathering ground. A tilt of the continent toward the south-
west over New England might have had the same effect, but no evidence of such
a movement has been found.

The nature of the retreat of the ice front between the first and the second
substages of the Wisconsin stage is indicated in the Cape Cod region by numer-
ous ice block holes between the Falmouth and the Nantucket moraines. The
formation of these holes was accompanied by stagnation of the ice far within
its front at Nantucket. Blocks of ice several yards thick appear to have re-
mained at some places until after the glacier had readvanced into that field at
the second substage. The interval between the two chief advances of the Wis-
consin glacier in this region was, therefore, not long enough to permit these out-
lying blocks of ice to melt.

Nantucket MoRAINE

The marginal deposits of the Wisconsin ice sheet on Nantucket consist of
an outwash plain built up in front of the ice, a depression back of the head of the
terrace formed by the plain, and, north of this, a belt of low hills and hollows
strewn with boulders and drift. This series of deposits is here called the Nan-
tucket moraine. The knobs and basins of this moraine, which is regarded as sub-
marginal, differ from those of the frontal moraines in other areas, for they are
composed largely of flexed and contorted beds of an older glacial series, whose
eroded surface was crumpled and wrinkled by the forward-moving Wisconsin ice.

The island of Tuckernuck extends the characteristic morainal topography of
Nantucket westward along the line of the ice front. The plain on the south side

60 CAPE COD GEOLOGY

of the island and the corrugated moraine on its north side have been reduced
by marine erosion to narrow coastal belts and the fosse in the middle of the
island forms a large part of its surface.

The ice front, curving northwestward, next appears on the island of Chappa-
quiddick, a southeastern appendage to Marthas Vineyard, where, however, the
distinctions between the plain, the fosse, and the submarginal moraine are
not clearly defined.

On Marthas Vineyard the frontal features of the ice sheet reappear with
typical ice contact slope along the east coast, modified by the overrunning of the
ice upon its frontal outwash plain, a feature which Dr. Wigglesworth has found
along the entire iceward border of the outwash plain. West of Vineyard Haven
the ice either pushed through gaps in the pre-Wisconsin hills or rode over these
hills, here and there depositing heaps of boulders, as in North Tisbury. The
strong ridges on the western side of the island are only in small part due to the
accumulation of frontal or retreatal moraine deposits. The Wisconsin drift is
everywhere a thin veneer mantling older Pleistocene deposits or the Cretaceous
deposits of the upland.

As the base of the ice sheet lay mainly above the level of the outwash plain,
ice contact slopes are rare except at the south ends of gaps in the hills. The sur-
face of the upland in the western part of Marthas Vineyard differs little from that
of the upland many miles back of the terminal moraine except for large boulders
and occasional morainal mounds of doubtful nature, and the ice front appears to
have passed seaward of the western part of the island, lying south of Gay Head,
as well as south of the islands west of Gay Head, nearly to Montauk Point.

From Vineyard Haven eastward to Tom Never’s Head, on Nantucket, the
ice front formed a lobe whose axis of maximum flowage appears to have passed
southeastward, presumably along the line of the glacial striae on Cape Ann, where
the stronger lines show a movement S. 10° E. From Tom Never’s Head the ice
front turned southeastward to form another more marked lobe over Nantucket
shoals. The axis of this lobe was probably determined by the South Channel, a
deep depression separating Nantucket shoals from George’s Banks. From
Vineyard Haven westward to Block Island a broad lobe of the ice sheet pushed
out beyond the present site of the islands, probably with its axis of maximum flow
along the low ground of Narragansett Bay. The topography of the insular tracts
would have tended to introduce irregularities in the ice front at its maximum
advance, so that the ice probably threw out small lobes in the depressions between
the islands, such as that occupied by Menemsha Pond, which acted somewhat

CAPE COD GEOLOGY 61

like that broader and deeper opening between Gay Head and Block Island. A
curve drawn from the boulder shoal southwest of No Mans Land to Montauk,
where the frontal moraine reappears, indicates that the axis may have been
prolonged as much as five or ten miles south of the south coast of Block Island
in the area between that island and No Mans Land.

A striking feature of the morainal topography of the outer islands is their
freedom from alteration by wave action above the present sea level. Except for
long-continued atmospheric weathering, which is particularly noticeable in some
of the granitic boulders, the surface has been but little altered, even by fresh-water
streams. A strong contrast with this retention of the forms impressed upon the
surface by the glacier and the streams that flowed over the outwash plain is seen
in the present destructive work of the sea in cutting away and trimming the edges
of the land.

FatmoutH Morainr

The second Wisconsin terminal or frontal moraine is best developed in the
town of Falmouth. It skirts the shores of Buzzard’s Bay and the south side of
the Cape Cod Canal, where it forms a huge outwash fan of sand and minor beds
of gravel, sprinkled with thousands of granitic boulders. Southwest and east of
the apex of the frontal fan, which coincides in position with the interlobate angle
of the ice sheet, the mounds of the frontal moraine rise above the level of the
stratified drift and form rather typical morainal topography, as at Woods Hole
and on the Elizabeth Islands; but farther east, along the frontal of the Cape Cod
Bay lobe, the beds of outwashed sand continue to form a large part of the frontal
deposits. They were more or less overrun by the ice and are pitted with large
holes, which were occupied by blocks of ice left over from the Nantucket substage.

The deposits of stratified material in this moraine dwindle eastward, toward
Orleans, whence the ice front appears to have turned southeastward to form a
lobe whose axis, like that in the earlier Nantucket substage, lay along the South
Channel. A weak interlobate axis is thus traceable from Tom Never’s Head, on
Nantucket, through the Orleans-Nauset section of Cape Cod, north of which the
forearm of the cape lies in the interlobate axis between the South Channel or
offshore lobe and the Cape Cod Bay lobe.

In the interlobate tract in the northern part of Falmouth the features of the
Nantucket substage at Vineyard Haven are repeated and continued northward

over the Plymouth quadrangle by the great mass of gravel and sand in the
Plymouth woods, in which Manomet Hill is prominent.
A remarkable fact in the history of the three lobes in this part of the glaciated

62 CAPE COD GEOLOGY

area in the second or Falmouth substage of the Wisconsin ice is the earlier
melting of the ice on the west than on the east. The streams of water that built
the high sand plains between ice block holes in the western part of the interlobate
moraine, about Plymouth, poured southwestward from the lobe of ice lying over
Cape Cod Bay, and, as Grabau! pointed out, the outwash plain at Eastham,
on the arm of Cape Cod in that interlobate axis, was also traversed by streams
running toward Cape Cod Bay, coming from ice lying east of the site of Cape
Cod. It would thus appear that the Wisconsin ice sheet thinned and melted
away over the present mainland before it melted over the Bay of Maine in the
latitude of Cape Cod.

The moraines of this substage form the surface features of the Elizabeth
Islands, but apparently not the mass of drift that stands above sea level in those
islands. On Naushon and other islands large boulders are grouped in lines showing
the faltering retreat of the ice front across these broad, low Pleistocene ridges.
Almost everywhere in the islands a bed of yellow sand underlies the surface
moraines. Conjectures as to its stratigraphic position are given in the text deal-
ing with these islands (Pt. 3, Chap. 2). Back of the main Falmouth moraine there
are numerous retreatal moraines, only a few of which lie within the area covered
by this report.

INTERLOBATE MORAINES

Enormous piles of gravelly and sandy drift lie on the west shore of Cape Cod
Bay, in the Plymouth woods, extending as far north as Kingston, Mass. These
deposits are here called the Plymouth interlobate moraine. This moraine is a rude
ridge of rather bouldery drift or till, sections of which disclose older Pleistocene
deposits, including a blue clay of either Montauk or Gardiners age. Most of its
sections in the interior show stratified beds of gravel. The highest mass of this
moraine forms Manomet Hill, which has an elevation of more than 380 feet above
sea level. A cut made in the northern part of the crest of this hill when the roads
of the state were being reduced to standard grades showed a coating of gravelly
till, some 12 feet thick, overlying waterlaid gravel, confirming the opinion that
most of the glacial drift in this moraine is stratified. This eastern, more decidedly
morainal part of the deposit is separated from the area of plains and ice block
holes on the west by a line of lakes that occupy ice block holes. These lakes,
which are the largest in the district here considered, include Billingston Sea,
famous in the annals of the Pilgrim Fathers, one of whom is commemorated

u, A. W., The sand plains of Truro, Wellfleet, and Eastham, aoe new ser., 5, pp. 334-335,
ees Be ‘1897. For discussion of this paper, see same volume, p.

CAPE COD GEOLOGY 63

in its name. Great South Pond and Long and Halfway ponds and, farther south,
Great Herring Pond, have their longer axes in the line along which the group ex-
tends, about N. 42 W. Running out southwestward from each of the larger ponds
in this line, there are small depressions, the deeper parts of which are occupied
by ponds or drainage lines, such as that of Agawam River, draining Halfway
Pond. This complex group of sand hills, sloping plains, and ice block holes is the
most singular and at the same time the most regular in its repetition of features
due to the deposition of gravel and sand between and around blocks of ice that
lay in these depressions, the deeper of which contain bodies of standing water.

The area of a certain group of these lakes appears to have been occupied by
the eastern margin of the Buzzard’s Bay lobe of the ice sheet. From this margin
sloping plains of outwash were laid down by streams flowing southwestward,
toward Buzzard’s Bay. These plains, which along their eastern margin rise to
elevations of 200 and 250 feet, have the appearance of large fans built between
ravines that have disappeared.

That streams flowed from the ice front at this or a later stage across the
lower surfaces on the southwest is indicated by large drainage channels now
occupied by small streams, such as Agawam River. Great Herring Pond drains
into a channel that runs across the tract traversed by the Cape Cod Canal. The
central and western parts of this channel are occupied by Manomet River,
which has a course parallel to that of the smaller chains of lakes in the Plymouth
quadrangle and appears to be allied to them in origin, its bed having apparently
been occupied by a remnant of ice lying at the head of the Falmouth outwash fan.
In this respect the depression is analogous to the fosse on Nantucket, but it is
notably deeper and more complex in its relations to the neighboring glacial
features. This depression appears to have been followed by streams that flowed
from the Cape Cod Bay lobe or from marginal lakes in that lobate region west-
ward into Buzzard’s Bay during the retreat of the ice from the Falmouth moraine.

From the Nauset inlet northward to Pilgrim Heights, Cape Cod is com-
posed almost entirely of plains of stratified gravel, sand, and clay, though here
and there boulders are scattered on the highest surfaces in Truro or appear in
certain coastal areas in beds of gravel. These plains form three rather distinct
areas. The southernmost is the Eastham plain, already described as having been
built by water flowing westward from an ice mass lying outside the present area
of the Cape. It is the most perfect and most typical of the plains on the Cape
and is among the latest glacial features there, being probably somewhat more
recent than the fans and plains in the Plymouth interlobate district and on the

Cape farther southwest.

64 CAPE COD GEOLOGY

North of the Eastham plain, extending through Wellfleet and Truro, there
is a plain that is deeply dissected by channels locally known as “ hollows,” the
bottoms of some of which lie below the present sea level. These hollows appear
to have been similar in origin to the channel of Agawam River, in the Plymouth
region. If they were occupied by remnants of the ice sheet they appear to have
been modified by running water from an ice mass on the east, signs of which are
found in kettles and boulders from Highland Light southward, as well as in ice
block holes now occupied by lakes.

At Highland Light the blue clay of the so-called clay pounds, together with
an overlying bed of fine sand and an underlying bed of coarse gravel, with an
occasional erratic, reproduce in vertical section the essential features of the
Jameco gravel, the Gardiners clay, and the Jacob sand in the island on the south-
west and have been assumed by Fuller to be the same beds.

North and west of the Truro high plain, at about the level of the Eastham
plain, there is a lower plain, which appears to have been cut back into the high
plain.

The tip of the Cape at Provincetown is formed chiefly by marine deposits
and sand dunes.. What appears to be an extension of the glacial deposits of
Cape Cod, laid down before the north end of the peninsula was cut back by the
sea, was seen by Dr. Vaughan in gravel exposed at low tide on the outer beach,
near Wood’s End.

Cape Cod Bay is in origin analogous to the New England sounds; it is a
depression back of a well-developed frontal moraine, and, like the sounds, it
appears to have been scoured and deepened by the action of ice; but drainage
lines like those drawn by Shaler ! in his report on Cape Cod probably had a share
in the erosion of the depression in the Vineyard interval prior to the first advance
of the Wisconsin ice.

CERTAIN GLACIAL FEATURES OF THE DISTRICT

Certain features of the glacial history and the glacial deposits of Cape Cod
and the New England Islands may here be considered, namely:

1. The deformation and dislocation of beds by glacial thrust

2. The correlation of the glacial deposits of New England with those of the

Mississippi Valley
3. The classification of glacial deposits
4. The larger glacial erratics
5. Postglacial changes

1 Shaler, N. S., Geology of the Cape Cod district, Eighteenth Ann. Rept. U. 8. Geol. Survey, pt. 2,
pp. 407-593 (see p. 516, fig. 86), 1898.

CAPE COD GEOLOGY 65

DEFORMATION AND DISLOCATION OF BEDS BY GLACIAL THRUST
The folding and overthrusting seen in the Cretaceous, Tertiary, and older
Pleistocene beds, so well shown at Gay Head, on Marthas Vineyard, is char-
acteristic of the beds in all the New England Islands, from Long Island to Nan-
tucket. The equivalent beds of the coastal plain in New Jersey and farther
south on the Atlantic border exhibit no such widespread distortion. Small dis-
placements and distortion of soft beds are seen at places along the ‘‘fall line,”

Fig. 3.— Sketch map showing approximately the area of glacial dislocation off the south coast of New England.
The heavy dotted line shows the southernmost limit of the Wisconsin ice front.

at the contact of the beds of the coastal plain with the crystalline rocks of the
Piedmont plateau, as at Richmond, Virginia, where the Miocene is faulted down
against the granite. Folding is seen at some places in the coastal plain, as in the
eroded anticline traversed by the Tombigbee River, in Alabama, and dislocation
| is found at Muscle Shoals, on the Tennessee River. None of these disturbances
of the beds on the coastal plain south of the terminal moraine on Staten Island,
however, have the breadth of exposure and the peculiar association with glacial
deposits that are seen in the New England Islands.

66 CAPE COD GEOLOGY

The earlier explanations of the commingling of contorted drift with older
soft beds, including the conception of icebergs grounding on a shallow sea floor,
of violent disruption of the earth’s crust, and of mountain building, have given
way to the conception that an overriding ice sheet ploughed and pushed the soft
beds over a coastal plain. In 1886 Merrill! expressed the cpinion that the dis-
locations on Long Island were due to the advance of the Pleistocene ice sheet over
the soft deposits of the coastal plain. Upham 2 somewhat later took the same view
regarding the distortion of the beds at Sankaty Head, on Nantucket, and at Gay
Head, on Marthas Vineyard. In 1894 Hollick * in considering the structure of
beds studied by him on Staten Island, Long Island, and Gardiner’s Island in
connection with the facts reported by Shaler and others on Marthas Vineyard,
compared the theory of mountain building as applied to this structure with that
of glacial thrust and concluded, from the coincidence of the terminal moraine
with the zone of dislocation, that glacial action alone was the cause of the folding
and faulting in the beds. He also noted at Cold Springs, on the north shore of
Long Island, that the lower Cretaceous beds there exposed were undisturbed,
and he predicted that if excavations were made elsewhere below the limit of dis-
turbance of the upper beds by the ice sheet similar undisturbed strata would be
found.

In 1906 Veatch * showed by the records of well borings made along the north
shore of Long Island that beneath the crumpled and dislocated Cretaceous beds
that lie immediately under the glacial drift there are undisturbed basal Cretaceous
beds that dip seaward.

Two facts appeared to lend support to the idea that these disturbances were
due to mountain building forces, which were suggested by Shaler as the cause of
the dislocations on Marthas Vineyard. One of these facts was the great extent
of the area of the disturbed beds in the New England Islands. The disturbed
area between New York Narrows and Sankaty Head amounts to at least 2,200
square miles, and as that area may be 20 miles wide it may have once included
more than 4,000 square miles of the sea floor and the islands, exclusive of the
vast shoals east of Nantucket and Cape Cod. If the disturbances were practically
simultaneous throughout this great area, glacial thrust appeared to be an inade-

1 Merrill, = a H., es ee geology of Long Island, Ann. New York Acad. Sci., 8, pp. 258-259, 1886.

Also On f the ice sheet, Proc. Am. Assoc. Adv. Sci., 35, pp. 298 229, 1886.
2 soe Warren, Marine shells and oe of shells in till near Boston, Am. Jour. Sci., 37,
ser., p. 270, |

3 Hollick, se Dislocations of certain portions of the Atlantic coastal plain strata and their
probable cause, Trans. N. Y. Acad. Sci., 14, pp. 8-20, 1894.

‘Veatch, A. C., Underground water resources of Long Island, U. 8. Geol. Survey Prof. Paper 44,
pp. 16-19, 1906.

CAPE COD GEOLOGY 67

quate cause of them. Merrill seems to have held that the folding took place
during the last ice stage, the Wisconsin stage. Shaler and his assistants, in their
work on Marthas Vineyard, found that the disturbances at Gay Head long
antedated the last or Wisconsin stage of glaciation; and Woodworth reached the
same conclusion in regard to the date of the disturbance on Long Island,! where
dislocations appear to have occurred at different times before the Wisconsin stage.
The latest surveys confirm the theory of glacial thrust, showing a succession of
dislocations and glacial deposits so correlated as to indicate that at each ice in-
vasion there was more or less crowding, crumpling, folding, and disruption of the
beds.

These dislocated deposits are comparable with true moraines, but they are
genetically and lithologically distinct from them, for they were moved as a mass
and not as detached fragments, such as boulders. The displacement of the beds
appears to be the result of crumpling in a zone beneath an overthrust mass of
ice that was pushed forward under competent gravitational pressure from the
ice sheet. The effect of the ice thrust is wholly structural; it does not involve a
change in the nature of the deposits or in their classification. The disturbed beds
are therefore not to be grouped with moraines composed of rock débris that has
been eroded, transported, and deposited by glaciers or by streams of water flowing
within or out of glaciers. They form the ‘‘contorted drift” of English writers,
the ‘‘schichtengestérung” of German geologists. They were laid down beneath
a moving ice sheet; they are subglacial deposits, and their structure in the New
England Islands is rather typically that of isoclines overturned in the direction
of the movement of the ice, with dip toward the ice mass.

The surface of the contorted drift as it was left by the melting ice sheets
is not well shown in the older greater typical masses in the New England Islands,
such as those at Gay Head and Clay Head, but it is suggested by the present
surface of areas covered by the last ice sheet, such as that on Block Island and No
Mans Land. In these two islands the surface above sea level has not been at all
changed, either by marine action or by the work of streams, and the form of the
subglacial surface is there clearly shown. This surface is of the type known in the
United States as ‘‘morainal,”’ that is, it consists at some places of groups of
mounds and hollows, some of them circular in horizontal section, and, at others,
of long ridges or troughs, more or less sinuous in outline. This surface differs,
however, from that of a true frontal or terminal moraine in that it is not primarily

1 Woodworth, J. B., Pleistocene geology of portions of Nassau County and the Borough of Queens,
N. Y. State Mus. Bull. 48, p. 632, 1901. f

68 CAPE COD GEOLOGY

a product of glacial deposition, but a surface imposed upon a series of contorted
and dislocated beds of diverse age and origin — the older glacial drift and the
Cretaceous clay — by the overriding action of glacier ice, and here and there by
the thickening of a veneer of later rubbly drift.

Within small areas the ridges and hollows of this pseudo-morainal contorted
drift show a certain parallelism of direction, which is curvilinear in places, as in
the so-called submarginal moraine on Nantucket. A sudden change in the direc-
tion of the axis of such a group of deposits may occur on opposite sides of a more
or less arbitrary line, such as a trench or crease, as if it were due to the arrange-
ment of ridges and gigantic puckers beneath part of the ice moving diversely
toward the general front.

Owing to the lobular form of the ice front in areas of the New England
Islands, the movement of the ice was not everywhere directly southward but
swerved to the southwest and to the southeast on opposite versants of a lobe.
For this reason, probably, the overturning on No Mans Land, on the east side
of the axis of the Narragansett Bay ice lobe, was to the southeast. The opposite
effects are seen on Block Island, where the ice pressed southwestward or west-
ward, producing overthrust in those directions, with resultant troughs and ridges.

TENTATIVE CORRELATION OF THE GLACIAL DEPOSITS
AND INTERGLACIAL STAGES

The correlation of the glacial deposits of New England with those of the
Mississippi Valley indicated in the following table is tentative only. In the
column headed ‘‘Deposit” the nature of certain deposits that, theoretically,
should occur in the areas indicated, but that have not been found there, are
placed in brackets.

There is little doubt that the terminal moraines and other later drift deposits
in New England may be correlated with the deposits of the Wisconsin stage in
the interior, and that the Manhasset deposits are the eastern representative of
the Ilinoian drift of the Mississippi Valley. The Illinoian drift is a relatively thick
and widespread sheet, deposited by a Labradorean glacier long after the Kansan
drift had been deeply weathered and extensively eroded. The Illinoian deposits

were in turn greatly weathered and much eroded before either the Iowan or the
Wisconsin stage of glaciation. The Iowan drift, although it is older than the
Wisconsin, is probably considerably younger than the Illinoian. It is a relatively
thin drift of less extent, deposited by the Keewatin ice sheet. It is not certainly

Correlation of the glacial deposits and interglacial stages in the Mississippi Valley with those
2 Cape Cod and the New England Islands

Stage Substage Deposit Location and character
In Mississippi | In New
Valley England
[Clay] Offshore, under the sea?
San In outwash
Gravel In outwash plains
Falmouth ill In frontal moraine
[Gravel] Laid down in pes of the ice;
[Sand] covered or orked over in
Wisconsin Wisconsin [Clay] Falmouth ie
(glacial) (glacial) [Clay] a nee thes
Sand Grav and in soe plains
Gravel In Het nie os ine
Nantucket [Till]
feae Laid down in advance of the ice;
Sand] covered or worked over in ground
Iclay| moraine
n Old valleys on Marthas Vineyard
(interglacial) and Block Island
es Widespread erosion on Nantucket
n Vineyard Eros nd Cape Cod
(glacial) (interglacial) | “70507
ngamon
Gnterglacial)
(oe Offshore, under the sea?
Hompotead Sand Sparingly developed
Illinois Manhasset Gravel Strongly developed
(glacial) (glacial)
Montauk Till Boulder clay
Herod Gravel Well developed
Jacob Well developed
(transitional) Sand
eee ee oes
interglacia : Stratified glacial blue clay in the
ak iad Marine | Clay islands and possibly at Highland
nterglacia invasion Light, on Cape
(Unconform- [Sand] Absent or in iat ee
ity [Gravel] Locally in
Moshup Till Boulder bed Gide clay
K a ee
ae ee al) Lae facies of Jameco
Lo
ie In lenses on Cape Cod
cl 1 Weathered and iron cemented
ay we bed; supposed base of
Aftoni re Dee in Gay Head section
Gidea pieialy See Erosion lay Head section on Block
Se —— uke | folding at Gay H
M tt ey y Head by glacial ria: also
cae 1) Gr val o on Nantucket. Depo sition of
ee) Till? Hey blue clay (till) in at
et y Head, overlain by gra:
Interval of Gravel The Weyquosque glacial gravel and
glacial reces- Sand sand are regarde -
ion a [Clay] lent of the Sankaty fossiliferous
marine in- Sand marine sand on Nantucket and
Nebraskan vasio: Gravel under Cape
laci :
aes Till Dukes boulder bed (local)
First glacial [Gravel] ee laid down prior to deposi-
[Sand] mn of boulder bed were removed
a [Clay] S ee changes
Nonglacial a d Aquinnah conglomerate

Basement of Cretaceous and Miocene strata.

70 CAPE COD GEOLOGY

known that the Labradorean ice sheet advanced at the Iowan stage, for Iowan
drift has not been clearly identified east of the Mississippi River.

Three advances of the ice prior to the deposition of the Montauk till and the
Gardiners clay appear to have occurred. One of these, indicated by the Moshup
till, probably represents Kansan glaciation. The Moshup till and the Dukes
boulder bed, which are exposed at but few places and have complicated structural
relations, are regarded as representing two advances of the Jerseyan ice sheet,
separated by an interval during which the Weyquosque gravel and sand were
laid down.

The relations between the Jameco formation and the beds on which it rests
are not well shown either on Block Island or Marthas Vineyard. Many of the
beds at Gay Head cliffs and at Clay Head on Block Island are local or lenticular
and their stratigraphic order is uncertain.

A comparison of the deposits of till in the New England Islands is hampered
by differences in the state of their preservation. The deposits of the Wisconsin
drift remain above sea level essentially as they were left on the retreat of the ice,
except for certain weathering. Nowhere do they show modification by marine
action at places above the present reach of storm waves. The great bulk of the
material in the so-called frontal moraines is water-laid gravel and sand; the
boulders, most of which are superficial, are only here and there huddled together
along lines comparable with a frontal moraine. The average thickness of the
Wisconsin till on Marthas Vineyard, Nantucket, and Block Island is probably
not more than 3 feet. Over a large part of the surface the Wisconsin drift is repre-
sented only by scattered boulders, which rest in a rubbly surface layer. The
thickness of the beds of water-laid gravel in the outwash plains on Nantucket is
measurable approximately by their elevation above sea level. Their mean thick-
ness in the section not yet cut away by the sea is about 25 feet. The mean thick-
ness of the beds of gravel and sand in the plain on Marthas Vineyard is greater,
though it is probably less than 50 feet, but the possible presence of pre-Wisconsin
beds above sea level in that tract and the absence of borings makes any estimate
uncertain.

The Manhasset series of beds of gravel and gravelly sand and the intercal-
ated Montauk till form the thickest glacial deposit on the islands. The Montauk
till, which is seen in continuous exposures in the cliffs, is probably thicker than
any comparable bed of the Wisconsin till, which is an insignificant rubbly veneer,
not thick enough to bury the boulders that form its grosser members. Moreover,
the Montauk till is a typical boulder clay, whereas on these islands the Wisconsin

j

CAPE COD GEOLOGY 11

till is usually an aggregate of boulders, gravel, and sand relatively free from a
clay matrix. The gravel below the Montauk till (the Herod gravel member) and
that above it (the Hempstead gravel member) appear to have been laid down
during one glacial advance, the Manhasset.

What appears to be a boulder clay till bed at or near the base of the Gardi-
ners clay near Nashaquitsa cliffs is in many respects like the Montauk till, but
it is less than 10 feet thick. Unlike the lowest boulder beds, which are invariably
water-washed deposits, this bed looks relatively fresh, as does also the Jameco
gravel, which lies at nearly the same horizon or just below it. Judged by its con-
tent of blue clay and its fresh appearance, as well as its freedom from cementation
by secondary alteration and deposition of salts of iron and lime, this bed of till
lies above the oldest Pleistocene deposits, with whose physical aspects and wear
by water it has nothing in common except its glacial origin. Its exemption from
weathering and alteration is probably due to the fact that it was not exposed to
leaching and oxidation above ground water or sea level so long as the Jerseyan and
Kansan tills. The older beds of boulders, gravel, and drab sand, some of them
containing water-worn Miocene fossils, consist of glacial material worked over
by water and are comparable with the deposits now being laid down along our
coast rather than with the glacial material on the land that has not been worked
over by waves and currents. The distinction is as sharp and as important as that
between the stratified and the unstratified drift of the last glaciation.

The lowest and oldest beds of boulders on Block Island and Marthas Vine-
yard contain no true boulder clay. The boulders are either embedded in strati-
fied gravel or occur in water-washed and rudely bedded masses, having evidently
been reassorted under an ice sheet by the action of waves and currents or by
streams. Only at one point, in an exposure at Gay Head cliffs, have I found
glacial striae on a fragment in these deposits. The appearance of these huddles
of boulders and rounded gravel suggests that they were included in a sheet of
morainal drift that was long exposed to the action of waves and currents on
shores and shoals. In fact, the boulders are as well worn and clean as those that
have been long exposed to wave action on existing shores. This characteristic
has a diagnostic value in excluding from the earliest glacial origin any drift that
proves to be a typical boulder clay. Any such clay is undoubtedly more recent
than the Dukes boulder bed. It may lie above that horizon, in the Moshup stony
blue clay below the stoneless blue clays of the Gardiners formation, or it may
belong still higher up, at the Montauk horizon. No typical boulder clay of the
bluish unoxidized type has been found in the Wisconsin moraines on these islands.

CAPE COD GEOLOGY

CLASSIFICATION OF THE GLACIAL DEPOSITS

The chief object of a classification of the moraines of Pleistocene glaciers is

to assist in recognizing their mode of origin, whether through the agency of ice

or water, and, by an imaginative restoration of the ice sheet or its melting rem-

nants, to determine the position of particular deposits relative to the ice. A

classification proposed by me in 1890 is here presented, expanded to include the

subvarieties of moraine not specifically named in my original paper.

In this

classification, mode of origin is the prime factor. Deposition either within a field

occupied by a glacier or just beyond its limits is a secondary factor. Position with

reference to the ice, whether on its surface, within it, under it or at its side, takes

a tertiary place in the classification.

Classification of glacial deposits (moraines)

ae medial, marginal moraine of cli
débris (unstriated débris). Rock tal ae

Superglacial Ablation deposits brought up from within
the ice
Crevasse ee a
Wind-blown
Ice-laid Intraglacial Dirt bands; crevasse (vein) moraine.
moraine i Englacial Boulders; clay pockets. Drift worked in
from above or up from below
Ground a till plai ains; submarginal
: moraines; drumlins; cr. ag, tails. Grove d
Subglacial blocks. Dislocated. terranes; €.g.,
Head cliffs
Ice bound; in con- | Frontal, terminal, dump moraines at edge
tact with ice or of ice, resting on Gaalcnied terrane;
: once supported also lobate and interlobate moraines.
on goes Extraglacial by it Boulder belts
orale Ice free; beyond | Drop moraine on slopes. Bergdrift in seas
w the and lakes. Boulders rolled beyond
edge of the ice- ice fron
sheet,
Stream gravel and sand
Superglacial Some kames ? lowered to base
ome eskers
noe
gravel, sand and F Some kames and eskers doubtfully of this
lay Englacial origin. “Englacial drift of Upham
Water-laid : Eskers; kames (in part); various stream
aad —— gravels. Boulders (in part)
drift ; :
= Outwash plains; sand plains; esker fans;
Ice bound kames; pitted plains. Lateral terraces;
Extraglacial kame terraces
gravel, sand and
slay Some sand plains; ae trains silt plains;
Ice free proglacial clays. osits reworked by

rivers, waves and ee

The ice contact is typically shown by the sloping sides of eskers (long ridges

of water-laid drift), possibly by the steep sides of kames (mounds of gravel and

CAPE COD GEOLOGY 73

sand), and by the edges of sand plains and deltas that were built up against the
front of the ice or in open spaces within it while it was melting. The same ice
contact slope is seen in the steep banks of ice block holes and of some of the
larger kettle holes.

Some of the terms now used in America to designate glacial deposits are
different from those used in Great Britain. In Scotland the term kame is applied
to what is here called an esker. In Ireland the term esker is used for both a kame
and an esker, as those terms are now used in America. Kame is here used to sig-
nify a mound in stratified drift. In New England these forms are at many places
strongly developed along the iceward margin of an outwash plain in such a way as
to indicate the ice contact, which is usually on the northern or iceward margin of
a tract of kames. In these places the outwash material was evidently built upon
wedge-shaped fronts of the ice sheet (as seen in vertical section), so that when
the ice melted the material was let down to form mounds and hollows. Farther
out upon the outwash plain the material was more regularly distributed, its
surface sloping in the direction of the drainage, except where there were outlying
remnants of ice of an earlier stage.

At some places the ridges known as eskers are subdivided so as to form a
series of ridges enclosing rounded or oval hollows. The peaks and depressions in
these ridges give them the aspect of inosculating kames. On such a surface the
esker and the kame merge into one another and the distinction between them is
lost. The term kame terrace is used for a terrace-like deposit made between the
side of a valley and a tongue of ice lying in the valley. On melting out, the ice let
the deposit down, in the manner of a kame, at the ice contact border of an out-
wash plain. Certain tracts of submarginal moraine appear to be masses of ill-
assorted gravel and sand having a surface of mounds and hollows; hence the
name kame moraine. But if moraine is used as it is in Europe the second part
of this term is redundant, for a kame is a form of moraine. If kame is to be used
in a generic sense, it should have prefixed to it terms denoting the special form
of glacial accumulation it signifies.

The term proglacial has been applied mainly to beds of glacial clay laid down
in bodies of water in front of an ice sheet, but it is appropriately used also to
designate any deposit laid down by ice or water in front of an ice sheet. The word
is correlated with superglacial, englacial, and subglacial in denoting a position in
relation to the ice sheet.

There is perhaps some impropriety in grouping dislocated and overthrust
beds of preglacial age with moraines. Although these beds have been moved by

74 CAPE COD GEOLOGY

glacial action into their present positions they may not be detached from the
terrane of which they are a part, and they thus differ from boulders and from
those large shoved blocks of strata that were surrounded and underlain by
glacial drift.

Most of the glacial deposits considered in this report fall into two great
classes — ice-laid and water-laid drift. No drumlins or eskers are described,
although certain narrow and relatively short ridges of gravel and sand that rise
between two pits, kettle holes, or ice block holes in the plains and kame tracts,
may be likened to eskers. These interkettle and interlake ridges are, however,
quite distinct from those serpentine ridges in central and northern New England
which clearly represent the aggraded courses of streams flowing toward the
ice front under the ice or between walls of ice.

The classification above presented takes account only of forms produced by
the action of ice and water during the glacial period. The drift deposits display
depressions, unfilled areas, and eroded tracts or channels which may be classified.
These fall under the following headings:

1. Depressions due to the melting out of ice

n till, giving rise to pits and kettle holes
b. In sand plains, giving rise to kettle holes and ice block holes.

2. Channels eroded by water escaping from the ice or flowing within the ice
ce. Stream channels cut in drumlins and ground moraine or across a frontal moraine
d. Stream channels cut across an outwash plain (creases)

The numerous lakelets and ponds in the Plymouth woods and on Cape Cod
are depressions formed either in the frontal moraine or in outwash plains. The
outwash plains on Nantucket and Marthas Vineyard bear channels cut by
streams flowing in open air from the ice front.

THE LARGER GLACIAL ERRATICS OF THE DISTRICT

Cape Cod and the adjacent islands are noted for their glacial boulders. Most
of these boulders are on the uplands, in areas displaying the knob-and-basin top-
ography of unassorted drift, commonly spoken of as morainal topography and
interpreted as due to the direct deposition of material from the ice. This in-
terpretation is sustained by the absence of boulders from the sand plains, outwash
plains, or fields of water-laid drift that lay outside of the ice sheet. Here and
there, as on Cape Cod and Marthas Vineyard, boulders as much as 8 feet in diam-
eter may be seen on the plains near broken ground having a morainal topography,
in places where the ice advanced upon gravel already washed out from the

|

CAPE COD GEOLOGY 75

glacier, or where material was carried out on the plain from the ice front by
glacial streams.

Boulders are particularly abundant in the morainal hills on Cape Cod from
the vicinity of Orleans westward to Buzzard’s Bay and thence southwestward to
Woods Hole, on the iceward border of the mass of sand that forms the highest
part of the land. This belt of country lies along the ice contact, where boulders
dumped from the melting ice front would naturally be found. A similar line of
bouldery moraine is traceable over the Elizabeth Islands.

On Nantucket and Marthas Vineyard the surface mapped as till or frontal
moraine was originally much more bouldery than it is now, for many boulders
have been broken up to make foundations for houses. As a result of this use of
the only available supply of large blocks of stone on Nantucket, very few boulders
remain there. In the settled parts of Cape Cod and of the islands the smaller
boulders and blocks of rock have been gathered into stone fences; and in some
areas, particularly on Block Island, the smaller stones that were not suitable for
building fences have been thrown into the numerous pits that indent the surface.
Notwithstanding these uses of the blocks, boulders still encumber the surface
of large tracts in a way to impede or prevent the use of modern methods of culti-
vating the soil and reaping grain.

None of those high heaps of boulders which many existing glaciers accumu-
late in their frontal moraines are found in the district, or indeed anywhere along
the Wisconsin frontal moraines in southern New England. The nearest approach
to such a pile of boulders along the ice front is seen near the middle of Marthas
Vineyard, in North Tisbury, on the south side of the northern ridge of the island,
on land once owned by Professor Shaler. Certain tracts in the ice contact at the
head of the Falmouth outwash plain in and about Bournedale, on the south side
of the Cape Cod Canal, display a marked huddling of blocks, but no distinct
pile of boulders along the ice front is seen in the Cape Cod morainal tract.

On Marthas Vineyard, No Mans Land, and Block Island, where boulder
beds of older Pleistocene age crop out in the cliffs and appear to be truncated at
the surface of the ground by erosion, erratics brought to the islands at different
times may be commingled on the present surface. On the beaches at the bases
of cliffs in which older beds of boulders lie beneath a top sheet of Wisconsin
drift, it is impossible to distinguish boulders from till. It is, therefore, not possible
to determine the direction of the motion of the ice by studying the boulders in
connection with their parent ledges on the mainland, for these erratics may have
been carried some distance forward during one advance of the ice and finally laid

down after a short journey by ice moving in a different direction.

76 CAPE COD GEOLOGY

Some of the boulders in the terminal moraine on the islands and in the
moraine on Cape Cod are more than 25 feet long, and one boulder measured
34 feet. The largest boulders on Marthas Vineyard and Naushon measure 29
feet. Enos Rock, in the Nauset kame fields, on Cape Cod, measures 34 feet.

Many large erratics have broken up along joint planes into a mass of smaller
blocks. Here and there an erratic has been split along a single nearly central
joint and the divided halves have moved apart, leaving a narrow passage between,
giving rise to the name ‘‘split rock.’’ Such split rocks are seen on the beaches
within reach of the tide, where the difference in strain at the top and the bottom
of the boulder may cause the fracture. Some large jointed rocks have been broken
into fragments by frost and by the growth of trees. Such rocks are common on
Naushon, and a big boulder described by Hitchcock in Brewster is of this sort.

Pairs of large boulders that stand in the sounds, particularly in navigable
water, have been called by such names as ‘‘Rose and Crown,” ‘‘Bishop and
Clarks” (clerks, in modern spelling), ‘‘Hen and Chickens,” all well-known danger

points in Vineyard and Nantucket sounds.

POST-GLACIAL CHANGES

The postglacial changes in this district consist of slight weathering of the
surface rocks, the formation of soils, the growth of swamps and marshes, insig-
nificant erosion by small streams, notable work done by the wind in shifting sand,
and the irresistible and rapid erosion of the coast by the sea. Among the effects
produced by these agencies the dunes and lag gravel tracts formed by the wind
and the swamps and marshes formed by the growth of plants are the most con-
spicuous. The soils of the district are proverbially poor, owing to the wide extent
of sand in the level tracts that are suitable for agriculture. Certain areas on the
upland of Marthas Vineyard and Block Island that are underlain by clay have
better soils.

SWAMPS AND MARSHES

The swamps on the islands of the district are small. Most of them border
or occupy small lakelets in the glacial drift, the waters of which are in different
stages of displacement by the growth of water-loving plants. Hundreds of
small swamps that lay in depressions on the sandy plains of Cape Cod and on
Marthas Vineyard have been converted into cranberry bogs, and some depres-
sions that contained no natural vegetation have been by means of barriers to
the drainage artificially turned into similar bogs. Cranberry bogs are particu-

i ea ha ialial

CAPE COD GEOLOGY 77

larly numerous on the south side of Cape Cod between Falmouth and the
east coast.

There are marine marshes on the west side of the upper arm of Cape Cod
and elsewhere behind barrier beaches wherever shallow water gives opportunity
for the growth of vegetation. Marshes of this type occur between Plymouth
Heights and the Peaked Hill bar beach, as well as along the south shore of Cape
Cod Bay, near Barnstable and Sandwich. The largest tracts of marsh are those
of the Pamet River (partly converted into freshwater swamp by a dike at Truro
village) and the marshes behind the beach between Nauset Harbor and the
Nauset coast guard station in Eastham.

Except where they are cut back by the sea or covered by beaches of shingle
the marshes are slowly increasing in area, and since 1620 have closed up several
small shallow embayments, particularly where the inwash of silt by the tide has
helped the growth of plants. The inner part of Wellfleet Harbor (see Plate 2) was
once a small port in which vessels rode at anchor.

From point to point, along the coast, a fresh-water swamp deposit containing
logs may be seen at or just below sea level, where it has been exposed by the cut-
ting away of the drift around a kettle hole in which the swamp was formed, its
original position protecting it from the intrusion of salt water. Such a deposit
was exposed on the beach in front of the Nauset coast guard station in 1916.
Deposits formed long ago in salt water marshes are seen at many places along
the beach between high and low tide. Water-worn boulders and pebbles of such
deposits are thrown ashore along the outer side of Cape Cod and fishermen report
that they encounter marsh deposits on the outer bar at considerable depths below
tide when they are driving the poles for their fishing gear. Masses of peat cast
up by the waves are often seen on the south shore of Gay Head!

WIND ACTION AND DUNES

Cape Cod and the New England Islands are often exposed to violent storms.
The prevailing southwesterly wind is registered in the shape of the trees that
get a foothold on the coast. Wherever the scant sod on the sandy and gravelly
plains becomes broken, particularly near the edges of bluffs, where vortical
movements of the air are set up, the wind sweeps away the fine sand, leaving
saucer-shaped hollows strewn with lag gravel, the transported sand and dust ac-
cumulating now on one side, now on another of the hollow. In these hollows and

1 On the nature of the New England marshes see Edson 8. Bastin and Charles A. Davis, Peat deposits
of Maine, U. S. Geol. Survey Bull. 376.

78 CAPE COD GEOLOGY

on bare flats and the brows of gravelly cliffs, pebbles and fragments have been
shaped and polished by wind-blown sand. Fantastically carved forms, combina-
tions of water-worn and glaciated surfaces, with sand-carved facets or spoon-
shaped depressions, abound along the tops of the bluffs of the Cape, along the
north coast of Nantucket, and on lag gravel tracts on Marthas Vineyard. On Gay
Head boulders of granite and diorite 3 feet across show sand-blasted facets.!

Bluffs of gravel and sand are eroded by wind in dry weather when the sand
is not held together by films of moisture. At such times the wind removes a con-
tinuous stream of sand and pebbles from the high bluffs on the ocean side of
Cape Cod or on the south side of Marthas Vineyard, and high tides sweep away
the sand and pebbles that reach the base of the talus along the bluff. Violent
gusts carry sand over the top of the bluff to form an eolian layer near its edge.
This layer gradually becomes thinner inward but may be as much as 6 feet thick
at the edge of the bluff.

Of quite different type are the sand dunes along the beach. Though some
are carried half a mile inland, most of them are formed immediately back of the
beaches from whose sand they are fed. They reach an altitude of nearly 100 feet
on the tip of Cape Cod back of Provincetown, where the most extensive tract
of dunes in the district is found. Other notable dunes are seen in the southeastern
part of Cape Cod, at Nauset and Monomoy; about the south shore of Cape Cod
Bay off Barnstable; on the north coast of Nantucket; and east of Menemsha
Inlet, on Gay Head.

The sand of these dunes consists mainly of grains of quartz but includes
particles of magnetite, as well as garnet, which at some places forms thin layers
between layers of grains of white quartz. These layers indicate the action of
winds strong enough to blow away the light quartz but not strong enough to
move heavier material. The dunes on the east coast of Block Island are darkened
by grains of iron ore derived from the magnetite in the schist of the Narragansett
Bay region and probably also from ilmenitic iron ore in the glacial drift derived
from the stock of peridotite at Cumberland Hill, in northeastern Rhode Island,
3 miles east of Woonsocket.

On many parts of the coast the wind during dry weather blows back into the

1 For Shaler’s original account of the sand-blasted pebbles on Nantucket see U.S. Geol. Survey Bull.
53, pp. 23-26, pl. x, 1889. For a statement of the sand blast theory of origin of glyptoliths see J. B.
Woodworth, Post-glacial aeolian action in southern New England, Am. Jour. Sci., 47, pp. 61-71, 1894.
For notes on sand-blasted pebbles on Cape Cod see W. M. Davis, Facetted pebbles on Cape Cod, Mass.,
Proc. Boston Soc. Nat. Hist., 26, pp. 166-175, pls. 1-2, 1894, including figures of pebbles from Cape Cod
and Martha’s Vineyard collected by Davis and Woodworth. See also E. E. Free, The movement of soil
material by wind, U. 8. Bureau of Soils Bull. 68, 1911.

:
:
)
a

CAPE COD GEOLOGY 79

sea the sand that is thrown upon the land by gales. The difference between the
trend of the beaches and the direction of the prevalent wind produces differences
in the position, distribution and shape of the dune tracts. By a singular paradox,
on certain beaches, such as the crescentic bathing beach on the east side of
Block Island, the southwesterly dry winds move the sand northward and sea-
ward, so that when the wind is strong the beach is lowered several inches during
a single low tide; but at the same time the pebbles on the beach work up against
the wind in the opposite direction to that in which the sand is traveling, for the
wind scours out a small pit on the windward side of each pebble, into which
it slides under the action of gravity as the sand is blown away from around it.
In this manner pebbles work their way from the headlands along the wasting
beach independently of the longshore motion of the surf.

The movement of the dunes has been troublesome at Provincetown, in the
so-called ‘‘province lands,” where the state of Massachusetts has made attempts
to arrest the shifting of the sand by planting grasses and trees.!_ On the northeast
side of Gay Head a small tract of dunes has marched inland and uphill, burying
trees and shrubbery, and on the southwest side of Gay Head the dunes, sweeping
inward under the prevailing southwesterly wind, have ponded the drainage.

CHANGES IN THE SHORE LINE

The most effective geological work now in progress in this district is the
attack of the sea, which cuts away the land and forms beaches, bars, spits, and
hooks of gravel and sand. The outer side of Cape Cod is being cut away ata
rate between 5 and 8 feet a year, and the coast on the south side of Marthas
Vineyard is being carried into the sea at a rate almost as fast. Nantucket is also
being cut back rapidly, as at Wauwinet and in a stretch along the south coast
between Tom Never’s Head and the coast guard Station. Great changes have
been made in a few years in the length and position of the sand bars off the em-
bayed parts of the coast line, as at Nauset, Chatham, and Monomoy on Cape
Cod, at Haulover Break, Surfside, and Smith Point on Nantucket, and south of
Edgartown on Marthas Vineyard.

Within historic time several small islands near the shore have disappeared,
such as Webb Island, off Chatham, and a small island north of Sandy Point, at
the north end of Block Island. Beach flats formed at several places serve as a
partial and temporary compensation, of little economic value, for the loss of

* Report of the Trustees of Public Reservations on the subject of the province lands, February, 18938,
Appendix III, House No. 339, Second Ann. Rept. of the Trustees of Public Reservations, Boston, 1893.

80 CAPE COD GEOLOGY

islands and of the coast. Conspicuous among the recent deposits that form a
fringe along the shore, standing but little above ordinary high tide, are the
southward extension of Nauset Bar, the bars and beaches at Chatham, and the
forelands at Siasconset and Surfside, on Nantucket.

On the low south coasts of Nantucket and Marthas Vineyard bars formed
by the sea cut off the drowned extensions of the valleys of glacial streams, form-
ing ponds of salt or fresh water.

As a consequence of such changes along the coast, lighthouses have been set
back from time to time or new ones have been built to replace earlier structures
that have fallen into the sea, as at Chatham and Nauset, on Cape Cod. Surveys
showing the retreat of the coast have been made from time to time by the United
States Coast and Geodetic Survey, the reports of which give the most complete
account of these changes.!

The early charts do not afford sufficiently precise positions to warrant their
free use in estimating the changes in the coast line during the three centuries in
which this region has been occupied by European settlers. The earliest map of
Cape Cod and the New England Islands that pretends to give much detail was
apparently drawn in the second decade of the eighteenth century, probably by a
Boston pilot named Southack.? The part of this chart that represents the coast
from Block Island eastward is reproduced in Plate 7. The most that can be
inferred from this chart concerns the occurrence and position of small islands and
shoals. The coast line proper is sketched with very little regard to what must
have been its actual alignment and position. The upright part of the arm of
Cape Cod north of Nauset is represented as an island separated from the hori-
zontal part of the arm by a crooked passage between Nauset Harbor and Cape
Cod Bay. The chart bears an inscription on which is based the statement that a
whale boat was taken through this passage in 1717. Captain Townshend’s

1 For localities surveyed or reported, see General index of scientific papers contained in the annual
reports of the United States Coast and Geodetic Survey from 1845 to 1881, inclusive; Appendix No. 6,
Report for 1881, Washington, 1882. Other data will be found in the annual reports of the Massachusetts
Board of Harbor Commissioners, continued as the Harbor and Land Commissioners. See Seventh Ann.
Rept., January, 1873, House No. 65, for report of Henry Mitchell concerning Nauset Beach and the
peninsula of Monomoy (pp. 94-108), and for report on Haulover Break, Nantucket (pp. 109-117).
More elaborate recent surveys are those by H. L. Marindin, On the changes in the shore lines and anchor-
age areas of Cape Cod (or Provincetown Harbor) as shown by a comparison of surveys made between
1839 and 1867, and 1867 and 1890. United States Coast and Geodetic Survey, Appendix No. 8, pp. 283-
286, pls. 11-12, 1891. Also cross-sections of the Shore of Cape Cod . . . between the Cape Cod and Long
Point lighthouses, Appendix No. 9, pp. 289-341; both in part 2, Report for 1891. Also, by the same
author, On the changes in the ocean shore lines of Nantucket Island, Massachusetts, from a comparison
of surveys made in the years 1846 to 1887 and in 1891. Appendix No. 6, pp. 248-252, pls. 24-27, Rept.
U.S. Coast and Geol. Survey for 1892.

2 Townshend, C. H., Notes on an early chart of Long Island Sound and its approaches, U. 8. Coast
and Geodetic Survey for 1890, pp. 775-777, pl. 71.

CAPE COD GEOLOGY 81

remarks on the historical references to this passageway across the Cape are con-
densed as follows:

The chart furnishes positive proof of the existence of one of the closed passages that
tradition says existed in early times through Cape Cod and sustains the statement of Capt.
Bartholomew Gosnold, in 1602, that Cape Cod was then an island. That one of these passages
remained open as late as 1717 is shown by a marginal note commenting on the loss of the
pirate ship Whido.

The main passage was much used in early colonial time by small vessels and boats when
making voyages from the bay of Maine to Virginia. It is shown on the early Dutch and
French charts and on the one sketched by Schipper Adrian Block in 1614.

These memorable passages were closed up, as I have been told by Capt. William Foster
of Brewster, Mags., about 150 years ago, during a furious gale of wind,’ which was accom-
panied by a tidal wave. This herculean effort of the elements changed the whole east and south
shore of the Cape, and deposited, in the salt marshes and lowlands, sand hills sixty feet high,
and completely washed away a sand point off Nauset, where to this day, at extreme low tides,
stumps of former trees have been laid bare, which have been seen by men now living who
visited the spot for that purpose.

As a matter of fact this passage seems never to have been actually closed
to tidal water. The ancient channel is followed by a marsh through which a
modern ditch would allow high tides to course were it not for a dike about a
third of a mile north of the point where the railroad crosses it. The ancient
entrance on the bay side is still known as Boat Meadow Creek. As late as 1844
the sea is said to have occasionally swept through at high tide.’

The remarkable hollow known as Pamet River, in Truro, may at some time
have been temporarily open so as to afford a passage across the Cape but prob-
ably the sea would not permit the east end of that trench to remain unbarred
long by gravel and sand. It is further probable that, when the coast stood farther
east, this trench was represented by one or more gullies leading down from the
upland surface, in the manner of the shorter hollows on the north. Except for the
beach and dune sand at the east end of this hollow the sea might now run through
this passage and thus make an island of that part of the Cape which lies north
of it.

Crab Bank, shown as lying east of Cape Cod on the chart of 1917, appears
to have been so named because of the peculiarity of the bottom there rather than
because of shallow depth. The soundings on the ancient chart show that the
water gradually deepened eastward across the tract. Commander Stellwagen of
the Coast Survey in 1856° reported that no shoal then existed at that place
off the arm of Cape Cod, although it is shown on some charts.

1 Probably a reference to the great storm of Saturday, October 20, 1770, or to that of Sunday, Febru-
ary 24, 1722-23: vide Sidney Perley, Historic storms of New England, Salem, pp. 41, 86, 1891.

2 Enoch Pratt’s History.

?U.S. Coast Survey Report for 1856, p. 115.

82 CAPE COD GEOLOGY

The chart makes ‘‘Webb Island” coincide with the long bar of Monomoy.
There are other reasons for supposing that ‘‘Webb Island” lay southeast of
Chatham, where the modern chart shows a small shoal with 4 fathoms of water.
No trace of this shoal is seen on the map published in 1717. Indeed, it is stated
in local histories that the island disappeared before 1700.

At what appears to be the south end of the Monomoy hook the map places
‘“the Seal island sunken channel way,” probably pointing to changes in that
vicinity involving the disappearance of former islands of glacial drift.

The greatest changes appear to have taken place in the neighborhood of
Tuckernuck and of Muskeget shoal. Four small islands are represented off the
west end of Nantucket where now only Tuckernuck Island, some shifting shoals,
Muskeget, and the Gravelly Islands appear above the sea. The soundings on
other shoals south of Nantucket given on the map do not accord with the present
soundings, which uniformly show greater depth of water. Marthas Vineyard is
too grossly drawn on the map to warrant comment; but No Mans Land and
the bouldery bar connecting it with Gay Head are shown with considerable
accuracy. Cuttyhunk and Nashawena are represented as a single island. There
is some reason for believing that in Gosnold’s time the islands were tied together
by barrier beaches that closed the existing Canapitsit Channel. Block Island
is rudely sketched on this ancient chart. For nearly a century no better chart
of the coast was brought out. What appear to be copies of this map were pub-
lished in the British Coast Pilot and were used by the British navy prior to the
American War of Independence.!

A few centuries ago the eastern coast of Cape Cod must have been very
different in outline and position from what it is now, for it has been straightened
out by the cutting back of headlands and the building out along shore of the
winged beaches and hooks that terminate the Cape at Monomoy and Province-
town. Davis? has attempted to restore the old form of this part of the coast.
According to his interpretation the innermost, oldest bar at Provincetown *
may have been formed when the land on the south, between Truro and Wellfleet,

1 The English Pilot, the fourth book, London, 1775. Copy in Congressional Library at Washington
contains (No. 8) ‘‘A map of the coast of New England from Staten Island to the Island of Breton, as it
was actually surveyed by Capt. Cyprian Southack.” See Phillips, A list of geographical atlases, 1, pp.
590-591, Washington, 1909, which contains references to early maps of the New England coast in earlier

editions of The English Pilot.

2 Davis, W. M., The outline of Cape Cod, Proc. Amer. Acad. Arts and Sci., 38, pp. 303-832, 1896.
See fig. 1, p. 311.

3 At Provincetown in 1916 Dr. T. W. Vaughan called my attention to coarse gravels on the bar at
Wood End and Long Point, which indicate the former existence there of a shoal, possibly first an island,
of glacial material that has been washed away.

CAPE COD GEOLOGY 83

extended seaward as much as two miles beyond the present coast. If Marindin’s
determination of the annual rate of recession — a mean rate of 5 feet per annum
between Nauset and Highland Light — holds good for an indefinite past, the
coast has retreated a mile in about 1,050 years and would have been over two
miles farther east when the bars of Provincetown were begun. At the same
rate of wear the narrow segment of the Cape between Orleans and Wellfleet
will have been consumed by the sea within 3,000 years.

Independent calculations as to the length of time taken to change existing
shore lines at several widely distant points, such as the south coast of England
and the coast oF Massachusetts, tend to support the idea that about 3,000 years
ago certain parts of the North Atlantic shore, after undergoing a positive delevel-
ing, were brought to their present level. Reid ! regards the south coast of England
as having been stable for about 3,500 years, or from the beginning of the Bronze
Age. Johnson ? concluded from the accordant level of the successive beach crests
at Nantasket that there had been no measurable deleveling during the period
of their construction, which he estimated at not less than 1,000 years, and prob-
ably 2,000 or 3,000 years. But this conclusion must meet the objections raised
by those who hold that submerged peat bogs and the marshes along certain coasts

are proofs that a positive deleveling is now in progress.

SUMMARY OF THE GEOLOGIC HISTORY OF THE REGION

The rocks of the neighboring mainland afford evidence of some of the con-
ditions that existed and the events that occurred during the remote geologic
past in this region and indicate the sources of the material that forms Cape Cod
and the New England Islands. In late Paleozoic time the land appears to have
extended far south and east of the site of the present coast. During that time
gravel, sand, and clay that are now changed to conglomerate, sandstone, and
shale were brought to the site of the coal beds at Mansfield, Mass., and to the
adjoining part of Rhode Island. Prior to the deposition of these coal beds this
ancient land had been invaded by magmas that formed granite, on the eroded
surface of which the coal beds were laid down. Bordering the granite on the
south, beyond the gneiss and diorite of the region about New Bedford, there
were areas of Cambrian quartzite carrying marine fossils, the relics of a far
earlier invasion of the sea. In Carboniferous time great quantities of these fossil-

1 Reid, Clement, Submerged forests, The Cambridge Manuals of Science and Literature, New York,

2 Johnson, D. W., The form of Nantasket Beach, Jour. Geology, 18, pp. 162-189, 1910.

84 CAPE COD GEOLOGY

iferous pebbles were carried to the region extending from Newport nearly to
North Atterbury. Along with the Cambrian pebbles were a few that carried
marine Devonian fossils. Pebbles of both these types were dragged out of ledges
of conglomerate at Taunton and Newport during the glacial epoch and carried
southward to Block Island and Marthas Vineyard.

While Carboniferous sediments were being laid down, bodies of granitic
magma, were intruded along the west side of the site of Narragansett Bay, con-
verting sandstone and shale into gneiss and schist and forming new minerals.
Abundant fragments of these rocks are found in the drift on Block Island.
Farther north, about North Attleboro and near Boston, basic igneous rocks, in
the form of dikes and sills, as well as lava flows, formed melaphyre, diabase, and
other dark, heavy, iron-bearing rock, fragments of which occur in the drift in the
region on the south. Among these igneous rocks were large quantities of an acid
lava, the felsite or apo-rhyolite seen in North Attleboro and about Boston
and Salem, fragments of which are found from Cape Cod and Nantucket west-
ward to Block Island. Hot springs that accompanied this igneous action formed
large masses of quartz, in stocks and in veins, as at Diamond Hill, Rhode Island,
fragments of which are found in the glacial drift farther south. A few miles west
of Diamond Hill there is a mass of an ancient eruptive rock, periodotite, rich in
iron, fragments of which are scattered from Gay Head to Block Island.

By the end of the Carboniferous period the coal beds were thrown into
mountainous folds that form what Shaler termed the East Appalachians. This
mountain range probably embraced the site of Cape Cod and the neighboring
islands. The height of this range above sea level at Canton Junction was prob-
ably 15,000 feet. This mass of rock, of which little or no trace here remains,
appears to have been worn down nearly to the present level of the lowland of
eastern Massachusetts by the end of the Cretaceous period.

During Cretaceous time weathering and erosion along the site of the present
south coast of New England produced a surface of slight relief, over which streams
carried sand and clay southward toward the Atlantic, which then lay at an
unknown distance beyond the present islands. Thus was built up a plain like
that now seen along the seaboard south of New York, on which from time to
time the trees and shrubs of late Cretaceous time were buried in the low places
and lagoons in which they grew, forming the lignite now found. Before the end
of the Cretaceous period the sea came in upon the land, extending far inland.

Between the end of the Cretaceous period and the beginning of Miocene

deposition here there was a long period of erosion, probably more than one

CAPE COD GEOLOGY 85

oscillation of the land in relation to sea level. At the end of the Cretaceous period 1
the land probably rose and was somewhat eroded before any marine beds were
laid down, but the possibility of transgression by the sea in Eocene time is shown
by fragments of fossiliferous Eocene material found in the drift on Cape Cod.
Oligocene and early Miocene time was a period of uplift.

At the time of the deposition of the greensand, regarded as an extension
of the upper Miocene Chesapeake beds, to the south, the Miocene was probably
a period of submergence of the lowland, in which the shore may well have lain
against the upland somewhat east of Worcester, or even farther inland. The
beds of greensand represent the offshore facies of deposition during this trans-
gression of the sea. The Miocene sea teemed with life. Whales, dolphins, sharks,
and probably also walruses and seals, roamed along off the shore, and crabs,
mollusks, gastropods, and barnacles inhabited the bottom. The temperature of
the water in this Miocene sea appears to have been not very different from that
of the present sea off the south coast of New England. The only trace of land life
is a single molar tooth of a primitive rhinoceros found at Gay Head.

In early Pliocene time in southeastern Massachusetts the land was uplifted
and the sea withdrew. Small deposits of shell-bearing sand then laid down along
the south coast have been found on Gay Head and Long Island. The fauna,
so far as known, was chiefly molluscan and probably lived in shallow water along
the coast. The shell beds at Sankaty Head, which are of upper Pliocene and
Pleistocene age according to Dall, have heretofore been regarded as of inter-
glacial Pleistocene age, and are so considered in this report. The upper beds
of what may be called the Macoma incongrua zone, according to Dr. Wilson,
contain species which, according to Dall, are not now living in the North Atlantic
but are found in the North Pacific, indicating that a connection once existed
across or around North America from Nantucket to the North Pacific Ocean.
The presence of these North Pacific types of mollusks indicates a lowering of the
temperature of the ocean water of 5 to 10 degrees Centigrade as compared with
that of the Miocene sea in the same latitude.

The Pleistocene deposits of the New England Islands and Cape Cod consist
chiefly of beds of boulders, gravel, sand, and glacial clay arranged in a more or
less rhythmic series, separated by erosion between stages of glaciation. The
earliest of these glacial deposits are exposed only in two areas on Marthas Vine-
yard and Block Island. Subsequent to what appears to be a third glacial advance,

1 Stephenson, L. W., The Cretaceous-Eocene contact in the Atlantic and Gulf coastal plain, U. 8.
Geol. Survey Prof. Paper 90-J, pp. 155-182, with map from Long Island southward, showing Cretaceous
boundary, 1915.

86 CAPE COD GEOLOGY

indicated by profound dislocation of the beds already laid down, the sea covered
the area, spreading blue clay from Long Island to Marthas Vineyard and prob-
ably also northward along the east coast to Scituate or farther north. This was
the best marked and possibly the last recorded submergence of the south coast
of New England, though other lower stands of the land are suggested by the
partly effaced terraces of the succeeding Manhasset and Vineyard deposits.

During the Wisconsin stage of glaciation, the last stage, two lines of frontal
moraines were left in the district, one on the outer islands, including Nantucket,
and the other on the Elizabeth Islands and Cape Cod. The interval between
these two ice advances was relatively short, the remnants of the ice of the first
not having entirely melted before the second advance. The interval between the
Wisconsin glaciation and the next preceding one was much longer than the time
which has elapsed since the Wisconsin ice disappeared from New England. The
duration of the intervals between the other advances is not so clearly shown.
The interval following the first ice advance appears to have been long enough
to allow waves or streams to work over very thoroughly the glacial drift, much
as it is being worked over now.

During Pleistocene time elevation and subsidence in this region appear to
have alternated, the epochs of elevation corresponding to periods of glacial
advance and epochs of depression to periods of deglaciation, but this generaliza-
tion is not firmly established. At the time of the last ice advance the land south
of Boston appears to have stood somewhat higher than it is now. The coast
at Portland, Maine, has risen as much as 300 feet above sea level, and there has
been no change near Lynn, Mass. A depression of 40 fathoms in the latitude of
Nantucket since the Wisconsin stage would explain all the observed phenomena
of submergence along the coast and account for several features on the floor of
the sea.

Postglacial and recent events consist of the establishment of the existing
fauna and flora on the land occupied by the Wisconsin glacier. The outer islands
were occupied by animals and plants that established themselves there before
the Sounds came into existence. The flora of the southern pine barrens was
carried northward to the maritime provinces of Canada, which appear to have
stood higher during the Wisconsin stage than they stand now.

The box tortoise, the black snake, and the mole on Marthas Vineyard, the
brown snake and the mole on Nantucket, and field mice on all the outer, least
accessible islands can be explained only by assuming a former connection be-
tween the islands and the mainland. Some evidence of the length of time that

7

CAPE COD GEOLOGY 87

has elapsed since the outer islands were separated from the mainland by post-
glacial submergence is shown by the peculiar species of field mouse on Muskeget
Island, now a mere shoal between Nantucket and Marthas Vineyard. A very
similar example of variation under long isolation is seen in the mouse of Block
Island. Dense forests spring up on the stagnant margin of the ice of Alaskan
glaciers that approach a coast bathed by a warm oceanic current and a moist
atmosphere. Such forests may have grown along the ice front of southern New
England, and plants and animals may thus have bridged directly over the gaps
between lands that are now separated by arms of the sea.

Long after the islands had become separated from one another and the
mainland, the American Indian may have established himself in the district.
Although few of his shell heaps are found on the present coasts, many of them
may have been lost by the encroachment of the sea upon the land.

MINERAL RESOURCES

The valuable mineral resources of Cape Cod and the New England Islands
are the Cretaceous white clay of Marthas Vineyard, the black iron sand of Block
Island, and the beach cobbles that are suitable for use as paving stones. An
attempt was made in 1891 to obtain capital to work the lignitic clay of Gay
Head ! but the futility of the attempt was promptly shown.

The selectmen of certain towns in the islands have from time to time sold
cobblestones from the beaches to contractors for paving streets in near-by cities,
but usually the inhabitants of the islands have quickly perceived the consequent
danger to the shore lands, and there is now little or no commerce in these essen-
tial defenses of the coast.

The remoteness of Cape Cod rather than the absence of a grade of glacial
sand suitable for use as molding sand has prevented the exploration of the
region for supplies of this material. Such sand is likely to lie above the blue clay
on the north shore of Cape Cod near West Barnstable and on the islands at
what may be the horizon of the Jacob sand, but that formation usually lies
under a cover of coarse gravel and sand which prevents the economical recovery
of the finer sand.

Small beds of blue clay crop out along the shore of Pleasant Bay on Cape
Cod and along the south shore of Cape Cod Bay from West Barnstable to the
entrance of the Cape Cod Canal. At West Barnstable a brick kiln has been in

1 Boston Herald, 90, No. 22, Wednesday, July 22, 1891.

88 CAPE COD GEOLOGY

operation for several years. The blue clay at Highland Light has been used
locally. A thick section of this clay is exposed along the shore of the bay for
more than a mile south of the railway station of North Truro. This and other
beds of clay on Cape Cod generally occur in lenses, as they do beneath the light-
house at Highland Light, forming the so-called ‘‘clay pound,” or they appear
above sea level as the arches of low folds known as ‘‘clay heads.”

Small beds of clay are exposed in the western islands of the Elizabeth group
and large beds of blue clay on Block Island, but the most valuable clays in the
district are the white, red, and mottled clays and kaolinites of Marthas Vineyard,
found on the north side of Gay Head and in the northern part of the main island
from the vicinity of Menemsha pond to Makoniky, near Vineyard Haven. Sev-
eral attempts have been made to ship this clay for use in making pottery and
fire brick. The beds in the western part of the island are highly inclined and much
dislocated, being so intricably folded in with beds of gravel and sand that it
is desirable to explore the ground thoroughly with the drill before workings
are started. There is a small tract at Makoniky in which the white Cretaceous
kaolinite is less disturbed, and at that point an extensive plant having kilns
for burning several varieties of brick has been operated. The necessity of ship-
ping the clay by boat to the mainland is an obstacle to its successful competition
with other similar clay for which all-rail transportation is available.

The beds of Cretaceous white clay at Ball’s Point, Clay Head, on Block
Island, and of lignitic clay farther south are too small and too much covered by
Pleistocene beds to find other than occasional local use.

The beds of lignite in the Gay Head cliffs contain nodules of marcasite
and acicular crystals of selenite, and the bed of greensand at the same place
contains phosphatic nodules, but these materials are specimens suitable for
display in a case containing natural history objects rather than useful substances;
and this remark applies also to the fossil bones and sharks’ teeth found at the
same locality.

The bed of Miocene greensand, usually turned reddish brown where it is
exposed, has been exploited mainly in the cliffs at Gay Head, east of the light-
house. The material might be valuable as a fertilizer of the sandy soil of the
island, where it occurs in sufficient quantity to be utilized, but I am not aware

that any experiments have been made with it.

The water supply of Cape Cod is abundant, though most of it is under-
ground. The same is true of Nantucket and of the eastern and southeastern part
of Marthas Vineyard. In the upland part of Marthas Vineyard and on Gay

CAPE COD GEOLOGY 89

Head the underlying clay is not well stored with water, and an adequate supply
for other than small household uses cannot everywhere be counted on. Wells
bored and sunk in the gravel on the south side of the uplands usually give fair
supplies. Similar conditions exist on Block Island, where, owing to the con-
tortion of the beds, experience alone can determine the practicability of obtain-
ing an adequate supply of water at any given site. In the Elizabeth Islands
several successful bored wells have been put down from 150 to 200 feet or more,
and for the most of this depth below sea level.

PART IT
GEOLOGY OF PARTICULAR AREAS

|
|

CHAPTER I
GEOLOGY OF NANTUCKET AND ADJACENT ISLANDS

By J. B. WoopwortH
NANTUCKET
GEOGRAPHY

Nantucket, which lies about 25 miles south of the main arm of Cape Cod,
is the easternmost of a group of glaciated sandy and clayey islands off the south
coast of Massachusetts, Rhode Island, and Connecticut. Although it is low,
attaining an elevation of 100 feet above sea level at only one point, it is the third
largest island in the group, and it forms a barrier behind which broad sounds
afford protected passageways for ships for nearly 200 miles. On its east and
southeast sides it is protected from the breakers of the heavy storms of the
Atlantic by broad shoals, of which George’s Banks, about 90 miles to the east,
is the best known. Notwithstanding this protection the islands are encroached
upon by the sea, which here and there capriciously adds piles of sand to the
coast or as capriciously removes them.

Nantucket enjoys a wide reputation for its cooling sea breezes in summer
and for its oceanic climate throughout the year. Its beds of glacial gravel yield
an abundant supply of drinking water, and its excellent sand beaches afford
varying exposures to the sea, facing the open Atlantic on its south and east
sides and the quieter water of the sound on its north side. The island contains
no valuable mineral resources, but the striking waste of its coast through the
attack of the sea (see Plate 10, fig. 1) and the fact that it is an instructive part
of the great terminal moraine at the latest stage of the glacial ice give it peculiar
geologic interest.

Nantucket appears to have been well wooded before it was occupied by
Europeans, but it is now almost treeless. Evidence of the existence of the ancient
forest is occasionally seen in fallen trunks of oak found in peat bogs.! The pines now
growing on the island were set out 60 or 70 years ago, but those that were planted
along the coast did not survive the attack of the high winds, and the existence
of all the trees was at one time threatened by the pine moth (Retina frustana) 2

1 Wilder, Burt G., Evidence as to the former existence of large trees on Nantucket Island, Proc. Am.

Assoe. Adv. Sci., 40, 1894.
2 Scudder, Samuel H., The pine moth of Nantucket, Pub. Massachusetts Society for the Promotion of

Agriculture, Boston, 1883.

94 CAPE COD GEOLOGY

The northeast arm of Nantucket has been at times cut off from it by storms
that washed away the beach at the head of the harbor, and the island of Tucker-
nuck has sometimes been joined to it by storm-made beaches. Tuckernuck is
virtually an extension of the so-called terminal moraine along a line running
from Nantucket to Chappaquiddick, an island at the east end of Marthas Vine-
yard. Muskeget, which lies west of Tuckernuck, is a low, gravelly islet. South
of Muskeget are the Gravelly Islands, small outlying parts of the same dry
shoal

GEOLOGY
CORRELATION OF FORMATIONS

The geology of Nantucket is shown on Plate 8. The following table shows

Dall’s and Woodworth’s interpretations of the formations recognized on Nan-

tucket:

Pliocene and Pleistocene Formations on Nantucket

|
Arranged with lower part of Sankaty | Arranged with Sankaty sand as equiva-
sand as Upper Pliocene (Dall’s interpre- | lent of glacial Weyquosque formation on
tation) Marthas Vineyard (Woodworth’s inter-
pretation
= Wisconsin glacial stage; Nantucket substage
a Vineyard interglacial stage; erosion
3 Manhasset formation (glacial); Hempstead gravel member
2B Montauk gravelly till member
S Jacob sand (transitional; interglacial)
Gardiners clay Gnterglacial) at Sachem spring
(Jameco gravel and associated deposits of till on Marthas Vineyard; not recog-
nized above sea, level)
Stony blue clay, passing laterally into stratified gravel and locally contorted drift
of probable Manetto age
. Upper shell bed at Sankaty Head Fossiliferous Sankaty sand and bed of
a waterworn marine shells at Squam
S Lower shell bed at Sankaty Head Head (at horizon of the Weyquosque
a formation of Marthas Vineyard)
z Ferruginous gravel (of Desor and Cabot), | Ferruginous gravel of Desor and Cabot
5 lying unconformably on light-brown (Not exposed)
sandy clay

The geological formations that lie deep beneath the surface of Nantucket
are supposed to be extensions of the beds of Upper Cretaceous clay and sand
seen on Marthas Vineyard, but such materials have not been seen above sea

)
|

|

CAPE COD GEOLOGY 95

level or reported in well borings on the island. The sole trace of these Cretaceous
deposits appears to be a drifted fragment of fossiliferous, reddish argillaceous
sandstone containing poorly preserved casts of marine mollusks, the whole re-
sembling similar drifted fragments of the Matawan formation (Upper Creta-
ceous) found on Marthas Vineyard. Of the Eocene and Miocene formations
found elsewhere in the district, either in place or as glacial erratics, the only
known trace on Nantucket consists of the battered and waterworn tooth of a
Miocene shark found in fossiliferous sand at the base of the cliff at Squam Head
in 1915. This deposit is a part of the Sankaty sand, which has been variously
referred to the Upper Pliocene and Lower Pleistocene series. Dall held that a
certain part of it should be referred to the upper part of the Pliocene series, but
for reasons stated below it is here referred to the lower part of the Pleistocene
series, the term Pleistocene being used to include deposits of the first ice invasion.

PLEISTOCENE EpocHu
SANKATY SAND.

The name Sankaty beds, proposed by me for the beds of fossiliferous ma-
rine sand under the Sankaty Head Lighthouse at the east end of Nantucket,
is retained in this report as Sankaty sand to designate a group of deposits con-
cerning which three different views have been held as to their position in the
time scale and their place in the succession of local deposits. These beds appear
to be the lowest that are exposed above sea level on the island. According to
Desor and Cabot they rest on a bed of ferruginous gravel, which in turn over-
lies unconformably a bed of light-brown sandy clay of unknown thickness.

For a time J. D. Dana adopted the erroneous view that the shell-bearing
beds were laid down after the glacial epoch and put them in his ‘‘Champlain
epoch” of submergence. The mistake was further made of assuming that the
altitude of the upper edge of a set of tilted beds indicates the height at which
they had stood above the level of the sea. Upham has shown that the beds had
been disturbed and that their elevation above the present sea level does not
indicate their relation to the sea level at the time of their deposition. It was
also shown that the deposit had certainly underlain the last ice sheet, that. it
was much eroded, and that it considerably antedated the last glacial stage.

For many years the assemblage of fossil mollusks in the beds was regarded as
evidence of their post-Pliocene or Pleistocene age. In a paper on the older Pleis-
tocene deposits of the islands, I tentatively placed the beds at Sankaty Head
at the same horizon as certain beds of sand and gravel on Marthas Vineyard,

96 CAPE COD GEOLOGY

and adopted for the deposits at this horizon the name Sankaty beds, because the
beds at Sankaty were fossiliferous and were well known. In Fuller’s report
on Long Island the Sankaty beds were described as ‘‘separable into two distinct
units, the Jacob sand and the Herod gravel member of the Manhasset formation,”’
each of which had been traced by him from Long Island to Nantucket

According to Fuller the beds at Sankaty Head lie below the Montauk till
and are well up in the Pleistocene series, having below them the Gardiners clay,
about 40 feet thick, the Jameco glacial gravel (with possibly lateral changes to
a glacial boulder clay), a lower Pleistocene glacially derived bed of gravel and
sand, and finally, as the sections on Marthas Vineyard and Block Island would
lead us to expect, a more or less continuous bed of washed glacial boulders at or
near the base of the series.

In a doctorate thesis published by Dr. J. Howard Wilson? the beds at
Sankaty Head are regarded as deposits laid down in a lagoon. A lower bed of
shells is regarded as well protected from the sea. The upper bed of shells was
laid down under colder water, supposed to be due to the readvance of the ice
sheet from the north. The fossils in this bed are of more northern types than those
in the lower bed. A noticeable unconformity is observed between the fossiliferous
beds and overlying fine sand, which contains only minute fragments of shells
and is regarded as probably wind-blown material.

Wilson made very thorough collections of the fossil shells in this bed, and
found in the upper bed Serripes laperousii Deshayes and Macoma incongrua
von Martens, species belonging to the fauna of the Pacific coast, not found
heretofore, according to Dall, east of Point Barrow. He also found Pandora
crassidens Conrad, a form common in the Miocene of Maryland but not known
at higher horizons northeast of that district. Pandora crassidens and a single
specimen of Chrysodomus stonet Pilsby were the only extinct forms discovered
in the beds. Wilson regarded the fauna of both beds as Pleistocene, thinking
the underlying ‘‘clay”’ of Desor and Cabot a ground moraine of this period.

In discussing the deposit carrying Macoma incongrua, Dall stated his inclina-
tion to ‘‘regard that horizon as probably Upper Pliocene.”’ He writes:

I take it that the glacial period cut off the intercommunication between the two sides
of the continent, but there is no reason why some of the Pliocene species should not have
lingered on into the Pleistocene on the Atlantic side. But I am confident from the association

of species that the period of close intercommunication was Pliocene, because the fauna shows a
milder climate than subsequently. This is true all around the northern hemisphere.*

1 Fuller, M. L., Geology of Long Island, U. 8. Geol. Survey Prof. Paper 82, p. 92, 1914.

2 Wilson, J. Howard, The glacial history of Nantucket and Cape Cod, New York, the Columbia Uni-
versity Press, 1906.

3 Official letter.

CAPE COD GEOLOGY 97

Dall appears to have supposed that the species considered were obtained
from the lowermost bed at Sankaty, but Wilson states that they were obtained

‘from the upper bed, which lies above the bed containing a Pleistocene fauna.

These mollusks may have lived during a long and warm interglacial stage, when
the conditions simulated those of late Pliocene time.

My own work at Sankaty Head has been limited to the attempt to de-
termine the stratigraphic relations of the beds in this section to those in other
sections on the island. For this purpose a few exposures on the coast immediately
north of Sankaty Head were available.

In the low bluffs between Sankaty Head and Squam Head a section that
was visible in the summers of 1915 and 1916 showed a tilted bed of sand con-
taining comminuted shells, evidently the upper part of the Sankaty sand, which
was unconformably overlain by a bed of till containing striated pebbles. This
bed of till came out horizontally from the upper part of the bluff and was flexed
downward into a vertical position, its resistance to erosion by the sea causing it
to form a small buttress on the beach. In this section the Sankaty sand appears

- to underlie one of the beds of till in the older Pleistocene, a fact shown also,

though less clearly, in the section under the lighthouse.

In the section exposed in the bluffs at Squam Head in 1915 and 1916 the
same gravelly till that overlies the shell-bearing deposits on the south passed
northward in nearly horizontal attitude into stratified material.

All the sections on the east coast of Nantucket exposed in these years showed
that a bed of till of the type I have called a stony clay, rather than a boulder bed,
lies above the fossiliferous sand. At some places this bed of till is stratified and
looks like a bed of gravel containing large quantities of clay, or a bed of clay
containing some pebbles (see Plate 10, fig. 2). The deposit has no feature in
common with the, basal Dukes boulder bed, on Marthas Vineyard, a deposit
resembling the thoroughly washed huddles of boulders on a sloping beach of the
present coast. On the other hand, the till strongly resembles the Moshup stony
blue clay or till of the Gay Head section. I, therefore, conclude that the Sankaty
shell beds lie above the base of the local Pleistocene series, defined as marking
the beginning of the first ice invasion.

The time of the deposition of the shell beds and the overlying till is also
suggested by a consideration of the geological structure in its relation to the
time of the dislocation by ice thrust and to the Vineyard stage of erosion on
the island. The front of the Wisconsin ice sheet at its farthest advance stood
along the head of the outwash plain on Nantucket, covering the upland at

98 CAPE COD GEOLOGY

Sankaty Head, on which it spread a thin veneer of drift. The surface over which
this ice sheet advanced was produced by the erosion of the folded bed of till and
the bed of shell-bearing sand, a bed that had evidently been already deformed
and folded by an ice advance antedating the deposition of the Montauk till.
We are thus led to place the bed of till that overlies the Sankaty shell-bearing
deposits below the horizon of the Gardiners clay and at the horizon of the Jameco
formation, which has a till phase (Moshup till member) on No Mans Land
and at Nashaquitsa cliffs, or to place the bed of till overlying the Sankaty sand
at the horizon of the stony blue clay in the Gay Head section, which in this
report is referred to the Mannetto formation, a conclusion similar to that indi-
cated by the facts first presented. I am, therefore, inclined to place the Sankaty
shell-bearing beds very low down in the Pleistocene series, above the Dukes
boulder bed and under the Jameco and its Moshup till member, at the horizon
of the beds of glacial sand and gravel found at the east end of Nashaquitsa cliffs
(the Weyquosque formation of this report), or in like relation to the Sankaty
beds of my earlier paper.

If this argument is valid, no Pliocene deposits have yet been found on
Nantucket. But as the delimitation of Pliocene and Pleistocene deposits has
been determined by somewhat arbitrary and very different standards and criteria
it may be possible that here on the seacoast the glacial and interglacial deposits
may have become interlocked with coastwise marine deposits that extend south-
ward beyond the glacial limits and that have been regarded as parts of the Plio-
cene series.

FOSSIL SHELLS UNDER THE INTERIOR OF THE ISLAND

Several references to fossil shells encountered in digging wells and making
excavations are found in the literature concerning Nantucket. Most of the
wells in New England were dug long ago and no records were made of the beds
penetrated.

In 1882 E. K. Godfrey! published a note by Mrs. Anne Mitchell Macy on
“The botany, conchology, and geology of Nantucket,” in which she states that
shells like those seen in the bluffs at Sankaty Head had been found far from the
bluffs. Mr. Godfrey also reproduces a letter written by Zaccheus Macy to the
Massachusetts Historical Society, dated Nantucket, ‘‘ye 2d ye 10 mo., 1792,”
in which he says he found shells in his well at depths nearly 40 feet below the
surface.

Dr. J. Howard Wilson states that in boring for a well many years ago on the

1 Godfrey, E. K., The island of Nantucket, Boston, 1882, pp. 32-33.

CAPE COD GEOLOGY as

Kimball farms, southwest of the towm of Nantucket, shells were encountered at
a depth of 50 feet. This well affords some evidence as to the thickness of the
last glacial outwash gravel deposits on the outwash plain.

The reported depths at which shells are found, presumably in the Sankaty
sand, confirms the indications seen in the cliffs along the shore, that the last
glacial drift of Wisconsin time, in the morainal northern half of the island and
in the creased plain forming its southern half, is relatively thin.

Edward Hitchcock ! collected a shell of Pyrula carica (Busycon carica) from
a depth of 47 feet below the surface of Nantucket. The Sankaty sand and its
fossil shells probably have a rather broad extent beneath the outwash plain at
about the present sea level.

COARSE GRAVEL

Between the lighthouse at Sankaty Head and Siasconset there is a coarse
rubbly gravel bed, from 10 to 12 feet thick at the upper part of the section,
containing pebbles of Upper Cambrian quartzite, casts of Obolella sp., a diabase
with pronounced ophitic structure, a fine-grained red sandstone resembling the
red Carboniferous rock about North Attleboro, a gray conglomerate that is
common in the Carboniferous coal measures of southern Massachusetts, ‘a red-
banded felsite, a dark schist resembling varieties of the metamorphosed Car-
boniferous rocks, hornblendic granitite of eastern Massachusetts type, diorite,
fragments of reddish Cretaceous nodules and sandstone and lignitic sandstone,
and some gneissic and amphibolitic rocks. Most of these rocks are of types com-
monly found in the drift as far west as Block Island and in southeastern Massa-
chusetts. The felsite is the same that is found in the Pleistocene gravel from
Nantucket northward, on Cape Cod, and presumably came from the Lynn-
Saugus area or an eastward extension of it now beneath the sea. The bed lies

unconformably on the fossiliferous sands of the Sankaty section.

SECTIONS ALONG THE NORTH SHORE
Sections along the north shore from Sherburn bluffs westward are discon-
tinuous partly because of folds that carry the beds below sea level and partly
because of accumulations of talus. An instructive section is seen at Sachem
Spring, in Nantucket cliffs.
Section at Sachem Spring

Rubbly drift and sandy soil at top ee

Brown pebbly clay or till rr 10

Fine yellowish sand (Jacob sand) ls ‘aC

Blue clay (Gardiners clay) oe ek 15

1 Catalogue of the collection of rocks, minerals, and fossils in the State Cabinet, Sixth Ann. Rept.
State Board of Agriculture for 1858, Boston, 1859; Appendix, Agricultural Museum, p. xi, specimen No.
3.

100 CAPE COD GEOLOGY

This section shows the same succession of beds that is seen on the islands on
the west, except that the Herod gravel member, below the Montauk till, is not
represented. The blue clay in this section may be interpreted as the lost bed of
clay at Sankaty Head, formerly seen in Anthony’s Nose; the yellowish sand
may be the equivalent of the fossiliferous sand, and the pebbly clay or till may be
the same bed that lies above the shell beds on the east coast, but that interpreta-
tion is not made here.

In the low headland west of Copaum Pond there is a bed of pebbly clay or
till carrying rounded pebbles of white quartz, probably derived from Cretaceous
gravel. The base of this bed is not exposed. It is overlain by a bed of gravel, a
foot thick, containing pebbles, the largest 4 inches in diameter, upon which lies
a bed of fine, buff clayey sand. Upon all these beds lies the universal coastwise
recent wind-blown sand, here 3 feet thick. Other exposures show what appear
to be parts of the same set of beds. In the best of these sections gravelly till at
the base is succeeded by grayish buff clay, which is in turn overlain by sand
containing scattered pebbles.

At the southern limit of the town of Nantucket, southwest of Windmill
Hill, beds of rusty clay are exposed. These beds pass southwestward under
fine yellowish sand, evidently repeating the section at Sachem Spring. It is prob-
ably one of these same beds of clay that is brought up by a fold in the hill on
which the water tower stands, just east of Washing Pond.

East of the town, in the Wier valley, glacial gravel is struck in shallow wells
apparently at a horizon above that of the beds west of the town.

Only one bed of pre-Wisconsin till appears to be exposed on the island, and
this probably lies at the horizon of the bed of stony blue clay at Gay Head,
which is referred to the Mannetto stage. It nowhere carries large boulders, and
at many places it passes laterally into water-laid drift. The section exposed is
not as a whole exactly comparable with that on the islands to the west and
lacks the apparent persistent parallelism of the beds that enabled Fuller to trace
the Pleistocene above the basal beds from Long Island eastward to Marthas
Vineyard. If the bed of till is at the horizon of the stony blue clay at Gay Head,
the Gardiners clay proper and higher beds are not represented, probably because
they have been eroded away. The island is subject to great erosion, and erosion
may have taken place at one of the stages of the Vineyard interval marked by
now partly masked terraces on Marthas Vineyard. The island was not only sub-
ject to erosion by the sea but was crumpled and deformed by the Wisconsin ice.

7
i

CAPE COD GEOLOGY 101

Wisconsin STAGE OF GLACIATION

Nearly all the surface features of Nantucket, except the beaches and sand
spits, are parts of the terminal moraine and the outwash deposits of the first
substage of the Wisconsin glaciation. The island may be divided longitudinally
into three sets of glacial features: the outwash plain, which forms its southern
part and includes more than half its surface; the Nantucket moraine, which
forms its northern hilly belt; and the fosse or longitudinal valley that lies be-
tween the other two areas. For most of the length of the island the northern
limit of the outwash plain is fairly well shown by a bluff or ice contact slope,
which marks exactly the position of the front of the ice during probably the
greater part of the time it was on the island. The area north of this slope was
covered with ice that extended northward as far as Labrador. The area south
of the slope was free from ice, forming a plain that sloped southward to or toward
the sea; and from its analogy with similar plains in front of glaciers in high lati-
tudes today we may infer that one who might have traveled over this plain
would have been impeded only by the streams of ice-cold water that flowed
from the front of the ice.

THE OUTWASH PLAIN

The outwash plain that occupies the southern half of the island slopes south-
ward except at the east end of the island, where it slopes southwestward. The
crest of the ice contact slope stands somewhat more than 60 feet above sea level
and the slope descends to the floor of the fosse, which lies between the 20-foot
and the 40-foot contour. The crest is notched by creases that were made by
streams flowing from the ice and that extend southward, over the plain. Some of
the creases have received local names, such as Madequecham Valley, Barnard
Valley, Wier Valley. Madequecham Valley appears to be continued across
the Nantucket moraine, just west of Altar Rock Hills, to the depression at
Polpis Harbor. Immediately south of the town of Nantucket the ice contact
slope is scarcely distinguishable, and the deposits there include a sandy till
that lies south of the general line of the head of the plain on the east.

In the western part of the island, near Hummock and Long ponds, the
creases are more pronounced and the depressions are deeper, their bottoms for
most of their length lying below sea level. They also extend farther north across
the fosse into the region of the corrugated Nantucket moraine. The Hummock
pond crease is continued in Washing and Maxey ponds and a small pond farther
south, all of which appear to occupy ice block holes in a downfolded part of the

moraine.

102 CAPE COD GEOLOGY

The ground about Hummock Pond, as Dr. J. Howard Wilson has pointed
out, consists largely of beds older than those of the plain, clay appearing at or
near the surface on the east side of the pond, where also a few boulders may be
seen.

Few boulders are found on the plain. One was seen in 1915 on the line of
the old railway, a mile or so from the supposed position of the ice front at the
time the plain was formed. An older sheet of till may have furnished this boulder
as well as those seen about Hummock Pond. On the other hand, the Wisconsin
ice sheet, in its earlier substages, may have advanced beyond the site of the
present island and its effects may have been largely masked by the building of
the plain.

The plain must have originally extended a mile or more south of the greater
part of the present southern coast line. Tom Never’s Head (see Plate 11, fig. 1)
is a bluff cut by the sea in the iceward part of the plain where the fosse and the
ice contact slope turned southeastward along the ice front, which appears to have
extended as far southeast as Nantucket shoals. The moraine probably also con-
tinued in this direction. On an ancient map of the shoals, near their southern
border, is the inscription *‘Bow Bell is great stones,” which may be interpreted
as evidence of the presence there of glacial boulders.

e

THE FOSSE
The longitudinal valley or fosse that lies between the crest of the outwash
plain and the corrugated Nantucket moraine is due to the building up of the plain
south of the ice front and to the formation of the moraine north of it. It is, there-
fore, a depression held open by the ice that lay along the border of the ice sheet.
It is evidently not a drainage channel cut by a stream that flowed from the
edge of the ice during its retreat, for these drainage channels, such as that of
Long Pond, stretch across the fosse and the plain alike. The bottom of the
fosse, although it contains a few boulders, is the smoothest surface on the island,
and it is prevailingly swampy (see Plate 11, fig. 2). Gibbs Pond, which stands
within the fosse, appears to occupy a shallow depression unconnected with glacial
streams. The fosse was apparently not eroded during the Wisconsin stage, and
although it contains some Wisconsin drift it may represent the old surface of the

island, upon which the outwash plain was built.

THE NANTUCKET MORAINE
The general position of the ice front on Nantucket is well defined by the low
bluff at the northern margin of the creased outwash plain. The moraine-like

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CAPE COD GEOLOGY 103

mound-and-kettle surface north of this bluff, or ‘tice contact,” is separated from
the outwash plain by a depression or fosse that varies in width from half a mile
to more than a mile. The mounds and kettles of the so-called morainal hills
were once regarded as accumulations made inside and under the ice while the
sand plain was being laid down outside of the ice, but it now appears that most
of the drift in the mounds and hollows consist of stratified beds of gravel, sand,
and clay laid down long before the advent of the Wisconsin ice sheet. Where
the relation of form and structure can be discerned the contorted beds and the
mounds and hollows conform to such an extent as to indicate that their form
and structure are alike the results of deformation by the overriding Wisconsin
ice sheet or by earlier ice sheets, a deformation subsequent to the formation of
the surface that bevels the tilted and eroded beds of the island. The Wisconsin
drift or till in the so-called morainal belt is very thin, composed only of scat-
tered boulders and here and there a rubbly layer laid down on older stratified
material. The so-called moraine is not a true moraine in the sense of a deposit
made at the edge of the ice sheet.

On Nantucket the ridges and hollows of this submarginal push moraine or
pseudo-moraine are typically displayed east of Nantucket Harbor, in the Shaw-
kemo Hills, Altar Rock Hills, and Folger Hill. They are arranged in roughly
parallel lines that sweep around with a somewhat curvilinear trend similar to the
lobation of moraines. East of the deep crease known as Madequecham Valley,
which extends south-southwest from Polpis Harbor to Madequecham Pond,
the ridges trend somewhat north of west in the higher part of the area. Between
Folger Hill and Sesachacha Pond the ridges and depressions trend between north-
west and west of north. On the west side of Madequecham Valley the strong
ridges trend northeastward, and although this trend is not shown by some ridges
it reappears in strong ridges as far west as the east shore of Nantucket Harbor.
Yet within this northeastward-trending group of ridges there are kettle holes
whose long axes trend north of west.

The change in the direction of the lines of ridges and hollows on opposite
sides of Madequecham Valley suggests that the origin of this valley is in some
way associated with the origin of the hollows between the ridges, and that al-
though that valley was occupied by a subglacial stream, as Shaler first pointed
out, its position was determined by the deformation or dislocation, through
ice thrust, of the underlying gravel and sand. It may be possible also that along
this line there was a significant break in the nature of the deposits or in the

masses of ice that pushed them forward.

104 CAPE COD GEOLOGY

HYPOTHETICAL CONSTRUCTION OF THE CORRUGATED NANTUCKET
MORAINE BACK OF THE FOSSE

The evidence now available of the crumpling of the beds in the so-called
submarginal moraine makes it possible to offer a better explanation than has
yet been given of the mode of action of the ice sheet back of the outwash plain.
If the marginal ice rested on the relatively even older Pleistocene surface, as soon
as the sand and gravel washed out from the ice front had been banked up to a
height that would obstruct the forward motion of the bottom part of the ice,
the ice above a certain prism lying back of the head of the plain would begin
to shear up. The shear plane would dip inward and downward toward the ice,
cutting off a prism of stagnant ice from the live ice back of it and above it. Ac-
cording to this conception the topography of the head of the outwash plain
and the breadth of the fosse occupied by the prism of dead ice indicate that this
shear or thrust plane had an inclination from the horizontal of about 50 feet to
the mile from the present head of the plain, which stands at an elevation of 60
feet. The pliable material behind this thrust plane, below the bottom of the
ice, would be dragged and kneaded by the motion of the glacier. It is conceiv-
able that successively higher slices of the ice at its front, such tongues of ice
as the Mer de Glace, may have overridden the lower parts of its mass, leaving
relatively inert, detached sections beneath it. This theory would explain the
succession of ridges and hollows of the Nantucket moraine, especially as the
alignment of the under part of the ice front could hardly have been more orderly
than the mounds and hollows seen in the Shawkemo Hills.

Some evidence that the ice sheet overrode the outwash plain is afforded by
beds of sandy-gravelly till, containing small striated pebbles, seen in railroad
cuts southeast of the town of Nantucket. It is evident that the ice advanced
over many deltas, although the ice contact slope at the head of the plain is sharp
and distinctly preserved, showing the mean position of the ice front during most
of the time it stood along this general line.

The gravelly or rubbly layer at the top of the cliff near Sankaty Light con-
tains fragments of the following kinds of rocks:

Igneous rocks: A diabase with pronounced ophitic structure; hornblendic granitite;
diorite. Rocks of these varieties crop out along the east coast of Massachusetts north and
south of Boston.

Sedimentary rocks: Pebbles of Upper Cambrian rocks containing casts of Obolus sp.
[Westonia rogerst Walcott] identical with pebbles found in the Carboniferous conglomerates
of Massachusetts and Rhode Island. Fine red sandstone resembling the Carboniferous red
rocks about North Attleboro, Mass. Gray compound conglomerates identical with the con-

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CAPE COD GEOLOGY 105

glomerates in the Carboniferous areas of southeastern Massachusetts. Reddish-brown Cre-
taceous sandstone identical with fragments and nodules found in the drift on Marthas Vine-
yard, Block Island, and Long Island. Lignitiferous sandstones of Cretaceous age.
Metamorphic rocks: Gneiss and amphibolite schist; rocks like those found on the south
shore of Massachusetts and Rhode Island from Newport eastward.
The fragments of Cretaceous sandstone were probably of local derivation;
the other fragments may have traveled from the east coast of Massachusetts

or from points now under the neighboring waters on the east.

POST-GLACIAL OR RECENT CHANGES

Since the Wisconsin ice sheet melted on Nantucket the recorded changes
are few, consisting of the establishment of vegetation on the glacial gravel and
sand, a slight weathering of the mainly siliceous rocks of the drift, and the results
of the dominant action of the sea. Owing to the nature of the subsoil, rainfall
has had little effect in sculpturing the surface, particularly as the drainage area
is too small to permit the formation of rivers. The chief postglacial features
are the swamps and marshes, the beaches, and the dunes along the shore. A
minor feature consists of thin heaps of shells along the coast, accumulated by the
aboriginal inhabitants of the island. Of some scientific interest are the sand-
blasted pebbles or glyptoliths which abound in the areas of ‘‘lag gravel” on or
near the brows of wind-swept cliffs, particularly along the north coast of the
island.

NATURAL CHANGES

The sea is slowly wearing away the south and east coasts of Nantucket,
but the points of its attack have shifted somewhat, so that places which were
formerly receding are now fronted by broad sand beaches. Many years ago the
cliffs at Sankaty Head and Siasconset were freed from talus by the waves, but
now a broad beach encircles this part of the coast and the sea rolls in against
the cliffs only in high storms. Between Siasconset and Tom Nevers Head a wide
foreland of sand has been built out and, farther west, near Surfside, at a jog
in the coast line, another foreland has in recent years been formed in front of
the coast guard station. Between these forelands the sea has eaten away the
cliffs rapidly, and at Wauwinet also it is even more rapidly changing the form
of the coast line.! Still greater changes have modified the forms of the beach
bars thrown across depressions, such as that at the head of Haulover Break,
between Wauwinet and Coskata Island, and that at the west end of Nantucket.

1 According to Mr. W. H. Codd, the coast at Wauwinet retreated 400 feet between 1882 and October
3, 1893.

106 CAPE COD GEOLOGY

Haulover Break, so-called because whaling ships were once taken over it
into the inner harbor, was surveyed in 1846 by Henry Mitchell, of the United
States Coast Survey, and in 1872 by Henry L. Whiting. Between these years
the main inner stretch of the beach had remained essentially unchanged; even
‘the lines and details of sand hills” that were not exposed to the action of the
waves showed no change. Whiting! found, however, that between these years
the shore line outside of the beach had been driven back about 100 feet. The
shore line within the bay at this place had remained about as it was in 1846.
Haulover Break was again surveyed by Henry L. Marindin,? of the Coast and
Geodetic Survey, in 1890, when the outer face of the beach was 160 feet inside
the line of 1874, showing a loss at the rate of 10 feet a year; but Marindin notes
that the average loss since 1846 had been at the rate of 6% feet a year. Up to
1890 there is no record that the sea breached Haulover Break, though F. P.
Gulliver * states that he had heard of an old map which shows an opening there.
According to Gulliver the sea began to break over the beach in storms somewhat
before 1896, and on December 17, 1896, it broke through and maintained a
shifting passage until about 1900.* In 1916 the ocean side of the former gap was
filled by a narrow strip of beach, and on the bay side a sand spit had been built
out from the south and nearly enclosed a small oval inlet.

The beach from Sankaty Head southward appears to have been built out
mainly since the survey of 1846, when the apron of sand east of Tom Nevers
Head extended farther out than it did at the time of Marindin’s resurvey in 1890.
West of the stretch between Forked Pond and Surfside the coast for a consider-
able distance receded about 389 feet between 1846 and 1890, entailing, according
to Marindin, a loss of 165 acres of land in 44 years. This loss was still going on
in 1916, when the site of the Surfside Hotel was being consumed by the waves.
Miacomet Rip, at the west end of this retreating segment of the coast line, pre-
sented a concave front to the sea in 1846; in 1916 a rounded sand foreland there
projected several hundred feet into the sea.

Greater changes have taken place in the position of the long beach known as
Smith Point, at the extreme west end of Nantucket (Plate 9). The earliest
traditions of the island indicate that this point was the landing place of Indians

1 Whiting, Henry L., Massachusetts Harbor Commissioners’ Seventh Annual Report, January 1873,
House No. 65, pp. 109-111

2 Marindin, Henry L., On the changes in the ocean shore lines of Nantucket Island, Massachusetts,
from a comparison of the surveys made in the years 1846 to 1887 and 1891. Plate 25 gives details of
surveys of Haulover Break.

3 Gulliver, F. P., Nantucket shore lines, Bull. Geol. Soc. America, 15, p. 510 (footnote), 1904.

4 Gulliver, op. cit., pp. 511-513, and pl. 50. Also Ann. Rept. Chief of Engineers for 1903, p. 90.

CAPE COD GEOLOGY 107

coming from Marthas Vineyard. Late in the eighteenth century the inhabitants

of Nantucket drove their young cattle in the spring along this beach at low tide

to Tuckernuck Island! Ona map of Massachusetts compiled “from the best

authorities” by J. Denison, published sometime before 1795, a long bar is shown

extending from Nantucket westward along the south side of Tuckernuck Island

and to the west of it. A slight break is shown in the bar near its junction with

Nantucket.? On another small-scale map, engraved for the New Encyclopedia by a
L. Low, New York, and dated 1799, the bar that now ends in Smith Point is
shown extending somewhat beyond the west side of Tuckernuck to a point nearly
south of what appears to be the Gravelly Islands. The bar must then have lain
considerably farther south than it lay in the middle of the nineteenth century.
Accurate mapping of the beach began with the survey of 1846. From that time
the position of Smith Point and of the beach of which it is the west end is given
by Marindin, who describes the changes it has undergone as follows.

This point is most erratic in position. In 1846 it was situated at the end of a long and
narrow sandy beach, almost directly west of the island of Tuckernuck. Ten years later, in
1856, the point was about 1 mile to the eastward, and in 1887 the point to which the name of
Smiths was applied was found to the southwest of Tuckernuck Island, 37 miles east of its
position in 1846. These remarkable changes are exhibited in illustration No. 27, which
shows the position in 1846, 1856, 1887 and 1891.

In 1846 the south shore extended westward past the island of Tuckernuck, leaving a
waterway 250 metres wide between it and the island. In 1856 this waterway remained about
the same, but between 1856 and 1887 the storms wrought a great change in this locality.
The beach, which was a part of Nantucket Island and which protected the south shore of
Tuckernuck Island, had been beaten back on the island, filling up the water space existing in
1856. A new inlet had also broken through this beach at a point southeast from Tuckernuck,
which remained open at the last survey in 1891. The survey of 1891 shows an extension of old
Smiths Point beach to the westward as far as Muskeget Island since 1864, but under what
condition this growth took place has not been ascertained and may not be.

Marindin found that the annual loss of land on the south coast of Nantucket
for 45 years between 1846 and 1891 was 9 acres, and that the coast recedes
more rapidly in the stretch toward the west than in that toward the east because
of the protection given to the east end of the island by the Nantucket shoals.

Great Point, the northeastern extremity of the island of Nantucket, is a
large hook formed by the cutting back of the east coast of the island and the

1 St. John, J. Hector (Crevecoeur), Letters from an American ae p. 106, Philadelphia, March 4,
ee There is a London edition (8 vo.), 1782, and another (8 vo.), 1
The name of the town is given on this map as Sherburne. S was : olienged to Nantucket in 1795.
See Edward K. Godfrey, The Island of Nantucket, p. 284, Boston, 1882.
3 Marindin, Henry L., On the changes in the ocean shore lines of Nantucket a U.S. Coast and
Geodetic Sones Rept. for 1892, Appendix No. 6, p. 247, plate No. 27, reproduced her

108 CAPE COD GEOLOGY

long-shore drift of sand toward the entrance to Nantucket Sound. Professor
Henry Mitchell of the United States Coast Survey has shown by a comparison
of several surveys, dating from 1784, that this point had receded 1,400 feet by
the time of the survey of 1874.

The changes on the north shore of Nantucket have been less in recent years.
The sand flat built out in front of the old sea cliff known as Sherburn bluffs is
fairly ancient. The lighthouse at its east end, at Brant Point, was first erected
in 1746, but beacon lights were maintained there by the inhabitants as early as
1700.2

Before 1700 Copaum Pond, on the north coast, was a small port open to the
sea, and on its shore was made the second settlement on the island. A great
storm filled the entrance with sand, whereupon, in about 1720, the inhabitants
moved to the present site of Nantucket. A curious relic of the ancient play of
the tides in Copaum Pond may be seen in a small sandspit on its eastern shore.

Coatue Beach, whose remarkable cusps face the inner harbor, appears to
occupy a position determined by Coskata Island, a small tract of glacial deposits
just north by west of Haulover Break. The other beaches here mentioned derive
their sand from the longshore transportation of material derived from cliffs on
one or another side of them, but Coatue Beach appears to be composed, as
Gulliver has suggested,® of sand that has been carried along the east coast of
Nantucket around Great Point and then southwestward. Shaler * suggests that
part of the sand of Coatue Beach may have been derived from the bottom of
Nantucket Bay and that part of it may have been derived from Great Head.
Evidence that Coatue Beach once did not exist is found in an old sea cliff on the
west side of Coskata Island, where now a small lagoon is enclosed by beach sand.
Before the beach at Great Point or Coatue Beach had been formed, when the
sea bathed the base of Sherburne bluffs, the east coast of Nantucket, from Cos-
kata or Wauwinet southward, must have stood farther east, and the north
coast, from Coskata southwestward, must have lain west or southwest of the east-
ern headland. The beach at Great Point, which extends into the sound as a
wing thrown off from the present eastern headlands from Squam to Sankaty, is
probably working westward with the recession of the headlands upon which it
depends, and it and Haulover Break are probably marching inward with the
continued recession of their supporting headlands, and the breaches in the Haul-

1 Mitchell, Henry, Monomoy and its shoals, Mass. Harbor and Land Commissioners’ Report for the
year 1886, Public Document No. 11, p. 42, Boston, 1887.

2 Douglas-Lithgrow, R. A., Nantucket, a history, p. 279, New York and London, 1914.

3 Gulliver, F. B., Nantucket shore line, Bull. Geol. Soc. America, 15, pp. 521-522, 1904.

4 Shaler, N. S., Geology of Nantucket, U.S. Geol. Survey Bull. No. 53, p. 51, 1889.

:

CAPE COD GEOLOGY 109

over Break will doubtless be again repaired by the sea that made them in its
transportation of the waste that it has wrested from the cliffs.

Owing to the retreat of the south coast, the ponds there that lie in the beds
of glacial streams and that are held in by barrier beaches have been shortened
and must continue to decrease in length. The name Forked Pond, given to the
eastern member of this series of ponds, shows that within historic time it had a
branch, or branches, and resembled Hummock Pond, which lies farther west.
Of the Weeweeder ponds, now mere marshes, only the prongs remain. If we
compare the system of creases on the south shore of Nantucket with the system
on Marthas Vineyard we may infer that Nantucket has been cut back a mile or
more by the sea. The convergent group of creases in Nobadeer Pond and just
east of it would have had their confluence half a mile south of the present coast,
and if the Nobadeer crease and the Madequecham crease became confluent
they would have joined not less than a mile and a half south of the present coast.
Marindin, in the paper cited above, estimates the rate of recession of this coast
at 1.42 metres a year, which is equal to 1.42 kilometers (0.88 miles) in a thousand
years. The southward inclination of the surface of the outwash plain would
carry it below the level of the sea in the region west of Tom Nevers Head about
a mile south of its present position. If the land had been stable while this cutting
has been in progress this part of the island would have been cut back in 1,200
years, but the plain evidently turned southeastward at the place where Tom
Nevers Head now stands, and this part of it protected the western coast from
the strong southeast storms. Erosion was then probably slower, and the time
consumed by it was probably more than 1,200 years.

The ponds in the channels of glacial streams indicate submergence since
the streams ran across the plain, at the end of the first Wisconsin ice advance.
Peat and swamp material are found submerged at several places along the coast,
and are mentioned by Shaler.! Submerged stumps led him to believe that the
island had undergone a sinking, a positive deleveling, of 2 feet since the trees
grew, but this subsidence may have occurred many hundred years ago. The
old beach on the west side of Coskata, as Dr. J. Howard Wilson points out,
appears to have been but little depressed within the time it has taken Coatue
Beach to be formed in front of it, though the beach may have sunk two feet with-
out affording proof of a change of level. Aside from the evidence presented and
considered by Shaler I am not aware of any fact that would warrant the state-
ment that subsidence is now going on along the coast of the island.

1 Shaler, N. 8., Geology of Nantucket, pp. 28-30.

110 CAPE COD GEOLOGY

ARTIFICIAL CHANGES
CHANGES MADE BY WHITE MEN

The geological map of the densely built-over part of the town of Nantucket
is necessarily imperfect. Low, marshy ground that originally bordered the shore
of the harbor has been filled, and high ground has been leveled down. The
names of North and South Water Streets indicate that they were laid out along
the shore, the land east of them having been gained by filling in along and be-
yond the ancient beach. Gull Island, the site of the brick-clay pits referred
to in historical accounts, is not now an island. Everywhere glacial boulders have
disappeared. Wesko, the aboriginal name of the site of Sherburn, now Nan-
tucket, is said to mean ‘‘white stone,’”’ presumably a light-colored boulder that
stood on the site. The account given by the author of ‘“The Letters of an Am-
erican Farmer,” ! indicates that small boulders and ‘“‘stones” were never so
abundant on the morainal north side of the island as they still are on parts of
Marthas Vineyard and on the neighboring mainland. According to the writer of
these letters stones were brought from the mainland both for filling in about the
wharves and for building cellar walls.

INDIAN SHELL HEAPS

Some heaps of fragments of shells left by the aborigines are found along the
coast. Scant traces of these relics of the native inhabitants have been seen at
several places along the east coast, at the top of the glacial drift beds and
beneath a later coating of wind-blown sand. A deposit of shells covered by
peat was seen in the low cliffs at Squam Head.

In 1915 layers of shells were well exposed in the low bluff on the south side
of Coskata islet, at the north end of Haulover Break. The stratification in these
layers indicates a change in the species gathered, if not in the local geographic
conditions, while the shells were collected. The deposit begins on the east with
a zone about 2 inches thick made up entirely of shells of Venus mercenaria.
Upon this layer lie 2 to 3 inches of wind-blown sand, over which there is another
thin layer of shells, chiefly of Ostrea sp., and a few Venus mercenaria, all of
which is covered by old wind-blown sand and turf. A few feet west of this place
a layer of Venus mercenaria about 6 inches thick begins the record, upon which
lies a few shells of Ostrea. The whole deposit does not exceed 10 inches in thick-
ness and is covered by later wind-blown sand. The change from the clam (Venus
mercenaria) to the oyster (Ostrea sp.) is well marked in this deposit. The deposit

1 Crevecoeur, Hector St. John, The letters of an American farmer, pp. 97-98, Philadelphia, March 4,
1793.

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CAPE COD GEOLOGY 111

may not be more than a very few centuries old, but even two or three hundred
years ago the head of the harbor and the beach barring out the sea between
Coskata and the main island must have been several hundred feet east of their
present position, so that the shell heaps were laid down on the side of the present
harbor rather than at its extreme eastern corner, where Haulover Break now
joins Coskata islet. The erosion of the clayey till on the south side of Coskata
would have made the bottom of the harbor muddy and, therefore, favorable to
the growth of the clam (Venus mercenaria), and pebbles here and there would
have afforded seats for oysters. The addition of sand from the coast on the
ocean side as the head of the harbor moved westward would have in time changed
the character of the bottom off the point where the shell heaps are now found,
and the change from clam shells to oyster shells may mark this incident in the
history of the island.

In a small heap of shells at the top of the bluff at Squam Head, near Wau-
winet, I collected shells of Helix alternata, a species said to be extinct on the
island. The snail now living on the island (Helix hortensis) has been brought in
by Europeans. If Binney is right in saying that Helix alternata is not found near
the seacoast, the sea must have been much farther out when the shell heaps
were made and this species was living on Marthas Vineyard and Nantucket.
The land may have since been depressed in relation to the sea or erosion may
have brought the seashore to its present place. Both depression and erosion

may have occurred.

RELATION OF SHELL HEAPS OR KITCHEN MIDDENS TO DUNES
AND BLOWN-SAND TRACTS

All the small patches of Indian shell heaps or kitchen middens found in the
bluff along the coast crop out beneath layers of fine wind-blown sand. Thus it
appears that the coastal strip of wind-blown sand that surmounts the bluffs
on the eastern and northern sides of the island is more recent than the shell
heaps. This natural relation is a result of the retreat of the bluff and the blowing
up of fine sand to its top and a few yards inland. The occurrence of kitchen
middens beneath a layer of sand at the present coast line probably means that
the site of the shell heaps was not far from salt water and that the retreat of the
bluffs has not exceeded a few hundred feet. At some places, however, it may
have amounted to as much as half a mile, if the position of certain shell heaps on
Marthas Vineyard and Chappaquiddick Island are significant.

112 CAPE COD GEOLOGY
SAND-CARVED PEBBLES OR GLYPTOLITHS

At many places on Nantucket, particularly near the tops of the wind-swept
gravelly bluffs that face the harbor and at places west of Sherburn bluffs where
glacial pebbles and larger stones are exposed to a natural sand blast, hundreds
of pebbles and stones show faceted surfaces, some of which have intersecting
planes, forming so-called edged pebbles, or glyptoliths. Most of these pebbles
and stones display a high polish. The under sides of many of them have water-
worn or glaciated surfaces; the under sides of others are polished, proving that
they have been turned over since they were first exposed to the natural sand blast.
Some of these sand-polished pebbles are shown in Plate 12. These pebbles were
found in the course of a survey on bluffs where the wind was blowing up sand
and where sand carving is actively in progress. Figures showing some of these
sand-blasted pebbles are given in Shaler’s report on the geology of Nantucket,
where however, their polish is ascribed to the action of glacial streams. The
present accepted explanation of the. polish on these pebbles, which occur at
many places in glaciated regions of North America and Europe, was advanced
by Mickwitz as early as 1876, but it did not find acceptance in this country
until after Shaler’s report had been published.

TUCKERNUCK ISLAND

The geology of Tuckernuck Island duplicates in general that of Nantucket.
The northern part of the island is a remnant of the corrugated moraine of north-
ern Nantucket. A slight longitudinal valley that extends between Hast Pond
and North Pond separates the moraine from a tract of outwash plain on the
south, which forms the greater part of the area of the island. The fosse and the
ice contact slope at the head of the plain show that the ice front extended north
of west across the island to Chappaquiddick Island and Marthas Vineyard,

where similar features occur.

MUSKEGET ISLAND

Northwest of Tuckernuck Island, at the present west end of the group of
islands and shoals of which Nantucket is the largest mass of land, there is a low,
wind-swept island known as Muskeget. On a map made at the beginning of the
eighteenth century and accredited to Captain Southack the name ‘‘Sturgeon I.”
(island) is attached to an island west of what appears to represent Tuckernuck.
North of this island, on the south margin of a shoal having soundings of 3 feet,
the map has the name Muskeget Sand. This map confirms the geological prob-

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CAPE COD GEOLOGY 113

ability that Muskeget was once larger than it is now and that it was morainal
land analogous to Saul’s Hills on Nantucket and resembled the part of Nan-
tucket that lies along the line of the outer Wisconsin moraine, which stretched
lobewise from the east side of Marthas Vineyard southeastward over the site
of Muskeget and Tuckernuck Islands to and beyond Nantucket.

The geological mapping of Muskeget began with C. H. Hitchcock’s map
in the Massachusetts Atlas of 1871, where the islet is colored to indicate the
presence of ‘‘Drift and alluvium.” In the map in Shaler’s report on the geology
of Nantucket,! Muskeget is shown as a postglacial deposit but is not mentioned
in the text. Dr. Gerrit 8. Miller, who visited Muskeget in 1892 and 1893, writes:

Muskeget is about two miles long and at the widest part about half a mile across. It is
broadest at the east end, but toward the west it tapers gradually and irregularly, at the same
time bending into an imperfect and shallow crescent, the convexity of which is directed north,
toward Nantucket Sound. The southwestern end of the island extends as a slender tongue of
sand called South Point and is separated from Smith’s Beach by a narrow channel. South
Point is exposed to the full force of the tide and waves, and as a result is constantly changing
in form... . The island is, as Mr. Allen describes it, low and sandy — in fact, a mere dry
sand bar, nowhere rising more than fifteen feet above highwater mark. The surface is irregu-
larly ridged and furrowed, the general trend of the furrows being nearly east and west, or
parallel to the main axis of the island. Some of the deeper hollows contain small freshwater
ponds or marshes, and there is a salt marsh at the margin of the cove on the south side, but
the island is elsewhere perfectly dry and covered with coarse shifting sand. In spite of its
barrenness Muskeget has a varied flora, embracing most of the sand-loving plants found on
the coast of southern New England. *

Muskeget appears to be a wave-leveled remnant of the terminal moraine.
Its antiquity and its long separation from the neighboring islands is indicated
by its beach mouse (Microtus brewers Baird), an account of which is given by
Miller. This species, which is closely related to a field mouse that is widely
distributed on the mainland of New England, appears to have varied from the
parent type during its isolation on this island.

1 The geology of Nantucket, U. S. Geol. Survey, Bull. No. 53, 1889.
2 Miller, Gerrit S., The beach mouse of Muskeget Island, Proc. Boston Soc. Nat. Hist., 27, pp. 76-77.

114 CAPE COD GEOLOGY

BIBLIOGRAPHY OF THE GEOLOGY OF NANTUCKET}

17—. Macy, Zaccurus. Reports discovery of fossils on the island in a letter to the Massa-
chusetts Historical Society, vol. 17. Reprinted by E. K. Godfrey in The island of
Nantucket, Boston, 1882.

1833. Hircucock, Epwarp. Report on the geology, mineralogy, botany, and zodlogy of
Massachusetts, 700 pp., map, ills. (in atlas), Amherst. The map was also issued
separately in 1832.

1835, ------------ . Report on the geology, mineralogy, botany, and zodlogy of Massa-
chusetts, 2d ed., 702 pp., Amherst.
1888.5 . Report on a reexamination of the economical geology of Massachusetts:

House Document No. 52, 139 pp., Boston, State Printers.
Lists, on p. 121, 985 acres of peat on the island in beds ranging in thickness from 1
to 14 feet.

1841, ----------—- . Final report on the geology of Massachusetts; vol. 1, containing econom-
ical geology, scenographical geology, pp. 1-xii, 1-299, map, Amherst; vol. 2, con-
taining scientific geology, elementary geology, pp. 301-831, ills., map, Northampton.

%epeats former account of the scenery of Nantucket and includes a geological
map of the State colored to show that “diluvium”’ is the geological formation of that
island.

1844. Borpen, Simzon. Topographical map of Massachusetts. Includes geologic map, scale
5 mi. to 1 inch or 1:316800.

1844. Hrrencocx, Epwarp. Explanation of the geological map attached to the topographical
map of Massachusetts, 22 pp., Boston.

1848. Drsor, Epovarp. Drift fossils from Nantucket, Mass.: Proc. Boston Soc. Nat. Hist.,

3, pp. 79-80.
1849. ------------ . Deposit of drift shells in the cliffs of Sancati Island, or Nantucket:
Proc. Am. Assoc. Adv. Sci., 1, pp. 100-101
oe and Cazort, E. C. On the Tertiary and more recent deposits in the island ’

of Nantucket. In letter to Sir Charles Lyell, president of the Geological Society of
London: Quart. Jour. Geol. Soc. London (Proc.), pp. 340-344.
1863. Dana, J. D. Manual of geology, 798 pp., ills., map, Philadelphia.
1864, ------------ . Manual of geology, rev. ed., 800 pp., Philadelphia.
Refers the shell beds at Sankaty Head to the “Champlain epoch”’ (p. 551); gives
height of deposits above sea level as 30 feet.
1871. Hrrcncocx, C. H. Geological description [and geologic map| of Massachusetts. In
Walling & Gray, Official topographical atlas of Massachusetts, pp. 17-22, map.
1875. Dawa, J. D. Manual of geology, 2d ed., 828 pp., map, New York.
Refers the fossil shells at Sankaty Head to the “ Champlain epoch” (pp. 550-551),
states that the species lived in warm water, and appears to assume an elevation of the i
beds of 85 feet above sea level.
1875. ScuppEr, 5. H. Note on the post-Pliocene strata of Sankaty Head. In memoir by
A. E. Verrill (pp. 365-366), listed below. Reprinted by N. S. Shaler in Bull. U. S.
Geol. Survey, 53, pp. 32-33, 18389.
1875. Verritt, A. E. Gn the post-Pliocene fossils of Sankaty Head, Nantucket Island: Am.
Jour. Sci., 3d ser., 10, pp. 364-375.
1876. ScuppER, S. H. Post-Phocene fossils from the bluff at Sankaty Head, Nantucket: Proc.
Boston Soc. Nat. Hist., 18, pp. 182-185.

1 Includes some geographical papers.

CAPE COD GEOLOGY 115

1880. Dana, J. D. Manual of geology, 3d ed., 911 pp., ills., map, New York.

1882. Ewer, F. C. An essay towards accounting for the formation of Nantucket: Nantucket
Inquirer and Mirror, Dec. 24, 1881. Reprinted by E. K. Godfrey in The island of
Nantucket, pp. 48-57, Boston.

1882. Macy, Mrs. Anng Mircureti. The botany, conchology, and geology of Nantucket.
In E. K. Godfrey, The island of Nantucket, pp. 32-33.

1883. ScuppER, S. H. The pine moth of Nantucket (Retinia frustrata). Publications of the
Massachusetts Society for the Promotion of Agriculture, Boston, A. Williams and
Co.

1889. SHater, N.S. The geology of Nantucket: Bull. U.S. Geol. Survey, No. 53, 55 pp. Con-
tains colored geological map, plates, and ea im text.

1894. Marinprn, H. L. On the changes in the ocean shore lines of Nantucket Island, Massa-
chusetts, from a comparison of surveys made in the years 1846 to 1887 and in 1891:
U.S. Coast and Geodetic Survey Rept. for 1892, pt. 2, appendix No. 6, pp. 243, 253,

pls. 24-27.

1895. Dawa, J. D. Manual of geology, 4th ed., 1087 pp., New York.

1896. Hotiick, C. A. Geological notes, Long Island and Nantucket: Trans. New York
Acad. Sci., 15, pp. 3-10.

1896. ce F. J. H. Post-Pliocene deposits of Sankaty Head: Trans. New York Acad.

Seu, 1 10-16.
1896. MILLER, a =< The beach mouse of Muskeget Island: Proc. Boston Soc. Nat. Hist.,
27, pp. 75-87.

1896. Woopworrs, J. B. [Correlation of geological formations of Nantucket], in Shaler,
N. S., and others, The glacial brick clays of Rhode Island and southeastern Massa-
chusetts: U. S. Geol. Survey, Seventeenth Ann. Rept., pt. 1, chap. 2, Geology and
geography of the clays, pp. 975-988, with correlation table.

1899. Curtis, G. C., and Woopworts, J. B. Nantucket, a morainal island: Jour. Geology,
7, pp. 226-236. Contains halftone reproduction of a model of the island by Curtis

1899. Upnam, Warren. Glacial history of the New England islands, Cape Cod and Long
Island: Am. Geologist, 24, pp. 79-92.

1904. Cusuman, J. A. Notes on the Pleistocene fauna of Sankaty Head, Nantucket, Mass.:
Am. Geologist, 34, pp. 169-174.

1904. Gunurver, F. P. Nantucket shore lines: I, Bull. Geol. Soc. America, 14, pp. 555-556;
Il, 15, 507-522. Abstract in Science, new ser., 19, p. 531 and in Sci. Am. Suppl.,
57, p. 234-6.

1905. Cusuman, J. A. Notes on fossils obtained at Sankaty Head, Nantucket, in July, 1905:
Am. Geologist, 36, pp. 194-195

1905. Gututver, F. P. Island tying: Rept. Eighth Internat. Geog. Cong., pp. 146-149.

‘ 1905. Wirson, J. H. The Pleistocene formations of Sankaty Head, Nantucket: Jour. Geology,

13, pp. 713-734. (Doctorate thesis, Columbia University.) Abstract in Science, new
ser., 21, pp. 989-990.

1906. Cusuman, J. A. The Pleistocene deposits of Sankaty Head, Nantucket, and their
fossils: Nantucket Maria Mitchell Association, Pub. 1, No. 1, pp. 1-21

1906. Writson, J. H. The glacial history of Nantucket and Cape Cod, with an argument for
a fourth center of glacial dispersion in North America, 90 pp., New York, Columbia
University Press. Contains black-line geologic maps and figures; includes reprint of
paper of 1905. Abstract in Bull. Geol. Soc. America, 17, pp. 710-711 (1907); Annals,
New York Acad. Sci., 17, pp. 624-625 (1907) ; and Science, new ser., 23, p. 389 (1906).

116 CAPE COD GEOLOGY

1907. ----------—- . The Pleistocene beds of Sankaty Head, Nantucket (abstract): Annals,
New York Acad. Sci., 17, pp. 594-595.
1909. Guuuiver, F. P. Nantucket shore lines, III, IV: Bull. Geol. Soc., 20, p. 670.
Notes closing of breach in Haulover beach on November 12, 1908.
190 —~—™ . Wauwinet-Coscata tombolo, Nantucket, Mass.: Abstract in British
Assoc. Adv. Sci., Rept. 79, p. 536.

CAPE COD GEOLOGY 117

CHAPTER II
GEOLOGY OF MARTHAS VINEYARD

By Epwarp WIGGLESWORTH

GEOGRAPHY
GENERAL FEATURES

Marthas Vineyard is the second largest of the so-called New England
Islands, being exceeded in size only by Long Island. It is roughly triangular in
shape, with the apex of the triangle to the north, and its southern shore line
is remarkably straight. Its greatest length from east to west is 20 miles; its
length from north to south is about 9 miles; and its total area is about 96 square
miles. Chappaquiddick, at the east corner of the triangle, has been from time to
time cut off as an island. Gay Head, at the west corner, has probably long
been a part of the main island, with which it is connected by a more permanent
beach, behind which a small marsh has been formed.

Marthas Vineyard is separated from the ‘‘heel” of Cape Cod and from
the Elizabeth Islands by Vineyard Sound, which ranges in width from about
3 miles at the apex of the triangle to more than 5 miles at its west corner. The
shore of the island along Vineyard Sound consists of a series of headlands and
intervening lower stretches, which form irregular curves. Most of the head-
lands are steep cliffs, some of which are more than 100 feet high. The shore
between the cliffs is at some places only a low bank or a rather flat beach. Fresh-
ly cut parts of the cliffs show that the coast facing the sound is being pushed
back.

The eastward continuation of Vineyard Sound is known as Nantucket Sound.
The shore along this sound is a low beach except near the apex of the island and
on Chappaquiddick. Near the apex, between East Chop and Oak Bluffs, there
is a long bluff about 40 feet high, and on Chappaquiddick there are similar bluffs
at the entrance to Cape Poge Bay and the end of Cape Poge. Sengekontacket
Pond and Cape Poge Bay are lagoons formed by bars thrown up by the waves of
Nantucket Sound. Thus, although the headlands at East Chop and Cape Poge
are being cut back, the remainder of the shore has been built forward by the
formation of barrier beaches.

Marthas Vineyard is separated from Muskeget and Nantucket, which lie
more than 5 miles to the east, by Muskeget Channel. The east shore of Chappa-
quiddick consists entirely of a barrier beach, which is tied at its north end to

118 CAPE COD GEOLOGY

Cape Poge and at its south end to Wasque Point. Behind this beach lies a long
lagoon. The front of this beach is very straight and runs nearly due north and
south.
TOPOGRAPHIC Divisions

Marthas Vineyard may be divided into three topographic areas, as follows:

1. An area of hilly country, which occupies the western part of the island
and extends northward almost to its apex.

2. A northeastern area, which lies between West Chop and Chappaquiddick.

3. A great plain, which occupies the south-central part of the island.

—

Fig. 4.— Outline map of Marthas Vineyard showing the three topographic areas.

THE WESTERN AREA
The western area has by far the most varied and rugged surface found on
the island, consisting largely of boulder-strewn ridges that run roughly parallel
to the shore (Plate 15, fig. 1, and Plate 16, fig. 1). Topography of this type ex-
tends from the east side of Chappaquonsett Pond southwestward to Gay Head
and the southwest shore, along which there are steep cliffs. Gay Head is justly

[
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CAPE COD GEOLOGY 119

famous for its striking array of beds of bright-colored clay. (See Plate 14). The
ridges in this western area attain elevations of 300 feet. They are not continu-
ous throughout the area but are interrupted by small valleys and near the
southwest end of the island by two large ponds, which stand at sea level and
nearly separate the township of Gay Head from the rest of the island. In ad-
dition to these large ponds there are a few small ponds at higher levels. The
materials composing the other two areas of the island are too porous to hold
water on the surface, and this western area is therefore the only one of the three
that has a drainage system sufficiently well developed to form brooks.

THE NORTHEASTERN AREA

The northeastern area includes the north-central part of the island, a strip
along its northeast shore, and the greater part of Chappaquiddick Island. This
area is widest at its west end, where it includes the apex of the triangle that forms
Marthas Vineyard. It measures nearly 4 miles from north to south. Midway
between its extreme ends it is not more than half a mile wide. Its surface is
much less rugged than that of the western area and closely resembles that of
the north half of Nantucket. It includes no distinct ridges, and most of it
stands not more than 120 feet above sea level. This area is not continuous but
is interrupted by Vineyard Haven Harbor and Lagoon Pond, as well as by Ed-
gartown Harbor and Katama Bay, which cut off Chappaquiddick Island from
the rest of Marthas Vineyard.

THE GREAT PLAIN

A great plain makes up the remainder of the island. To the eye this ap-
pears to be a great level stretch interrupted only by the remarkable channels in
whose southern parts lie the large ponds that are so conspicuous on the topo-
graphic map. At its north edge this plain has an elevation of 100 feet, from
which it slopes southward at the rate of 20 feet to the mile until it reaches
sea level. Most of it is barren and uninhabited and is covered with scrub
oaks. (Plate 15, fig. 2).

NoTABLE TOPOGRAPHIC FEATURES
Ponds and bays are notable features of the topography. A deep reéntrant
is formed at the apex of the triangle by Vineyard Haven Harbor and Lagoon
Pond, which are now nearly separated by a narrow barrier beach, but which
once formed a continuous body of water that extended nearly 4 miles inland.

120 CAPE COD GEOLOGY

This reéntrant is probably a submerged valley formed before the last advance
of the ice. Two ponds of the same origin, though smaller, are Chappaquonsett
and James Ponds. Menemsha Pond, near the southwest corner of the triangle,
nearly separates Gay Head from the main island, and just south of Menemsha
Pond, beyond that part of the island known as Nashaquitsa, lies Squibnocket
Pond. The depressions in which these ponds lie are probably not due to absence
of Wisconsin morainal material but to depressions in the surface on which
the moraine was deposited. Both ponds would be large, open bays except for
barrier beaches, which entirely shut off Squibnocket Pond and would probably
shut off Menemsha Pond had not large jetties been built to keep the entrance
open. The larger bodies of water on the south shore include Chilmark Pond,
Tisbury Great Pond, Oyster Pond, Edgartown Great Pond, and Katama Bay.
All these bodies are in the great plain and all have characteristic shapes due to
the forms of the channelways in which they lie. With the exception of Katama
Bay all have long, narrow arms or branches called coves. On the northeast
shore the prominent bodies of water are Cape Poge Bay and Sengekontacket
Pond. These also owe their existence to barrier beaches.

If we attempt to restore the shore line of Marthas Vineyard before these
bays and ponds were formed by barrier beaches, we shall be struck at once by
the extreme irregularity of the island, in contrast with its present fairly simple
outline, yet such an irregular shore line must have existed at some earlier stage.

GEOLOGIC SIGNIFICANCE OF THE TOPOGRAPHY

There is a close relation between the form of the surface and the geologic
structure on Marthas Vineyard, but apart from the geologic sections exposed
in some of the cliffs there are few places on the island where anything but the
surface of the uppermost formation can be seen. At most places, therefore, the
nature of underlying beds must be inferred from the topography. The inferences
thus made will generally be trustworthy if two facts are borne in mind, namely
(1) that in the western area all pre-Wisconsin beds were pushed or dragged up
by the ice and form the foundation on which the true Wisconsin morainal ridges
rest; (2) that the Wisconsin deposits were laid down on a surface that had reached
maturity. Thus the morainal material does not consist entirely of Wisconsin
gravel, and not all the valleys can be attributed to the action of the last ice
advance and subsequent causes. The topographic evidence is locally of still
further value, for the nature and even the structure of the material at some
places furnishes no aid in the task of discriminating between one deposit and

CAPE COD GEOLOGY 121

another. The division of the island into the three areas here discriminated is
chiefly topographic, but each division is composed of essentially different geo-

logic deposits.
SALIENT GEOLOGIC FEATURES

Marthas Vineyard presents a wider range of geologic formations than any
one of the other islands considered in this report, or than Cape Cod, and is of
special geologic interest for three reasons: (1) It is underlain by Cretaceous and
Tertiary beds like those found on the Atlantic coastal plain, which are exposed
at several places and are not found farther north or east; (2) it is the only one
of these islands on which the Tertiary beds seen on the coast plain are manifestly
in contact with the overlying Pleistocene deposits; and (3) the Pleistocene series
is more nearly complete here than at any other place in New England and is

comparable with the series found on Long Island (see Plate 13.)

Marthas Vineyard is probably underlain everywhere by Upper Cretaceous
beds, but they are exposed only in the western half of the island. Upon these
beds, here and there, patches of Tertiary deposits are found. In the eastern
half of the island the deposits of both systems lie below sea level. Both the
Cretaceous and the Tertiary beds have been greatly deformed by the advances
of the ice sheets of the early part of the Pleistocene epoch, and the beds of both
systems are unconsolidated, consisting largely of clay, sand, and gravel. Uncon-
formably upon the Tertiary beds lie a remarkable series of Pleistocene deposits,
which are similar to those of Long Island. The lowest Pleistocene beds consist of
a basal conglomerate overlain by gravel and bouldery till and are only obscurely
exposed, but wherever seen they are distorted, along with the Cretaceous and
Tertiary beds, and they have obviously undergone long erosion since their de-
position. Upon these oldest Pleistocene beds lies a thick dark clay, which grades
upward into a fine sand. These beds are at the geologic horizon of the Gardiners
clay and the Jacob sand on Long Island and are much less disturbed than the
older beds, but they show considerable deformation. Upon these lies a series
of beds of sand and gravel separated by a thick bed of till. This series corre-
sponds exactly to the Manhasset formation on Long Island, and its deposition,
like that of the Manhasset, was followed by a long period of erosion before it
was covered with the Wisconsin glacial deposits. The Wisconsin deposits were
therefore laid down on a maturely dissected land surface and they attain con-
siderable thickness at only a few localities outside of the great plain. At many

places they are only 2 or 3 feet thick.

122 CAPE COD GEOLOGY

EFFECTS OF THE WISCONSIN ICE SHEET

The present form of Marthas Vineyard is due primarily to the action of
glaciers and glacial streams, and only secondarily to the later work of currents,
waves, and winds. Stream erosion since the retreat of the Wisconsin ice sheet
in this region has played only a small part in the development of the topography.
Stream erosion before the advent of this ice strongly influenced the form and

distribution of the Wisconsin deposits.
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oo

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Fig. 5.— Map showing position of the lobes of the Wisconsin ice sheet on Marthas Vineyard at the time of the farthest
advance of the ice.
Marthas Vineyard is a typical interlobate part of the terminal moraine and
represents the southern limit of the action of the Wisconsin ice in this region.
The ice covered at one time the two northern areas of the island but did not
extend to the great outwash plain, except perhaps temporarily to its northern
border. The presence of the ice in one part of the island and not in another

caused the difference in the topography of these parts. The advancing ice found
here no hard rock, but only the Cretaceous and later beds of clay, sand, and

CAPE COD GEOLOGY 123

gravel. It might, therefore, be expected that the ice would have completely de-
stroyed all the preéxisting topography, but it seems rather to have passed gently
over the surface without materially altering it, except that it deposited a rela-
tively small quantity of material in characteristic forms. (Plate 16, figs. 1 and 2).
Hence the topography is in two ways exceptional: because the ice passed over
only soft rocks and because its action was weak, whereas in other parts of New
England it seems to have been strong.

The southern margin of the Wisconsin ice sheet was made up of a series of
lobes! Only two of these lobes will be considered here. What may be called
the Buzzards Bay lobe extended over the site of Buzzards Bay reaching as far
south as the northwestern part of Marthas Vineyard. Its margin extended from
near Vineyard Haven southwestward nearly parallel to the shore and thence
to No Mans Land. The Cape Cod Bay lobe covered the site of Cape Cod and
what is now Nantucket Sound and reached the northeast shore of Marthas
Vineyard. Its margin extended from near Vineyard Haven, where it was in
contact with the Buzzards Bay lobe, southeastward toward Edgartown, across
Chappaquiddick to Tuckernuck and Nantucket.

North of the point where the margins of these lobes met there must have
been an interlobate line of slack ice. Along this line was deposited an interlobate
moraine (in this report called the Plymouth interlobate moraine), which is
weakly developed between Vineyard Haven and West Chop and was strongly
developed from Falmouth to Plymouth? at a later stage.

ForM OF THE ISLAND

During the first stage of the Wisconsin ice Marthas Vineyard occupied an
interlobate area between the Buzzards Bay lobe and the Cape Cod Bay lobe.
Its position at that time mainly determined its triangular form, which was de-
veloped in a reéntrant angle between these two lobes. The western and north-
eastern areas, however, were intraglacial, but the great plain was distinctly
extraglacial. The topography of the western area is due to the action of the
Buzzards Bay lobe on the preéxisting topography. The topography of the
northeastern area is due to the action of the Cape Cod Bay lobe. The great plain
was formed between these two lobes by the water that flowed from the melting

ice, largely that coming from the Cape Cod Bay lobe.

1 Chamberlin, T. C., Preliminary paper on the terminal moraine of the second glacial epoch, Third

Ann. Rept. U. S. Geol. Survey, pp. 291-402, 1883.
2 Upham, Warren, Terminal moraines of the North American ice sheet, Am. Jour. Sci., 3d ser., 18,

p. 204, 1879. (This paper contains the first reference to this interlobate moraine.

NW

124 CAPE COD GEOLOGY

INFLUENCE OF THE OLDER TOPOGRAPHY

The attitude and the elevation of the older beds determined to a considerable
extent the type of topography that was developed on them by normal stream
action during the interglacial period preceding the advance of the Wisconsin
ice. The surface of the low-lying plain and of the northeastern area, in both of
which the beds are but little or not at all disturbed, was not much altered by the
erosion, but the western area was considerably altered, for it stood high enough
to allow the streams to cut rather deeply and the structure of its beds controlled
to some extent the courses of the streams.

THE BUZZARDS BAY LOBE

The topography of the western area must be ascribed mainly to the action
of the Buzzards Bay lobe of the Wisconsin ice sheet. On reaching Marthas
Vineyard the ice encountered rather high elevations formed by deposits laid

SE

B

Fic. 6.—a. Generalized profile across the northeastern area and the great plain. b. Generalized profile across

the western area and the great plain. :

down by earlier glaciers on beds of clay and sand. On these beds the ice deposited
morainal ridges of gravel and a thin coating of till. The ice moved forward long
and in great volume, covering the high elevations and passing down on to the
plain, but it probably did not reach the limit of its advance until near the end of
this substage of the Wisconsin ice sheet. In the meantime it melted almost
rapidly enough to counteract its forward motion, and an immense quantity of

sand and gravel was washed out beyond its edge. As the ice melted, it deposited
as a sheet of till the part of its load that was not thus washed out, and this till

CAPE COD GEOLOGY 125
included the large boulders that it had brought from the mainland (Plate 17,
fig. 2). The quantity of material in the moraine thus formed was not large, and
at some places practically no material was deposited, so that pre-Wisconsin beds
are now found at the surface. The larger part of the deformation of these older
beds is due to earlier ice advances, and the fact that the pre-Wisconsin surface
can still be recognized suggests that the Wisconsin ice overrode that surface

without greatly disturbing it.
THE CAPE COD BAY LOBE

The topography and the surface deposits on the eastern half of Marthas
Vineyard, including Chappaquiddick Island, are products of the action of the
Cape Cod Bay lobe. They resemble in many ways those of Nantucket, although
their mode of development at some places was not so simple nor so clearly marked.
The eastern part of the island differs very strikingly from the western part.
Its topography is much less rugged and only a few of its elevations rise more than
a hundred feet above sea level. (Plate 17, fig. 1.) Its deposits consist almost
entirely of sand and gravel laid down by the Wisconsin ice sheet. The Cretaceous
and Tertiary strata are not exposed, and the pre-Wisconsin glacial deposits are
exposed only at some places.

The southern limit of the ice in this area is marked by a well-developed ice-
contact slope in the area south of Lagoon Pond. On Chappaquiddick Island this
slope is well defined at but two places, and for short distances only. Elsewhere
it can be traced only by the distribution of the boulders, for at many places
the topography north and south of the contact is much alike. A close study of
the surface, however, reveals a difference in the origin of the deposits. A poorly
developed ice contact extends along a line that runs northwestward for about
a mile and a quarter from a place near the shore at the south end of Poucha
Pond, at the southeastern extremity of Chappaquiddick. Boulders are found
along this line, the largest of them about 12 feet long. The lowland northeast
of this line represents the fosse; the higher land southwest of it is a narrow
fringe of outwash plain. This plain slopes toward Katama Bay and is cut by
several shallow creases. The ice contact is not clearly evident in the south-
central part of Chappaquiddick Island, but it can be traced by a line of boulders
that curves westward toward a small marsh south of Snow’s Point, where it

turns rather sharply to the northwest. The fosse also is lacking for some distance
here, but it reappears about half a mile east of the marsh. The outwash plain,
which is interrupted only by a few creases, extends as a fringe continuously

along the east side of Katama Bay.

126 CAPE COD GEOLOGY

On the opposite part of the main island, in a stretch extending northwest-
ward nearly to the south end of Lagoon Pond, a distance of 6 miles, the ice contact
can be traced by means of boulders. In this stretch there is a gradual transition
from stratified moraine to outwash plain.

The limit of the Cape Cod Bay lobe south of Lagoon Pond is marked by a
well-developed ice contact slope, which extends westward for about a mile and
then runs northwestward for about 24 miles. The fosse here is not wide but is
well marked. North of the fosse, on the west side of Lagoon Pond, and on its
east side as far as the north end of Sengekontacket Pond, there are the largest
areas of stratified moraine on the island. The outwash plain is well developed
south of the ice contact slope. Beginning abruptly at the crest of the slope it
stretches away far to the south, declining in altitude at an average rate of 15
to 20 feet to the mile. In this area the head of the plain reaches its highest ele-
vation, approximately 100 feet, about a mile and a half west of the head of Lagoon
Pond. The plain here appears to owe its origin largely to the Cape Cod Bay lobe
and not to the Buzzards Bay lobe, for nearly all its drainage lines except those
in its eastern part point toward this lobe. The drainage lines in the eastern part
of the plain, especially on the west side of Edgartown Great Pond, run south-
eastward, but they are not long, and those farther west do not cross the main

creases, which run southwestward.

MORAINES
STRATIFIED MORAINES
The moraines in the western area, which some geologists have called kame
moraines, are made of roughly stratified beds of sand and gravel that were de-
posited by water flowing from the melting ice. These moraines give this area
its characteristic aspect. Many of them are ridges whose long axes extend north-
eastward, but some are of irregular form. Such ridges are common in the

western area of Marthas Vineyard.

TILL MORAINES |
On Marthas Vineyard till moraines are much less common than stratified
moraines, but at many places the two kinds can be distinguished only by ex-
amining their internal structure. The till laid down by the Wisconsin ice is sandy
and contains very little clay. The till moraine is rounder in form; it nowhere
presents sharp cones and ridges. Typical till moraines are common in the Gay

Head region.
In the northeastern area the moraines formed by the Cape Cod Bay lobe

|
|
'

CAPE COD GEOLOGY 127

are distinctly different from those in the western area. They have no sharp ridges
and cones such as are seen in stratified deposits; they show the more subdued
forms of till moraines. The surface material is a sandy till containing no clay
and in places no pebbles. At a few places the ridges have a central core of older
till, upon which the later moraine was laid. The moraines on both sides of Lagoon
Pond occupy high ground and lie above the level of the outwash plain just south
of it; those farther east occupy much lower ground, and few of them are as
high as the adjacent plain.
KETTLES

Kettles are numerous in both the western and the northeastern areas, and
many of them are occupied by small ponds or swamps. Those in the till moraine
are relatively shallow and have gently sloping sides; those in the stratified mo-
raine are deeper, and many of them have steeper sides. The kettles of both
types are merely low undrained areas between ridges built up of material laid
down by the ice. Most of them are not ice-block holes, but depressions due
to the arrangement of the surrounding morainal ridges. Most of the kettles
in the till moraine have more regular outlines than those in the stratified moraine.

There are at least two kettle valleys on the island. One is on the west side
of Lagoon Pond and the other, which is larger and contains a series of ponds,
is the valley in which James Pond lies. This valley was probably formed by the
building up of a series of recessional moraines rather than by buried ice. The
chain of ponds, however, although it is not well shown on the topographic map,
suggests a kettle valley.
OLDER VALLEYS

Conspicuous elements of the physiography of the morainal areas of Marthas
Vineyard are the old valleys cut in the Manhasset deposits. Although these
valleys were cut in unconsolidated beds, most of their larger features were not
changed by the action of the Wisconsin ice sheet. They may be divided into two
groups: (1) the more maturely developed and larger, which run southwestward,
and (2) the more youthful, which are shorter and run at right angles to those
of the first set.

The first valley of group 1 to be considered here heads between Prospect
Hill and Peaked Hill, in the western area, and runs northeastward nearly parallel
to the shore as far as North Tisbury village, where the stream now occupying
th. The original valley probably extended farther northeast

it turns abruptly sou
but is now filled with outwash gravel. No single continuous stream occupies

128 CAPE COD GEOLOGY

shorter courses to the sea, and intercepted the older stream, diverting its water.
The second valley of group 1 here considered runs parallel to the first and in-
cludes the country along the Middle Road. It starts south of Peaked Hill and
is now occupied in its lower part by the Tiasquam River, west of West Tisbury.
This old valley is lost under the outwash in the same way as the other valley.

|
the whole valley, as the streams of group 2, working back from the coast, found
|
(

i

i

= js

Fia. 7.— Map showing location of pre-Wisconsin valleys on Marthas Vineyard.

Whether it once extended farther northeast, toward Lagoon Pond, or joined
the north valley cannot be told. The headwaters of this valley were inter-
cepted by a brook that flows into Chilmark Pond. There is a sharp elbow of

capture and a very considerable deepening of the original valley.

To this same group, and perhaps to the same drainage system, belong the
now submerged and glaciated valley of Lagoon Pond (Plate 18, fig. 1) and Vineyard
Haven Harbor. The upper parts of this old river course are now obliterated by
the outwash plain. The lower part has been much changed by glacial scour,
for its direction is nearly parallel to the movement of the ice of the Cape Cod
Bay lobe. Later wave action built a bar that nearly separates the lower part

CAPE COD GEOLOGY 129

into two portions. This valley looks large for the size of the island, but when
the possibility that two streams entered it from the western area is added to
the fact that it has been submerged, and the probability that glaciation widened
it, to say nothing of the results of wave work, it may reasonably be considered
the site of an ancient river. It must also be remembered that the Vineyard inter-
val was extremely long compared with the time that has elapsed since the
Wisconsin ice sheet disappeared.

The valleys of the second group are more numerous than those of the
first. Beginning on the southwest, we may say that the depression occupied
by Menemsha Pond was perhaps originally connected with a drainage system
that has since been submerged. In the higher ground on the northeast there
are two small brooks: Roaring Brook and Howland’s Brook. These have com-
paratively short and steep courses to the sea, and were once used for mill power.
There are several other smaller brooks between them and Paul Point. At James
Pond another old valley, which was described above as a kettle valley, extends
well back into the moraine. It is not now occupied by a stream, but it was
dammed by glacial deposits that hold the water in several small ponds.

Chappaquonsett Pond probably represents a valley that is now submerged
and glaciated in its lower part and obliterated by outwash gravel in its upper
part.

OUTWASH FEATURES
THE OUTWASH PLAIN

South of the two moraines lies a great triangular outwash plain formed by
gravel carried out from the melting ice of the Wisconsin glacier. Its northwest
side runs south-southwest, its northeast side runs southwest, and its south side
runs east and west and is virtually the south shore. That it is a true outwash
plain is shown by its relations to the terminal moraines, by the ice contact slopes
along its northern side, by its even, gentle slope, by the channels that traverse
it, and by the structure of the gravel that composes it.

ICHK CONTACTS
Ice-contact slopes are well displayed along the northern edge of the
outwash plain at a few places but elsewhere the plain merges into a morainal
surface or breaks down into stratified moraine. At places where the ice contact is
found there is a well-marked fosse containing no morainal features. At such
places the relations between the plain and the moraine are those shown in Fig-
ure 8a. Where there is no ice contact slope the relations are those shown in

Figure 8b.

130 CAPE COD GEOLOGY

1. About a mile north of West Tisbury post office the contact, which
is well marked for half a mile, extends northeast and southwest. The fosse lies
on the south side of North Tisbury Hill, and it contains several large boulders.
(Plate 18, fig. 2).

2. About a mile southwest of the head of Chappaquonsett Pond there is
an ice contact slope and fosse, which at its south end cannot be traced with
certainty but which extends to the head of the pond, where it becomes stronger
and presents the best example of this feature on the island. The slope is in places _

N
MORAINE s

1CE CONTACT
OUT WASH

N MORAINE

OUTWASH

B

Fig. 8.—a. Profile showing relation of bouldery moraine and outwash plain where there is a an ice-contact slope
and a fosse. 6. Profile showing relation of bouldery moraine and outwash plain where no ice-contact slope and
fosse exist.

more than 50 feet high and is clearly shown by the contours on the topographic
map. This contact is not at the edge of the great plain but was built by the
Buzzard’s Bay lobe at the edge of a local plain some distance north of the south-
ern limit of the Cape Cod Bay lobe.

3. The most extensive ice contact extends westward from a point about
half a mile south of the head of Lagoon Pond. It can be traced for more than
two miles, and it curves somewhat to the north as it approaches the state road.
It is a typical, clearly marked contact slope, and throughout its course it forms
the northern limit of the great plain. The fosse that accompanies it contains
in its deepest part a small pond known as Duart’s Pond. Unlike the two pre-
ceding contacts, this contact was made by the Cape Cod Bay lobe, and it is the

only one formed by this lobe on the main island.
4. On Chappaquiddick there are two short ice contact slopes formed by
the Cape Cod Bay lobe.

CAPE COD GEOLOGY 131

KETTLES

Kettles are not common in the outwash plain; indeed, with the exception
of two conspicuous examples, they may be said to be absent. One of these is
about a mile and a half due south of the head of Lagoon Pond, the other is about
two miles west of the first. Both are large and are shown on the topographic
map. One is near the house of the superintendent of the Massachusetts State
Game Reservation and is occupied by a small pond. It is the larger and deeper
of the two and is of very irregular outline. The other is fairly regular in outline
but is little more than a broad, shallow depression. These kettles were doubt-
less not formed by ice blocks, for they lie farther south than the probable

Ww E

B

Fia. 9.— a. Generalized profile of a channel or crease, showing the relative
steepness of the east and west bank. 6. Profile of Watcha Pond channel,
showing extreme difference in form of opposite slopes.

southern limit of the ice; though possibly the ice of early Wisconsin time may
have extended southward beyond that supposed limit, and all traces of it may
have been obliterated by the material laid down on the outwash plain when the
ice front occupied the position marked by the contact slope south of Lagoon
Pond. Or, more probably, they were once parts of the numerous channels
that were cut off from the present channel by local deposits of outwash ma-
terial. The last suggestion is supported by the facts that the large kettle on
the State Game Reservation is not far from the head of the deep Oyster Pond
Channel and that the other kettle is near the head of the former drainageway
to the head of Edgartown Great Pond.

132 CAPE COD GEOLOGY

CHANNELS

The numerous channels or creases on the outwash plain are among the
most conspicuous features of the island. Their form and distribution show that
they were once occupied by streams. They now contain no running water, but
their lower parts are occupied by ponds, which stand practically at sea level.
(Plate 19, fig. 1). These channels form a branching network that extends over
the greater part of the plain. The only part of it in which they are not found
extends along its northern margin. Some of the larger channels were evidently
master streams to which the smaller ones were tributaries. The bottoms of
these channels are fairly broad and flat and have an even grade from their. heads
down to the ponds. The banks of most of them are less than 20 feet high. The
east and the west banks of many of them differ greatly in steepness, the west
bank being almost invariably the steeper. This difference has been noted in
many of the large northward and southward-flowing streams of the world and
was long the subject of speculation. The work of G. K. Gilbert! and others
shows that it is possibly due to the deflection of the streams by the rotation of
the earth. When the forward motion of the Wisconsin ice was about balanced
by the melting, a large volume of water must have been poured over what is
now the outwash plain, sufficient to form streams that produced the now de-
serted channels and to carry material far from the melting ice. Most of these
channels, even those in the western part of the plain, with the exception of Tis-
bury Great Pond, point toward the area occupied by the Cape Cod Bay lobe,
indicating that most of the water was derived from the Cape Cod Bay lobe
and that this lobe was the last one to retreat from the region. The heads of
Edgartown Great Pond and Tisbury Great Pond alone suggest drainage from
the Buzzards Bay lobe.

SHORE FEATURES

Marthas Vineyard, being an island and being made of unconsolidated
material, has naturally many shore features that have been formed by the
action of the waves, currents, and tides since Pleistocene time. The action

1 Gilbert, G. K., The sufficiency of terrestrial rotation for the deflection of streams, Am. Jour. Sci.,
3d ser., 27, pp. 427-432, 1884. See also Lewis, E., Certain features of the valleys or watercourses of
southern Long Island, Am. Jour. Sci., 3d ser., 13, pp. 215-216, 1887.

For additional consideration of this question the reader is referred to the following articles:

n Baer, Karl E., Ueber ein allgemeines Gesetz in der Gestaltung der Flussbetten, Bull. Imp.
Acad. Sci., St. Petersburg, 2, pp. 218-250, 353-382, 1860.

Reclus, Elisée, The earth, pp. 372-377, New York, 1872, or 2, pp. 483-489, New York, 1871.

Bryson, John, The geological formation of Long Island, New York, with a description of the older
watercourses, New York, 1885

Cobb, Collier, Note on the deflective effect of the earth’s rotation as shown in streams, Elisha
Mitchell, Sci. Soc. Jour., pp. 26-32, 1893.

CAPE COD GEOLOGY 133

of these forces and of the wind have been both constructive and destructive,
but destruction has been and still is predominant, and the island is, therefore,
gradually being reduced in size.

CONSTRUCTIVE ACTION

The constructed forms are mainly barrier beaches, which are of different
types. The cliffs supply abundant material for building beaches. The largest
barrier beaches on the island are along the south shore. One continuous beach
stretches from Nashaquitsa cliffs, at the west end of the island, to Wasque
Point, the southernmost extremity of Chappaquiddick. The current along this
shore generally runs eastward, so that the openings in the beach migrate east-
ward. Much of the material of this beach, at least south of Chilmark and Tis-
bury Great Pond, is the waste of Nashaquitsa cliffs, and some is furnished
by. Squibnocket cliffs. The remainder is waste from the outwash plain. This
South Beach, as it is called, probably originated as an off-shore barrier beach
and was forced back by the waves until it encountered the land. It now ex-
tends in a practically straight line from Chilmark Pond eastward to the south
end of Chappaquiddick. The beach in front of the ponds does not bend in, and
the openings that are artificially cut through the beach each year are filled
within a few weeks. Natural openings have been made in this beach by the
waves, especially along the south side of Katama Bay. The records of the
United States Coast and Geodetic Survey! show openings at the west end of
Katama Bay, which work farther eastward from year to year until they reach
Wasque Point.

Another extensive barrier beach forms the east shore of Chappaquiddick
Island, connecting it with Cape Poge. Unlike the South Beach, this East Beach
is accompanied by dunes, especially along the east shore of Cape Poge Bay.
This beach is probably made of material derived from Cape Poge, where the
waves are actively cutting away material. No such cutting is in progress along
the south shore. The East Beach is also a barrier beach behind which lies
an almost continuous lagoon composed of Poucha Pond and Cape Poge Bay.

On the west side of Cape Poge there is a bar or spit that stretches south-
westward in a long curve. This spit, which is made from the waste of Cape

Poge, nearly shuts off Cape Poge Bay from the sea, almost converting it into

1 Whiting, H. L., Report of changes in the shoreline and beaches of Marthas Vineyard as derived from
comparisons of recent with former surveys, U. S. Coast and Geodetic Survey Report {or 1886, Appendix
No. 9, pp. 263-266, 1887, with map. Also, same author, Topographic 1esurveys on Marthas Vineyard,
[ete.], U. 8. Coast and Geodetic Survey Report for 1889, Appendix No. 14, pp. 459-460, 1890, with map.

134 CAPE COD GEOLOGY

a pond. Others of similar origin separate Sengekontacket Pond from the sea,
and cut off Lagoon Pond from Vineyard Haven Harbor.

At the west end of the island, on the north and southwest coasts of Gay
Head, there are two wide stretches of beach and dune. One extends from a
point about a mile east of Gay Head cliffs to the entrance of Menemsha Pond,
and its eastern part shuts off this pond from Vineyard Sound. The other extends
from the south end of Gay Head cliffs to Squibnocket and encloses Squibnocket

Pond. These beaches are being built forward, largely with material from the

Gay Head cliffs, and are accompanied by large dunes.

Barrier beaches or bars, some of which convert former bays into ponds,
are found along the shore of Vineyard Sound, especially where valleys come down
to the coast. Such are the bars in front of Chappaquonsett and James ponds.

DESTRUCTIVE ACTION

Most of the forms produced by the destructive action of the waves are sea
cliffs. A large part of the shore on the two northern sides of Marthas Vineyard
consists of headlands that end in cliffs, between which lie stretches of beach.
As these cliffs are composed of unconsolidated material, and as many of them
are exposed to the action of strong waves, their appearance is considerably
altered from year to year. The two largest and most striking cliffs are the
Gay Head cliffs and the Nashaquitsa cliffs. Lesser cliffs are seen near Roaring
Brook and at Cape Higgon, Norton Point, East Chop, Stonewall Beach, and
Squibnocket.

The Gay Head cliffs, long famous for their vivid colors, are about three-
quarters of a mile long and are 140 feet high at their highest point. They con-
sist of Cretaceous clay and some Miocene and Pleistocene beds, all much folded.
The material and the structure have determined in large part the picturesque
forms into which they have been cut by erosion. (See Plate 14). The more
resistant beds of clay form small headlands; the less resistant beds have been
cut back and form recesses, such as the Devil’s Den. Landslides have deter-

mined some of the forms, although most of these are, in turn, caused by the
undermining action of the waves at the base of the cliffs. The colors are due
in part to the original materials in the beds and in part to the weathering of
these materials, especially those containing iron oxides. All the colors have
‘‘run” more or less, for the rain washes down from the upper beds material
that coats the lower ones. The Gay Head cliffs evidently once extended farther
northwest, for the sea has long been cutting them back southeastward. The

CAPE COD GEOLOGY 135

first lighthouse on Gay Head had to be replaced by the present one in 1858,
for the encroachment of the sea made it no longer safe. A shoal extends north-
westward into the sound from the cliffs. This shoal is not made of shifting
sand but is underlain by the same material that forms the cliffs. On this shoal
there are many large boulders, such as cover the surface of Gay Head and are
seen in some of the Pleistocene deposits. These boulders were probably too
large for the waves to remove at the time the sand and gravel originally asso-
ciated with them were removed and were left as monuments marking the former
extent of these deposits. The name “Devil’s Bridge” has been given to this
boulder-strewn shoal.

The Nashaquitsa cliffs, although not so strikingly colored as the Gay
Head cliffs, except in small patches at their east end, are very picturesque.
(Plate 20, fig. 1). They are considerably longer, being two miles in length, and
they are somewhat higher in their highest part. Their lack of the vivid colors
of Gay Head cliffs is due to the absence of the Cretaceous clay and the abun-
dance of glacial gravel and clay. The clay found here is the blue-gray Pleistocene
clay. These cliffs begin at a small point at the east end of Stone Wall Beach
and rise abruptly to a height of 150 feet. The cliffs remain fairly high for about
three-quarters of a mile and then fall to a height of about 50 feet. From that
height, with some variations, they slope down to a height of about 20 feet
at their east end. These cliffs are also being cut back rapidly. According to an
estimate made by the United States Coast and Geodetic Survey! in 1853 they
are being cut back about 3 feet a year.

Of the cliffs along the northwest coast east of Gay Head, those north of
Prospect Hill are the most conspicuous. They are about 120 feet high and are
composed largely of beds of loose gravel and, at the base, of some Cretaceous
beds and glacial clay. The differences in the character of these beds causes
differences in the forms produced by the erosion of the cliffs, the Cretaceous
beds eroding in ridges and gullies, with an occasional pinnacle; the beds of
gravel eroding in smooth slopes at the angle of repose; and the beds of glacial
clay forming vertical walls. These different materials also give different colors
to the cliffs, among them notably the white of the Cretaceous beds and the
blue-gray of the glacial clay. At Cape Higgon and Norton Point there are
cliffs about 80 feet high, composed largely of beds of loose gravel, which are
continually creeping down as the waves attack them at the base.

1 Rept. Supt. Coast and Geodetic Survey for 1853, p. 30, 1854. Statement by Assistant H. L. Whiting.

136 CAPE COD GEOLOGY

LANDSLIDES
At several places in the cliffs there may have been small landslides, which
have involved beds of clay, probably when wet. The attitude of a bed may
determine its stability; a bed in one position is more likely to slip than a bed
in another. (Plate 20, fig. 2.)

STRATIGRAPHIC GEOLOGY
INTRODUCTION
OUTSTANDING GEOLOGIC FEATURES AND OBSTACLES TO
GEOLOGIC WORK
NATURE OF THE DEPOSITS
The deposits on Marthas Vineyard are unconsolidated beds laid down in
late geological time. At many places they are greatly distorted, and they cover
and hide all older Pleistocene beds. For this reason the boundaries of forma-
tions cannot everywhere be determined accurately, and at some places they

have been drawn where the relief changes.

THE TOPOGRAPHIC MAP
The topographic base map used was made in 1887, when it was not con-
sidered necessary to represent the features in as great detail as is now essential
for detailed geologic work. At many places the contouring was so greatly
generalized that the character of the surface is entirely lost. Furthermore,
the map is in some respects inaccurate. During the forty years that have elapsed
since the map was made, there have been many changes, some due to natural

causes, and some due to the work of man.

THE WISCONSIN DRIFT

The sheet of Wisconsin drift mantles all older deposits. In the morainal
areas it is usually a sandy till, which at some places is as much as 6 feet thick.
In the great plain it consists entirely of a thicker covering of outwash gravel.
In the till-covered area the drift has only in part obliterated the older surface.
In the outwash plain it has completely buried the older surface. The task of
determining the location and character of the older beds in the morainal areas
is therefore difficult, and in the outwash area it is at most places nearly or

quite impossible,

CAPE COD GEOLOGY 137

SECTIONS IN THE CLIFFS

The cliffs afford the best sections on the island. Many of them have been
almost continuously cut back by the waves and show the deposits well, except
where the nature of the material causes it to slide down. The structure of a cliff
as worked out one year may not be the same in later years. Many of the cliffs,
especially those in which the retreat is rapid and the dip is high, change so
greatly from one year to another, both as to contour and as to the beds ex-
posed, that none of the features first seen can be found again.

SECTIONS IN THE INTERIOR

The older deposits are exposed at but few places in the interior of the
island, and they show their character and structure only in fresh and fairly large
exposures. The exposures consist of sand and gravel pits, a few road cuts, and
pits from which clay was dug many years ago. As sand and gravel can be ob-
tained almost anywhere on the island and are-not much used, the pits from
which they have been taken are small. A few cuts along the state road expose
the later deposits. The old clay pits in the western morainal area help the geo-
logist to trace the distribution of the Cretaceous beds, but they are usually filled
with water, so that only the material in the dump indicates what is under-
ground.

LITHOLOGICAL SIMILARITY OF THE PLEISTOCENE DEPOSITS

The lithological similarity of the Pleistocene beds is particularly marked in
the waterlaid deposits of the Manhasset formation and in the Wisconsin de-
posits. These have about the same size of grain and are apparently composed
of much the same material. The upper and the lower members of the Man-
hasset formation could not be told apart were it not for the bed of till (Mon-
tauk till member) that separates them, nor could these two beds of Manhasset
gravel be distinguished from the outwash gravel of the Wisconsin stage except
by considering the difference in their distribution. The Wisconsin till, although
it is usually much sandier than the till member of the Manhasset, is at some
places so nearly like the Manhasset till that it can be distinguished only by
its position and by the fact that it is separated from the Montauk till by a
bed of gravel. Where this older till contains few pebbles and is made up chiefly
of reworked Gardiners clay it so closely resembles the Gardiners that it can

be identified only by its position. It is not possible to distinguish the various
Pleistocene deposits by differences in the amount of weathering.

138 CAPE COD GEOLOGY

LACK OF BORINGS

Well borings have been found at only two places on the island. A group
of wash borings were made in the Upper Cretaceous beds near Prospect Hill
to find white kaolin sand. The records of these borings were not of much assis-
tance, especially as they were made in an area where the lower beds of the
moraine have been greatly folded and probably overthrust. Borings were made
near Norton Point by the Clay Products Company. The records of these bor-
ings show the presence of Cretaceous beds, but they are of no value to the
geologist, for the notes showing exactly where the borings were made cannot
now be found. Since the field work for this report was completed, a deep well
has been sunk just east of Vineyard Haven, at the head of the harbor. This
well had reached a depth of 160 feet, but no ‘record of it is available except

that it encountered no hard rock.

NATURE AND AGE OF THE PRE-PLEISTOCENE DEPOSITS

The Cretaceous and Tertiary deposits constitute all the pre-Pleistocene
formations found on Marthas Vineyard. They are all unconsolidated, but
otherwise they vary considerably in character. These older deposits are ex-
posed only at Gay Head and at a few places in the western morainal area, both
along the shore and inland. The beds seen are much folded and overthrust.
The Cretaceous deposits comprise variegated clays and arkosic sand in which
the feldspar has been altered to kaolin. According to Berry! these Cretaceous
beds belong to the lower part of the Upper Cretaceous system. The Tertiary
deposits are much less extensive and have been clearly recognized only in the
Gay Head cliffs. They have been usually described as osseous conglomerate
(a semi-consolidated quartzose conglomerate containing numerous cetacean
bones) and greensand, though they possibly include some other sand. These
beds have been much folded and overthrust and are separated from the over-
lying Pleistocene beds by a marked unconformity. The fossils in the sand
show that it is almost entirely Miocene, though it includes some Pliocene patches.
The osseous conglomerate, however, is now regarded as of early Pleistocene age.
No Eocene or Oligocene deposit has been found, except possibly a few fossilifer-
ous fragments in the glacial drift on Chappaquiddick Island.

The Cretaceous and Tertiary deposits are of interest because they are

the most northerly and easterly known remnants of the beds of those ages in the

Berry, E. W., The age of the Cretaceous flora of southern New York and New England: Jour.
Geol., 20, pp. 608-618, 1915.

CAPE COD GEOLOGY 139

Atlantic coastal plain except a small amount of Miocene greensand at Marsh-
field, Massachusetts, and a small bed on the Elizabeth Islands. These beds
were probably once continuous with those of the same age on Long Island
and in New Jersey.

NATURE AND AGE OF THE PLEISTOCENE DEPOSITS

The Pleistocene beds form by far the greater part of the formations exposed
on Marthas Vineyard. With the exception of some cemented patches of gravel
these beds also are unconsolidated. They differ considerably in lithologic char-
acter, consisting of sand, gravel, till, and clay. They differ from the pre-Pleis-
tocene deposits in containing unaltered feldspar. The pre-Wisconsin beds are
exposed only in the western morainal area and are best displayed in the sections
along the shore. The oldest Pleistocene beds are greatly folded and distorted;
the later ones are much less so. The Manhasset beds are but slightly folded.

These deposits range in age from early Pleistocene to Wisconsin. At times
deposition ceased and interglacial stream erosion was established. The deposits
are mostly of glacial or glacio-aqueous origin, and afford evidence of four dis-
tinct advances and retreats of the ice. They cannot be certainly correlated
with those of the Mississippi Valley or those of Europe, but the beds on Long
Island! have been tentatively correlated with those on Marthas Vineyard.

The Pleistocene series of beds makes up the greater part of Marthas Vine-
yard, where it is more nearly complete than it is anywhere else in New England.
Together with Cape Cod, Nantucket, No Mans Land, and the Elizabeth Islands,
it is the only region, except a few small areas farther north, where the older
Pleistocene beds are well shown. Furthermore, Marthas Vineyard has the
finest exposures and the most complete series. This island, with Nantucket,
also marks the southernmost stand of the Wisconsin ice sheet. It exhibits
features of the terminal moraine not found elsewhere in New England, such
as the interlobate character of the moraines and outwash and the effects of the
overriding ice on older unconsolidated material.

PROBABLE NATURE AND DEPTH OF THE PRE-CRETACEOUS BASEMENT

The nature of the rocks composing the basement on which the beds of
Martha’s Vineyard rest can only be inferred from what is known of the geology
of the southeastern mainland of Massachusetts. This basement probably
contains no rocks later than Carboniferous, but it may possibly include some

1 Fuller, M. L., The geology of Long Island, New York, U. 8. Geol. Survey Prof. Paper 82, p. 220,
4,

140 CAPE COD GEOLOGY

earlier Paleozoic rocks, which may be accompanied by intrusive rocks. These
Paleozoic rocks are probably beds of more or less metamorphosed conglomerate,
sandstone, and shale. The surface of the basement series was probably pene-
planed during Cretaceous time. The depth at which this basement series lies
is also unknown and can only be roughly inferred. By calculating the average
slope of the hard rock surface from northern Rhode Island to the northwest
shore of Buzzard’s Bay and projecting this to Marthas Vineyard we get a
depth of 500 to 600 feet. Only deep borings can give the depth accurately.

CRETACEOUS SYSTEM
NAMES OF THE BEDS
No geologic name has been proposed for the series of Cretaceous beds
exposed on Marthas Vineyard, but locally and commercially a part of the
series has been called the “Gay Head clays.’’ Shaler applied the term “ Vine-
yard series’ to the greater part of these beds and to the associated Tertiary
beds, but he thought the whole series was of Tertiary age. Ward called them
the ‘Island series,” but this term has not been used by later writers.

SUBDIVISIONS

The beds of Cretaceous clay are so greatly folded and overthrust at the
only place where they are well exposed that their subdivisions and relations
cannot easily be determined. A paper by Shaler!, published in 1890, con-
tains a section of the Gay Head cliffs prepared by Woodworth, in which the
following beds are assigned to the Cretaceous system: (1) lignite beds; (2)
noduled clays and leaf beds; (3) white micaceous sand and clay. In a later
paper Woodworth? describes all three of these beds as ‘‘non-marine lignitic and
leaf-bearing clays,’ and added ‘‘marine sands and clays of Upper Cretaceous
age.’ These beds of sand and clay were not clearly exposed at Gay Head,
but numerous fragments of a micaceous hematitic sandstone containing Creta-
ceous fossils had been found at Indian Hill, 10 miles to the northwest.

Fuller® gives a more complete columnar section of the Cretaceous on Long
Island but adds that the deposits “differ extremely in composition within short
distances.”’ Similar differences would probably be found:on Marthas Vineyard

1 Shaler, N.S., Tertiary and Cretaceous deposits of eastern Massachusetts, Bull. Geol. Soc. America,
1, pp. 443-452, 1890.

2 Woodworth, J. B., Unconformities of Marthas Vineyard and of Block Island, Bull. Geol. Soc.
America, 8, pp. 197-212, 1897.

3 Fuller, M. L., Geology of Long Island, New York, U. 8. Geol. Survey Prof. Paper 82, p. 67, 1914.

ft

CAPE COD GEOLOGY 141

were there more good exposures, but no further subdivisions can now be given
than those observed by Woodworth at Gay Head, namely:

Marine sand and clay ‘‘of Upper Cretaceous age.”

White micaceous sand and clay.

Noduled clay and leaf beds.

Lignite beds.

— Yo

The thickness of the plant-bearing beds in the Gay Head section must be taken with
due allowance for thinning and thickening in close folds and for overthrusts, as well as for
the probable occurrence of the marine Cretaceous at the summit of the pre-Tertiary series.
One hundred and fifty feet is probably in excess for the beds exposed above sea level.!
This estimate includes only the contorted beds exposed in the Gay Head cliffs,
beneath which, according to the estimate of the depth of bed rock, there are
500 or 600 feet more of undisturbed beds.

CHARACTER OF THE DEPOSITS

The Cretaceous deposits are unconsolidated and consist largely of clay,
the largest constituent of which is kaolin. They vary slightly in composition
and greatly in color. The colors are due largely to the weathering of forms of
iron and other extraneous material in the clay. Many beds of red and brownish
clay would be bluish gray or light gray if unweathered. Some beds that con-
tain mareasite have assumed, on weathering, a bright yellow color, due to a
coating of alum. Some beds of the purer clay are almost white; some beds of
the impure clay, such as the lignitic beds, are black. All the beds of lignite
contain clay, but parts of some of them consist of fairly pure lignite. The exten-
sive white beds seen at Gay Head and elsewhere are composed of grains of
kaolin and quartz and scales of muscovite, a mixture suggesting transported
arkose in which the feldspar has been altered to kaolin and muscovite.

All the deposits, and even the fossil plants, are very similar to those of

the Cretaceous age in New Jersey.

SOURCE OF MATERIALS
The nature of the materials composing the Cretaceous deposits on Marthas
Vineyard makes it possible to form a picture of the conditions there when they
were laid down and to determine, at least tentatively, the area from which
the materials were brought.
The lowest Cretaceous subdivision except a small amount of lignite is nearly

1 Woodworth, J. B., Unconformities of Marthas Vineyard and of Block Island, Bull. Geol. Soe.
America, 8, p. 200, 1897.

142 CAPE COD GEOLOGY

all clay, some of which carries fossil leaves. This material must have come
from a land surface that was being elevated and subjected to erosion after a
long period of atmospheric weathering as a peneplain. The great quantity of
clay deposited must have been derived from feldspathic rock, such as granite
and other igneous rock, or from feldspathic sandstone or shale. If it was de-
rived from sandstone or shale the period of weathering was shorter. It might
even have been eroded from these rocks without weathering and later altered
to clay. If the materials are considered in connection with those of the next
higher deposits, it would seem that the weathering preceded the erosion, and
that they were not removed at once, as the gradient was too low to permit
their rapid transportation.

The beds of kaolin-mica sand represent a continuation of the conditions
and processes favorable to the deposition of clay. They indicate that the relative
elevation of the land was rather rapid, so that the remaining products of alter-
ation were swept away quickly and laid down as cross-bedded deposits in
shallow water. The presence of quartz grains shows that the region under-
going erosion was originally composed of granitic rock. Such a region—that
is, one composed largely of granite that had been long subjected to weather-
ing and was being reduced to a peneplain—is found in New England to the
north and west of Marthas Vineyard. As to the origin of the lignite, however,
which forms the lowest Cretaceous beds exposed, two theories may be ad-
vanced. The first is that they were formed in large fresh-water or brackish-
water swamps from vegetation that grew and died and accumulated, without
much decay, to considerable depths in the places where they now lie. To this
vegetable matter a small amount of fine inorganic material was added by streams.
The second theory advanced to explain the origin of the lignite is that the
material now compositing it grew elsewhere and was brought to its present
site by streams and deposited in lagoons. Both theories have supporters, but
the first is favored here, although the beds contain no tree trunks or other like
forms such as we should expect to find if the lignite had been formed where
it is found, and all the fragments are considerably waterworn. Those who
adopt the second theory must hold that the lignite was brought to its present

site by lowland sluggish streams; otherwise more inorganic material would have
been brought in and mixed with the vegetable matter. The lignite must have
been deposited in large swamps or shallow lagoons in which organic material
collected, together with a small quantity of fine silt, which formed clay.

‘
t

CAPE COD GEOLOGY 143
2 RELATION OF THE CRETACEOUS TO OLDER DEPOSITS
| The contact between the Cretaceous and the basement rocks is nowhere
seen on Marthas Vineyard, and the relations between the two must be inferred
from their relations at other places. The lowest Cretaceous deposit doubtless
lies almost undisturbed upon the eroded surface of older rocks; it has probably
not been dislocated by the shove and drag of the Pleistocene ice sheets. In other
words, the lower Cretaceous beds lie on the older rocks here just as they do in
the coastal plain to the south, although the Upper Cretaceous beds have been
more or less disturbed by the action of the ice.

STRUCTURE

The structure of the Cretaceous beds is well disclosed only at Gay Head,
but traces of similar structure may be seen throughout the western area. At
Gay Head (Plate 19, fig. 2), where the details of the structure have been care-
fully worked out by Woodworth,! the beds lie in a series of closely folded anti-
clines and synclines and are strongly overthrown to the southwest. The beds
have not only been folded but have been overthrust, so that the structure is
very complicated, as shown in Figure 10. At and near Gay Head the dip of the
beds is fairly high, averaging over 45°, and is almost uniformly to the northeast.
In the region between Menemsha Pond and Chappaquonsett Pond the dip is
not easily determined, but the strike is always northeast, so that the general
dip is probably northwest. In this region the dip appears to be very steep, but

in the eastern part of the island it is generally slight.

The Upper Cretaceous beds seem to have been deformed by the thrust and
drag of the earlier ice advances. The idea that glacial thrust was competent
to deform them was first suggested by F. J. H. Merrill? in 1886, and is now
generally adopted instead of the mountain-building theory advocated by Shaler.
Merrill thought that the high elevation of some of the ridges of the terminal
moraine on Long Island could be accounted for only by supposing that some
of the underlying older beds had been raised to their present positions by glacial
action. These older beds are thrown into a series of folds, which run at a right
angle to the line of glacial advance. Hollick*® held the same view in regard to
the structure of these beds and has summed up his reasons for holding it as follows:

1 Woodworth, J. B., Unconformities of Marthas Vineyard and of Block Island: Geol. Soc. Am.
f Bull, 8, ay ae 1897.

2 Mer 1, F. J. H., On the geology of Long Island, Ann. New York Acad. Sci., 3, pp. 341-364, 1886.

3 ee nae Dislocations in certain portions of the Atlantic coustal plain strata and their
probable causes, Trans. New York Acad. Sci., 14, pp. 8-20, 1895.

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Fig. 10.— Cross section of Gay Head Cliffs showing geological structure. (After J. B. Woodworth.)

A, Upper Cretaceous clay, sand, and gravel; B, Miocene greensand and Pliocene beds; C, older Pleistocene deposits, including, in ascending order, Aquinnah
(osseous) conglomerate, Dukes boulder bed, stony blue clay, and gravel bed, the last two correlated with the Manetto formation; D thrust planes and faults.

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sora SSRN

CAPE COD GEOLOGY 145

(1) The line of disturbance is coincident with the line of the terminal moraine
from Nantucket to northern New Jersey; (2) the beds are folded and crumpled
only where the moraine has advanced over some part of the coastal plain;
(3) folding and crumpling cease abruptly where the moraine bends away from
or leaves the plain. To these reasons may now be added another: deep borings
on Long Island show that the beds below those that are folded are much less
disturbed. The chief obstacle seen by Shaler to the theory of ice folding was
the fact that the pre-Wisconsin surface, formed during the Vineyard interval,
was very little disturbed by the Wisconsin ice. Shaler thought that if the
ice could override the region without altering the surface, it was hardly possible
that it would compress the underlying beds into close folds. The fact that
there had been earlier and more vigorous ice advances before the Wisconsin

stage was then not clearly recognized.

CONDITIONS DURING DEPOSITION

The conditions that prevailed on Marthas Vineyard while the Cretaceous
deposits were being laid down, as shown by the character of the successive
beds, indicate progressive subsidence and the formation of land wash. Early
in Upper Cretaceous time the land that stood on the site of the island was low
and poorly drained and contained fresh-water swamps. Plants grew in and
around these swamps and their remains formed most of the material deposited.
As time went on, more clay was brought in, probably because of differential
tilting of the land, which increased the gradient of the streams that ran into
the areas of deposition. The land was doubtless sinking, for in the later de-
posits signs of vegetation gradually became scarcer, and then only horizontal
layers of clay containing a few leaves were laid down, the deposits indicating
an increasing distance from the area of erosion. At this time the streams must
have been made very turbid by the material they brought in, evidently from
a region that had long lain at a low level and that had been subject to atmos-
pheric weathering. Gradually the land must have stopped sinking and the areas
of deposition must have become increasingly shallower, for the succeeding
deposits show cross-bedding. The erosion of the land was accelerated, for the
deposits became coarser, and grains of quartz and flakes of mica were mixed
with the clay. Finally parts of the region must have subsided and have been
invaded by the sea, for the deposits contain marine fossils. The record of Cre-
taceous time on the island is incomplete; it includes, perhaps, not much more

than the first half of Upper Cretaceous time.

146 CAPE COD GEOLOGY

DISTRIBUTION

Most of the Cretaceous beds are found in the western morainal area. From
Gay Head northeastward nearly to North Tisbury beds of Cretaceous clay
are exposed at many places, especially along the valley traversed by the North
Road. Some Cretaceous beds are exposed north of this valley, in the Indian
Hill region, beyond which none are seen except at a place near Norton Point,
where a large clay pit reveals them again. In nearly all this western area they
are covered by Pleistocene deposits. Cretaceous beds are not found above sea

level east of Chappaquonsett Pond.

GAY HEAD

As has already been noted, the largest exposures of beds of Cretaceous clay
are in the Gay Head cliffs (Plate 19, fig. 2), where they may be seen in a section
over a mile long. Here may be found the whole series so far as it is known,
beginning with the beds of lignite, upon which lie the beds of clay and white
kaolin sand. The section has been gullied considerably and presents much the
same form as a cliff in a badland region. The colors of the beds here are strik-
ingly brilliant. Upon the Upper Cretaceous clay lie the Miocene greensand and
some Pliocene sand, which is in turn overlain by Pleistocene deposits. The
thickness of the Cretaceous beds exposed here is exceedingly difficult to estimate
on account of complicated folding and overthrusting, but it probably nowhere
exceeds 100 feet.

CLAY PIT NEAR MENEMSHA POND

The nearest good exposure of Cretaceous beds east of the Gay Head cliffs
is in an old clay pit half a mile west of the northwest corner of Menemsha Pond.
This pit, one of the largest on the island exposes white kaolin sand and some red
clay. The sand is overlain by the Montauk till. The red clay, which flanks the
white sand on the northeast, lies below the Montauk till, as if it had been
dragged up by the ice. The white sand exposed in this pit forms a bed about
20 feet thick. It is cross-bedded and very gently warped into an anticline

having an axis extending east and west.

MENEMSHA CREEK
About a quarter of a mile east of Menemsha Creek, in a road cut on the
north side of the North Road where it descends a steep hill east of the creek,
there is a small exposure of Cretaceous white kaolin sand over clay. Above it

is Wisconsin till.

CAPE COD GEOLOGY 147

SQUIBNOCKET
Along the cliffs that form the greater part of the coast of Squibnocket,
especially at its northeast end, there are obscure traces of beds of red clay that
have been considerably disturbed, and perhaps have been reworked, so that they
may be more properly classed as Montauk till.

NASHAQUITSA CLIFFS

Near the east end of the Nashaquitsa cliffs, in Chilmark, there are expos-
ures of Cretaceous clay, both red and white, overlain by white kaolin sand. As
seen about two-thirds of a mile west of the east end, these are both gently
folded and are apparently overthrust on the older Pleistocene gravels. The last
third of a mile shows mostly clay, evidently considerably disturbed and over-
thrust on glacial gravels.

PEAKED HILL PIT NO. 1

Between the north and middle roads in Chilmark, half a mile south of
Peaked Hill, there is an old clay pit that exposes the white clay and the kaolin
sand. The pit extends northeastward along the strike of the beds, but its sides
have fallen in to such an extent that the structure of the beds cannot be
made out.

ROARING BROOK

On the northwest shore, about a quarter of a mile west of Roaring Brook,
there is an exposure of a Cretaceous bed high in the cliffs. This bed was re-
cently worked for kaolin. It includes both white kaolin sand and red clay, and
it underlies a thick series of beds of glacial gravel. The strike of the Cretace-
ous bed is nearly parallel to the shore. The dip, although it is not at all clearly
shown, seems to be toward Vineyard Sound.

PEAKED HILL PIT NO. 2

Half a mile east of Peaked Hill there is another old clay pit showing Cre-
taceous kaolin sand and clay. This also is badly slumped.

NORTH ROAD VALLEY
Northeast of the localities mentioned there are many small exposures of
Cretaceous deposits, chiefly in old clay pits along the North Road Valley. The
kaolin sand is the most common member exposed in these pits, but beds of clay
are also seen. The lignite bed was not seen at any of these places. No Cretace-
ous beds are exposed along the shore of Vineyard Sound between Roaring Brook
and Norton Point.

148 CAPE COD GEOLOGY

MAKONIKEY

About half a mile east of Norton Point, at a place known locally as
‘‘Makonikey,” there is a clay pit which has been recently worked. The clay
here, although undoubtedly Cretaceous, has a somewhat different appearance
from that worked elsewhere. This difference may be due in part to its fresh
exposure, or the bed may be different from those exposed elsewhere. The
clay is a light blue-gray, or even a slightly greenish gray. It has been used
for making yellow bricks. The kaolin sand is also found here, but it has not
been worked. Mr. Roy Matthews, the former superintendent of the clay works,
says the beds of lignite have been encountered near the pit. The section at
Norton Point contains beds of lignite. Unlike most of the Cretaceous deposits
exposed, these beds appear to be but little disturbed and lie nearly horizontal.
Shallow borings in this vicinity strike Cretaceous beds.

Other localities at which Cretaceous beds are exposed are shown on the map.
Many of these exposures are small, but they show the distribution of this

series.
FORM OF THE SURFACE

The surface of the Cretaceous deposits as it existed before the Tertiary
deposits were laid down is shown only in the beds exposed in Gay Head cliffs.
The Cretaceous beds appear not to have been then deformed as they now are.
They were undoubtedly much eroded before the beginning of Miocene time,
but they probably formed an eastern extension of the features of the coastal
plain, such as may still be seen southwest of the glaciated area in northern
New Jersey. The occurrence in the Cretaceous section of beds of quartz gravel
interstratified with beds of clay and lignite suggests that the Coastal Plain
became somewhat dissected during the earlier stages of erosion in the period
of uplift between the retreat of the sea at the end of Cretaceous time and the
beginning of the local Miocene marine invasion. Streams that run parallel to
the coast formed bluffs that sloped gently seaward from their crests. Across
such coastwise cuestas the master streams maintained consequent courses to
their mouths. No recognizable trace of this relief now remains in the district.

AGE AS SHOWN BY FOSSILS

Owing to the abundance of Tertiary fossils at the Gay Head cliffs and the
fact that little importance was attached to the less conspicuous fossil plants

as horizon markers, the early American geologists regarded the Upper Cretaceous

CAPE COD GEOLOGY 149

beds as Tertiary. Even Sir Charles Lyell', who visited Gay Head in 1842,
saw no evidence of the existence of Cretaceous beds, and Shaler,? as late as 1888,
regarded all the beds in the Gay Head section below the drift as Tertiary.

The similarity of the beds at Gay Head to those at Raritan Bay, New
Jersey, was recognized by some, but it remained for White* to show their age
beyond a doubt. The result of White’s work was later confirmed and elaborated
by Hollick,* and four years later the extent of the Tertiary was made out by
Dall.> More recently Bibbins* and Berry’ have placed the leaf-bearing Cre-
taceous deposits of Marthas Vineyard in the Magothy, the second subdivision
of the five Cretaceous formations now recognized in the Atlantic coastal plain,
as shown in the following table.*

Rancocas
Monmouth Marine
Upper Cretaceous ; Matawan
Magothy

: \ Non-marine (estuarine and fluviatile)
Raritan

THE MATAWAN MARINE FAUNA®

A search for traces of the marine fauna found by Shaler in the fragments
of ferruginous sandstone on the south side of Indian Hill near the site of Woods
Schoolhouse soon brought to light numerous fragments of rather similar material,
which is found as far west as Gay Head in the older drift west of the Devil’s
Den and to the east throughout the length of the island in the region of ice-
laid drift. As noted in the accompanying report on the identification of the
fossils by L. W. Stephenson, the material is poorly preserved, but in his opinion
it resembles closely the fauna of the Matawan beds of the coastal plain in
Maryland. The distribution of the erratic material does not show whether it

1 Lyell, Charles, On the Tertiary strata of the island of Marthas Vineyard in Massachusetts, Proc.
Geol. Soc. London, 4, pp. 31-33, 1842-43. Also Am. Jour. Sci., 46, pp. 318-320, 1844.
2 Shaler, N. S., The geology of Marthas Vineyard, Mass., Seu Ann. Rept. Geol. Survey, pp. 297—
363, 1888.
8 White, David, On Cretaceous plants from Marthas Vineyard, Am. Jour. Sci., 3d ser., 3, pp. 93-
101, 1890.
4 Hollick, Arthur, The Cretaceous flora of southern New York and New England, U. 8. Geol. Survey
a 50, 1906.
Dall, W. H., Notes on the Miocene and Pliocene of Gay Head, Marthas Vineyard, Mass., Am.
fae Sci., 3d ser., 48, pp. 296-301, 1
6 Bibbicg A.B., eS of the Meoiy formation on the ‘Aflantic Islands, Abstract in Bull.
Geol. Soc. oo 21, p. 672,
7 Berry, E. W., The age of o Cretaceous flora of southern New York and New England, Jour. Geol.,
23, s-68 1915.
ark, W. B., Upper Set es Maryland Geol. Survey, 1916.
Y ae by J. B. Woodwor

150 CAPE COD GEOLOGY

was derived from layers above or beneath the lignitic and leaf-bearing clays
referred to the Magothy formation, but the known facts justify its reference
to the beds overlying the Magothy on Marthas Vineyard.

The plant-bearing Magothy beds appear chiefly in the lower parts of
the island, as in the Gay Head cliffs, on the terrace at Makonikey, and in the
sea-shore cliffs near Cape Higgon and westward toward Menemsha. These
tracts of Cretaceous appear to be wholly or chiefly Magothy, and the uplands,
from Prospect and Peak Hill eastward into Indian Hill, where overlying Cre-
taceous sands and clays, apparently without lignites, have been folded up,
may represent the Matawan and be the source of the fossiliferous marine
blocks. The abundance of the material nearly in place near Indian Hill points
to this conclusion.

The fossil marine fauna found by Shaler! in loose fragments of sandstone
in the drift at Indian Hill and at Lagoon Pond are referred to the Cretaceous.
The genera are given in the following list. Owing to the fragmentary nature
of the material most of the specific names were not given. All are figured.

Plicatula or Ostrea Modiola ? (2)
Ostrea or Exogyra Anomya ?
Exogyra . ueul ana

Cardium ?

Lucina pale (Nerina)
Tellina (Linearia) ? Turritella

Lucina ? Cerithium

Camptonectes burlingtonensis Gabb. Chemnitzia
Camptonectes parvus Whitfield (?) | One thought to be a new genus
The determination of these fossils was confirmed by C. A. White, who,
in a later paper,? correlated the beds in which they occur with the Tombighee
sand of Alabama, and stated that they could be provisionally referred to the
base of the marine division of the Cretaceous of the Atlantic border.

REPORT ON COLLECTION OF UPPER CRETACEOUS INVERTEBRATE FOSSILS
FROM MARTHAS VINEYARD, MASS.

By L. W. STEPHENSON
Collection made by David White in August, 1890
U.S. G. S. Coll. 788. Lagoon Pond, 2 miles above Vineyard Haven, Marthas
Vineyard, Mass.

1 Shaler, N.S., On the occurrence of fossils of the Cretaceous Age on the island of Marthas Vineyard
Mass., Bull. Mus. Comp. Zoél., Harvard Univ., Geol. ser. 2, a No. 5, pp. 89-97, pl. 1 (map), pl. 2 (fossils),
1889.
2 White, C. A., A review of the Cretaceous formations of North America, U. 8. Geol. Survey Cor-
relation papers, Bull. 82, p. 93, 1891.

CAPE COD GEOLOGY 151

Matrix: Dark red, fine, micaceous ferruginous sandstone, probably a sandy oxidized
iron carbonate concretion. Some of the pieces have a hard, greenish-gray, only slightly weath-
ered center containing scattered grains of glauconite.

Ostrea sp. (Same as in U.S. G. S. Coll. 1688, p. 2.)
Paranomia scabra (Morton)?

Plicatula sp. (See Shaler’s figs. 2, 2a, Pl. 3. Le 2
Pecten cf. P. argillensis Conrad

Corbula cf C. carolinensis Conrad

Collections made by J. 8. Diller in 1894
U.S. G. 8. Coll. 1,639. Highland Bluff, Marthas Vineyard, Mass.

Matrix: Dark red, fine, micaceous, ferruginous sandstone, probably oxidized sandy iron
carbonate concretions.
Anomia argentaria Morton? (See Shaler’s figs. 6, 13, Pl. 2.)
Modiolus, probably a new species (See Shaler’s figs. 17, 18, Pl. 2.)
Undetermined fragments of oysters and other bivalves
U.S. G. 8. Coll. 1,638. Oklahoma cliffs, Lagoon Pond, Marthas Vineyard,
Mass.
Matrix: Same as preceding.
Ostrea sp. A small Gryphaea-like form, probably undescribed. (See Shaler’s
fig, 16, Pl 2)
Exogyra ponderosa Roemer?
Paranomia scabra (Morton)?
U.S. G. 8. Coll. 1,637. Red sandstone mound near Indian Hill, near Woods
schoolhouse, Marthas Vineyard, Mass.
Matrix: Medium coarse, red micaceous ferruginous sandstone, with some small pebbles
of quartz.
Gervillia (?) probably a new species. (Probably the same as Shaler’s fig. 1, PI. 2.)
Exogyra ponderosa Roemer?
Ostrea sp.

Collections sent to the United States National Museum, Nov. 9, 1904,
by J. B. Woodworth. Accession number 43432.

U. §. G. S. Coll. 9,870. Cape Higgon, Marthas Vineyard, Mass. A loose
block collected by J. B. Woodworth.
Matrix: Dark red, fine micaceous ferruginous sandstone, probably an oxidized concre-
tion of iron carbonate.
Ostrea sp. (Same as in U.S. G. S. Coll. 1638, p. 2.)
Exogyra ponderosa Roemer? (One medium-sized individual, apparently smooth.)
Plicatula sp. (See Shaler’s figs. 2, 2a, Pl. 2.)
Modiolus n. sp. (Same as in U.S. G. S. Coll. 1639, p. 2.)
Crassatellites sp.

1 Shaler, N. S., Bull. Mus. Comp. Zodl., Harvard Univ., Geol. ser. 2, 16, pp. 89-97, 1889.

152 CAPE COD GEOLOGY

U. 8. G. 8. Coll. 9,572. Chilmark, Marthas Vineyard, Mass. Collected
by A. F. Foerste, Sept., 1889.
Matrix: Coarse red ferruginous sandstone, with small quartz pebbles. Unidentified
pelecypods.
U.S. G. 8. Coll. 9,569. From Indian Hill near the site of an old school-
house, Marthas Vineyard, Mass. Collected by J. B. Woodworth, June 18, 1889.
Matrix: Medium coarse ferruginous sandstone.
Ostrea sp. (Same as in U.S. G. S. Coll. 1638, p. 2.)
Exogyra sp.
Gervilliopsis?
Corbula sp.
U.S. G. 8. Coll. 9,571. Lagoon Pond, Marthas Vineyard, Mass. Collected
by L. F. Ward, Aug. 7, 1889.
Matrix: Dark red, fine, micaceous ferruginous sandstone, probably an oxidized iron
carbonate concretion.
Ostrea sp. (Same as in U.S. G.S. Coll. 1638.)
Pecten cf. P. argillensis Conrad.
Paranomia?
U.S. G. 8. Coll. 9,568. A boulder on Gay Head cliffs, Marthas Vineyard,
Mass. Collected by J. B. Woodworth, June 1889.

Matrix: Medium coarse, micaceous ferruginous sandstone, with small quartz pebbles.
Gervilliopsis?
Ostrea sp. (Same as in U.S. G. S. Coll. 1638, p. 2.)
Exogyra ponderosa Roemer?
Pecten cf. P. argillensis Conrad
Cardium sp.
Corbula cf. C. carolinensis Conrad
Small unidentified gastropods
The fossils listed above were all obtained in pieces of ferruginous rock.
Though showing a general similarity in lithologic appearance these rocks may
nevertheless be divided into two types, which are probably different facies of
the same formation. One facies consists of dark red, fine micaceous ferruginous
sandstone, probably the oxidized product of concretionary sandy masses of
iron carbonate. Some of the specimens have a dark greenish-gray, only partly
weathered core; some possess the contraction cavities characteristic of septaria,
and many of the cavities are lined with small crystals. The localities of this
facies are:
U.S. G. 8. Coll. 9,571. Lagoon Pond
U. 8. G. S. Coll. 788. Lagoon Pond, 2 miles above Vineyard Haven
U. 8. G. S. Coll. 1,638. Oklahoma Cliffs, Lagoon Pond

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CAPE COD GEOLOGY 153

U.S. G.S. Coll. 1,639. Highland Bluff
U.S. G. 8. Coll. 9,570. Cape Higgon
The other facies is medium coarse, red micaceous ferruginous sandstone,
containing small quartz pebbles. The specimens were collected at the following
places:
U.S. G. 8. Coll. 9,573. Chilmark
U.S. G. §. Coll. 9,569. Indian Hill, near the site of an old schoolhouse
U.S. G. 8. Coll. 7,568. Gay Head cliffs
If the fossiliferous ironstones were all collected from the same formation
the fauna as a whole includes the following forms.

List of Cretaceous invertebrate fossils from Marthas Vineyard wn the collections
of the U. 8. National Museum and the U.S. Geological Survey

Gervillia? (Probably the unnamed species figured by Shaler as Plate 2, fig. 1.)

Gervilltopsis?

Ostrea sp. (A small Gryphaea-like form, probably the same as Shaler’s Plate 2, fig. 16.)

Exogyra ponderosa Roemer? (Small and medium-sized specimens of a smooth form.)

Pecten cf. P. argillensis Conrad. (Costae broader and coarser than those of P. belliculptus
(Conrad.) Same as Shaler’s Plate 2, figs. 8 and 9.

Plicatula sp. (Same as Shaler’s Plate 2, figs. 2 and 2a, probably undescribed.)

Anomia argentaria Morton? (Probably Shaler’s Plate 2, figs. 6 and 13.)

Paranomia scabra (Morton)

Modiolus sp. (Sculpture and form well preserved; probably undescribed; same as Shaler’s
Plate 2, figs. 17 and 18.)

Crassatellites?

Cardium sp.

Corbula cf. C. carolinensis Conrad.

Corbula sp.

A small unidentified gastropod. (Probably Shaler’s Plate 2, fig. 10.)

Shaler’s illustrations! indicate the following forms in addition to those
listed above: Pieria (fig. 5); Lucina (fig. 11); Cerithiwm? (fig. 12); and Turritella
(figs. 7, 14).

Subsequent to 1889 a collection of Cretaceous fossils from Marthas Vine-
yard, evidently obtained from the same source as the fossils listed above, was
submitted to Dr. T. W. Stanton, who prepared the following unpublished
report, the original copy of which he has kindly placed at my disposal:

The fossils from Marthas Vineyard sent by Prof. Battey for examination are mostly
imperfect casts and obscure impressions that cannot be determined. Numbers 1-3, 17, 31-33
and 35-37 are of this nature. Most of the forms have been figured, without specific names,

1 Shaler, N. S., Bull. Mus. Comp. Zoél., Harvard Univ., Geol. ser. 2, 16, pp. 89-97, pl. 1 (map);
pl. 2 (fossils), 1889.

154 CAPE COD GEOLOGY

by Prof. N. S. Shaler in the Bulletin of the Museum of Comparative Zoology, Geol. ser. 2,
16, No. 5, 1889, Plate 2, to which references are made below.

No. 4. Apparently a fragment of a large gastropod belonging to the Volutidae.

Nos. 6 and 9. Modiola. (Prof. Shaler’s fig. 18, and perhaps 17.)

Nos. 7 and 8. Impressions of a Plicatula or a Placunanomia. Resembles Placunanomia
lineata Conrad.

No. 15. Undetermined. (Prof. Shaler’s fig. 1.)

No. 16. Impressions of Turritella, Corbula, and another small lamellibranchs.

No. 18. Hxogyra? (Possibly the same as Prof. Shaler’s figs. 19 and 20, though his speci-
mens seem to be without plications. This species has some resemblance to the Eocene Ostrea
compressirostra.)

No. 19. Avitcula. (Apparently not the same as Prof. Shaler’s fig. 5. Compare Avicula
petrosa Conrad.)

No. 20. Ostrea. (Prof. Shaler’s fig. 16.)

No. 30. Fragments of wood in sandstone.

No. 34. Modiola and Anomia.

No. 38. Lucina? (Prof. Shaler’s fig. 11.)

No. 8. bis. Boulder full of Ostrea sp.

Dr. Stanton does not know what disposition was made of this collection,
but presumably it was returned to Prof. Battey.

The specimens named in the foregoing lists are poorly preserved and the
specific determinations are doubtful, but they throw some light on the age of
the formation from which the ferruginous masses were derived.

The small Gryphaea-like oyster appears to be unlike any oyster heretofore
found in the Atlantic and Gulf coastal plain.

The identification of Exogyra ponderosa Roemer is fairly satisfactory and
probably indicates a position within the Hxogyra ponderosa zone.

The sculpture of the Pecten, which is compared to P. argillensis Conrad,
is well preserved and is very close to that of typical examples of the species
from the Ripley formation (Hxogyra costata zone) of Tippah County, Miss. The
range of the species is not sufficiently well known to serve as a basis for corre-
lation.

Anomia argentaria Morton is a wide-ranging form in the zones of Hxogyra
ponderosa and Hxogyra costata.

Paranomia scabra is common to the Exogyra costata zone and the upper part
of the Exogyra ponderosa zone but has not been reported in the lower part of the
Exogyra ponderosa zone.

Specimens of Corbula like that here compared to C’. carolinensis Conrad have
not been reported from deposits younger than the zone of Hxogyra ponderosa.

The evidence afforded by the invertebrates seems to favor the Matawan

age of the deposits in which the fossils were originally embedded, but it is in-

CAPE COD GEOLOGY 155

sufficient to determine the division of the Matawan to which they should be
referred. If the Exogyra is correctly referred to Exogyra ponderosa, the deposits
certainly fall within the zone of Hxogyra ponderosa. The stratigraphic limits of
this zone in New Jersey appear to correspond approximately with those of the
Matawan, though the lower limit of the zone has not been definitely established.

The Cretaceous plants from Gay Head and Nashaquitsa cliffs are in sep-
tarian ferruginous concretions, which are similar to those that contain the inver-
tebrates, except that they are less hackly, splitting with smoother surfaces, and
the cavities appear to lack the drusy linings seen in the masses containing in-
vertebrate fossils. Most of the concretions are dark red, fine to medium grained,
and micaceous, and some are strongly micaceous.

The plant-bearing concretions have been correlated by Hollick with the
Raritan (‘‘Amboy clay”) of New Jersey, but, as the invertebrate-bearing concre-
tions contain no fossil plants except an occasional obscure stem, the plants and
invertebrates were probably not derived from the same source. The two kinds
of evidence therefore do not necessarily conflict, the invertebrates probably
having come from deposits younger than the plant-bearing beds. If it should
be shown that the plant-bearing and invertebrate-bearing concretions were
derived from different beds in the same formation, the evidence of age afforded
by the plants would carry the greater weight, for the flora is large and well

preserved as compared with the fauna.

FOSSIL PLANTS

The list of the Cretaceous fossil plants found on Marthas Vineyard given
by Hollick is reproduced below. (See Plate 21.) A list is also published by
Berry,! but this list includes also plants from Long Island and does not give
localities. So far as is known to the writer, only one addition has been made
to Hollick’s list since it was published—Prepinus vitecetensis sp. nov., described
by Jeffrey in 1910.

Plants described by Hollick

The plants named in the following list are described by Hollick: *

Gleichenia protogaca Deb. and Etts.? *Marsilea Andersoni Hollick
Thyrsopteris grevilloides (Heer) Sagenopteris variabilis (Vel.) Vel.?
*Qnoclea inquirenda (Hollick) Podozamites sp.

Pane W., op. cit., pp. 615-618.
ae a &, Ades Prepinus from Marthas Vineyard, Proc. Boston Soc. Nat. Hist., 34, No. 10,
pp. 333-338
a he U.S. Geol. Survey Mon. 50, 1906.

156 CAPE COD GEOLOGY

Czekanowskia dichotoma (Heer) Heer?
Baiera grandis Heer?

Dammara borealis Heer

Pinus sp

Cunninghamites elegans (Corda) Endl.
Sequoia ambigua Heer

Sequoia Reichenbacht (Gein.) Heer
Sequoia fastigiata (Sternb.) Heer?
Sequoia gracilis Heer?

Cone of Sequoia concinna Heer
Wirddringtonites Reichtt (Etts.) Heer
Widdringtonites subtilis Heer

*W iddringtonites fasciculatus n. sp
Frenelopsis Hoheneggert (Etts.) Schenk?
Juniperus hypnoides Heer

Cone scale of a conifer?

Typha sp.

Poacites sp.

Populus stygia Heer?

Aments of Populus sp.

Salix membranacea Newb.

Salix Meeki Newb

Salix proteaefolia lanceolata Lesq.
Salia proteaefolia linearifolia Lesq.?
Cone of Sequova sp.

Ament of Myrica sp.

Juglans arctica Heer

Juglans crassipes Heer

saci Nn. sp.

Quere

Planere Sehloidin n. sp.

Ficus myricoides Hollick

Ficus atavina Heer

Ficus Kraustana Heer

*Ficus sapindifolia Hollick
Proteoides daphnogenoides Heer
Dryandroides — Vel.
Banksites saportan

Nelumbo Kempw (Hollick) Hollick
Menispermites acutilobus Lesq.?
Cocculus cinnamomeus Vel.
*Cocculites imperfectus n. sp.
*Cocculites inquirendus n. sp.
Magnolia speciosa Heer

Magnolia tenurfolia Lesq.

Magnolia pseudoacuminata Lesq.
Magnolia amplifolia Heer
Magnolia Lacoeana Lesq.

Magnolia auriculata Newb.

*Liriodendron attenuatum n. sp.

Liriodendropsis angustifolia Newb.

Liriodendropsis constricta (Ward) var.

ee simplex (Newb.) Newb.
*Liriodendropsis spectabilis n. sp.

*Cuatterta cretacea n. sp.

Cinnamomum Heertt Lesq.?

Cinnamomum sp.

Persea Leconteana (Lesq.) Lesq.

*Nectandra unperfecta n. sp.

Sassafras acutilobum Lesq.

*Sassafras angustilobum n. sp.

Sassafras crebaceum Newb.?

Sassafras hastatum Newb.?

Malapoenna sp.

Laurus nebrascensis (Lesq.) Lesq.

Laurus teliformis Lesq.

*Amelanchier Whiter n. sp.

Hymenaea dakotana Lesq.

Hymenaea primagenia Sap.

Cassia sp

Colutea primordialis Heer

*Dalbergia minor n. sp.

*Dalbergia trregularis n. sp.

Leguminosites coronilloides Heer

Leguminosites convolutus Lesq.?

Ilex papillosa Lesq

Celastrophyllum grandifoluum Newb.?

*Gyminda primordialis n. sp.

*Klaeodendron strictum n. sp.

Fruit of Acer sp.

Paliurus ovalis Dawson

Zizyphus grinlandicus Heer

*Ceanothus constrictus n. sp.

*Sterculia pre-labrusca n. sp.

Sterculia Snowti Lesq.

Sterculia sp

Eucalyptus? angustifolia Newb.

Eucalyptus Geinitzi (Heer) Heer

Eucalyptus Schiibleri (Heer)? n. comb.

*Eucalyptus latifolia n. sp.
*Hedera simplex n. sp.

Araha grinlandica Heer

Araha ravniana Heer

Aralia coriacea Vel.

Panax cretacea Heer

Andromeda Parlatori Heer

Myrsine borealis Heer

Diospyros primaeva Heer

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CAPE COD GEOLOGY 157

Diospyros apiculata Lesq.? *Tricalycites major Hollick
Diospyros provecta Vel. Tricalycites papyraceus Newb.
*Pertploca cretacea n. sp. *Calycites obovatus n. sp.
Premnophyllum trigonum Vel. Carpolithus floribundus Newb.
Williamsonia problematica (Newb.) Ward Carpolithus hirsutus Newb.
*Strobilites perplexus n. sp. Carpolithus sp.

Tricarpellites striatus Newb.

REPORT ON UPPER CRETACEOUS FLORA OF MARTHAS VINEYARD
By Epwarp W. Brrry

The Upper Cretaceous flora of Marthas Vineyard comprises 117 recorded
species, which were found in material collected at Chappaquiddick, Nashaquitsa,
and Gay Head, most of it at Gay Head. This flora has been elaborated by
David White and Arthur Hollick. Hollick considers it the equivalent of that
of the Raritan formation of New Jersey, but it is obviously younger, being
equivalent to that of the Magothy formation.

Fifteen of the species are confined to Marthas Vineyard. Of those discovered
elsewhere 67 are not found in the Raritan, and of the 35 forms in the Raritan
29 are common to the overlying Magothy, leaving but 6 forms that are peculiar
to the Raritan, and all these are vague or unique (Carpolithus, Williamsonia,
Tricarpellites, Tricalycites). Nearly all of the plants found on Marthas Vineyard
that also occur elsewhere are common to the Magothy of New Jersey or Mary-
land or to post-Raritan formations at other places. Thus 44 occur in the Magothy
and 20 are peculiar to Marthas Vineyard and the known Magothy, so that I
have no hesitation in correlating the leaf-bearing Cretaceous plants of Marthas
Vineyard with those of the Magothy formation!

TERTIARY SYSTEM

By J. B. WoopwortH
ABSENCE OF EARLY TERTIARY FORMATIONS
No deposits of either Eocene or Oligocene age have been found in place
on Marthas Vineyard. Some fragments of fossiliferous sandstone found in the
surface drift on Chappaquiddick Island were referred to the Eocene epoch by
Mr. Thomas C. Brown in 1905, but the position of the rock from which these
fragments were derived has not been determined. The direction of glacial
flowage in the district would lead one to look for this sandstone in place along
a line extending northeastward across Cape Cod past Barnstable and thence

1 Berry, E. W., Jour. Geology, 28, pp. 608-618, 1915.

158 CAPE COD GEOLOGY

north and north by west under the water of Massachusetts Bay. Fragments
of similar rock, a ferruginous sandstone or mudstone carrying casts of marine
mollusks, are scattered over the surface of the island as far west as Gay Head,

but these fragments contain Upper Cretaceous fossils.

MIOCENE SERIES

Miocene fossils were seen in the first half of the nineteenth century in the
cliffs at Gay Head, and for a time not only all the folded and contorted beds
there but all the deposits on the island under the surface moraines were regarded
as Miocene. Later scrutiny of the beds and the discovery in them of additional
fossils, however, led to the restriction of the Miocene deposits to not more
than two distinct beds in the Gay Head cliffs, and one of these beds (the osseous
conglomerate), which contains Miocene fossils, is, for reasons already stated
in this report, now referred to the very dawn of the Pleistocene epoch, a period
before the advent of the glaciers. The Miocene series, therefore, is here repre-
sented by a single deposit, long known as the ‘‘greensand bed,’ which in places
at Gay Head appears to be underlain by a deep-blue clay that also contains
Miocene fossils.

THE GREENSAND
CHARACTER

The Miocene greensand is a greenish to brownish bed, in places clayey,
composed largely of the small nodular remains of foraminifers, many of them
of genera peculiar to the Cretaceous deposits of the coastal plain of Mary-
land. At some places the bed looks so much like certain beds of Cretaceous
greensand of the Atlantic coast that some geologists have suggested that it
may have been redeposited on Marthas Vineyard from a Cretaceous formation,
but no sections thus far exposed in the island have given reason to believe that
greensand was laid down in this area during Upper Cretaceous time. Moreover,
the occurrence of casts of Miocene mollusks in the greensand bed, many of them
in the attitude of growth, and the absence of any Cretaceous admixture of such
fossils make it reasonable to suppose that the greensand is a local deposit, formed
when the conditions favored the growth of foraminifers and the accumulation

of their remains on the sea floor.
OXIDATION

The normal color of the greensand bed in this area is a peculiar shade of

green, which is invariable in the lower part of the bed, whether that part has

CAPE COD GEOLOGY 159

been inverted by folding or not. The upper part of the bed, and in places the
whole of it, has been made rusty red by the oxidation of the iron in the
original glauconite of the foraminiferal nodules, and at many places in the
Gay Head cliffs the so-called greensand is therefore a rusty red bed.

THICKNESS

The thickness of the greensand bed varies greatly in its exposure in
the Gay Head cliffs east of the lighthouse, to which part of the island it is ap-
parently limited. The bed is at few places more than 3 or 4 feet thick, but in
certain folds it appears to be as much as 10 feet thick.

A small bed of greensand carrying much clay was found in a vertical position
in the Nashaquitsa cliffs in 1899, about in the position of the Pleistocene beds,
in contact with the Cretaceous deposits exposed there. This bed disappeared
in the retreat of the cliffs several years ago.

UNCOMFORMABLE CONTACT WITH CRETACEOUS CLAY

The greensand rests with sharp unconformity upon the underlying Upper
Cretaceous clay, though the beds are so greatly disturbed that a change of dip
in the two formations is not recognizable. Fair exposures of the greensand beds
in the Gay Head cliffs may usually be seen at stations 18, 16, 17, 19, 20, 21, 28,
24, and 28, on a chart of Gay Head cliffs accompanying a paper by J. B. Wood-
worth!

FOSSILS

The greensand in the Gay Head cliffs has yielded several fossils, most abun-
dantly casts of the clam-like form Macoma lyelli Dall. Many of these casts are
in the attitude of growth in the foraminiferal mud. Casts of gastropods, the
remains of at least two species of crabs, and the teeth of sharks are also occa-
sionally found, along with the vertebrae of cetacea, chiefly whales. The verte-
brate bones include the tooth of a walrus, possibly that of a seal, and among
land animals that of a small rhinoceros.

The assemblage of fossils found in the greensand suggests a division in
the history of the greensand bed into an earlier period, in which the greensand
was laid down, possibly in deep water, and a later period, when shallow-water
mollusks like Macoma and Panope bored into the foraminiferal mud. The
bones of whales found at or near the base of the bed may indicate a still earlier
period of shallow water. Certain cobbles or rolled stones, the largest 5 or 6

1 Uncomformities of Marthas Vineyard and Block Island, Bull. Geol. Soc. Am., 8, 1896, Plate 16, p.
197.

160 CAPE COD GEOLOGY

inches in diameter, composed of a quartz-pebble conglomerate, found at or
near the base of the bed in 1889, appear to have been derived from some part
of the underlying Cretaceous deposits rather than from the breaking up of the
osseous conglomerate, as was then thought. In the course of the reéxamination
of the cliffs in 1915-16 no such cobbles were found in the greensand bed.

In places at Gay Head the greensand appears to be underlain by a deep-
blue clay containing few foraminifera but the same assemblage of fossils. It
was in such a bed that the tooth of a rhinoceros was found.

From such reconstruction of the highly distorted beds as can now be made,
it would seem that the Miocene sea swept over the site of the island while the
beds of Cretaceous clay and sand formed an undisturbed eastward extension
of the coastal plain like that still remaining southwest of Staten Island, and
that the water gradually deepened until the shore line, advancing across the
lowland of southeastern Massachusetts and Rhode Island, lay so far from the
present shore line that little or no sand and mud reached the site of Marthas
Vineyard. During this stage, in water that may not have been more than
50 or 60 feet deep, the deposits of foraminifers were laid down by the life and
death of these organisms in that part of the sea. The story of the retreat of the
sea in the succeeding Pliocene epoch belongs to the account of the immediately

overlying fossiliferous sand.

PLIOCENE SERIES

A deposit of sand carrying Pliocene fossils was found in 1899, faulted down
as a block less than 2 feet thick and having an exposure on the cliffs about 6
feet long, in the upper surface of the Miocene greensand bed near the north
end of the cliff, at an elevation of 80 feet. This remnant of a marine deposit
that was apparently widely extended is the only known Pliocene bed east of
Southampton, Long Island. If the interpretation here made is correct, the
Aquinnah or osseous conglomerate is a land deposit laid down at the very
dawn of the Pleistocene epoch, before the ice sheets reached the south shore of
New England.

AQUINNAH CONGLOMERATE (EARLIEST PLEISTOCENE)

In the part of the Gay Head cliffs that is described by Hitchcock as the
‘quadrangular fold,” between stations 30 and 36, there is exposed above the
white Cretaceous beds a bed of conglomerate, from 12 to 18 inches thick, made
up of rounded quartz pebbles; black and grayish, well rounded, smooth, and

in places highly polished chert pebbles; and an admixture of cetacean bones,

CAPE COD GEOLOGY 161

shark teeth, and, occasionally, a cast of a mollusk. This bed has yielded also
a bone of an early type of American camel and the astragalus of a highly devel-
oped Pleistocene horse, which were dug out of the bed some years ago by me
(Plate 22). The cetacean bones, the teeth of sharks, and the molluscan remains,
all in the condition of pebbles swept together by the action of water, have by
all previous observers been referred to the Miocene. Some of the chert pebbles
carry fossils now known to be of Helderberg (Lower Devonian) age. Until the
Pliocene and early Pleistocene fossils were discovered it seemed likely that the
bed of conglomerate was a beach or shoal deposit that had been rudely assembled
by currents or waves. It now seems more reasonable, however, to regard the
bed as a deposit laid down in a shallow stream on the border of the coastal
plain, in which the coarser debris, of mineral and organic origin, washed out
of neighboring banks from Cretaceous and Miocene beds, perhaps from the
ereensand bed, accumulated in the open air on the surface of eroded Cretaceous
sand and clay. This interpretation accounts for the local occurrence of the
bed, which has not been recognized, either as an unbroken deposit or as rolled
fragments, outside of Gay Head and the western part of Marthas Vineyard.
Both north and south of the exposure mentioned, rolled fragments of this bed
occur on the unconformable surface separating the Cretaceous deposits from
the older Pleistocene boulder beds and gravel deposits. Some cobbles, a few
inches in diameter, have been found at the same geological horizon near Peaked
Hill and on the south slope of the island near that hill as far east as a roadside
ravine at the east end of the flattish hill on the north side of Chilmark Pond,
a hill that affords an excellent view of the south shore.

The entire absence of pebbles of granite, gneiss, and other pacing
rocks in this conglomerate indicates its derivation from wash of the underlying
Cretaceous and Tertiary deposits at a time when the beds of the Coastal Plain
stretched northward over the area of the Sound and Buzzards Bay. This concep-
tion presents a picture of the dawn of Pleistocene time, when the probably drier
climate of the Pliocene epoch, indicated by the remains of a camel, had given
way to the cooler and moister Pleistocene climate, before the first ice sheet had

driven the native horse beyond the limits of glaciated New England.

162 CAPE COD GEOLOGY

QUATERNARY SYSTEM
By Epwarp WIGGLESWORTH
PLEISTOCENE SERIES
The remarkable abundance and variety of the Pleistocene deposits on
Marthas Vineyard reveal much more Pleistocene history than can be deciphered
at other places in New England, where the Wisconsin deposits dominate all
other glacial phenomena. On Marthas Vineyard the reverse is the rule, the
Wisconsin deposits form only an insignificant part of the Pleistocene beds,
and only the earlier ice of Wisconsin time extended so far south. The series is
very nearly the same as that on Long Island, New York, but no exact corre-
lations of the earliest deposits can be made. These deposits and their probable
correlation are more fully considered by Professor Woodworth in Part I of this
report. The series, as made out, is as follows: —
Wisconsin moraine and outwash
Hempstead gravel member
Manhassett formation Montauk till member
Herod gravel member
Jacob sand
Gardiners clay
Moshup till member; at Nashaquitsa cliffs
Coarse gravel of typical Jameco type; at Gay Head and Nashaquitsa
cliffs
| Ferruginous boulder bed; at Gay Head
Mannetto formation: at Gay Head cliffs
Weyquosque formation: at Gay Head and Nashaquitsa cliffs
Dukes boulder bed: at Gay Head cliffs
Aquinnah conglomerate: at Gay Head cliffs

Jameco formation

EARLY PLEISTOCENE DEPOSITS (PRE-GARDINERS FORMATIONS)

The lowest formations of the Pleistocene series, including all those laid
down before the deposition of the Gardiners clay, are clearly exposed in only
two small outcrops, one in the Gay Head cliffs, the other in the Nashaquitsa
cliffs. Small exposures of what are thought to be the same beds occur at five
other places, notably at Norton Point. Only in the two cliff sections are the
beds well enough exposed to justify an attempt to interpret their relations, but
the exposures are so small and so obscure that the interpretation made can be
regarded as only tentative. The interpretation proposed does not agree with
that proposed for the deposits on Long Island that preceded the Jameco, as
described by Fuller,! which consist solely of a gravel called the Mannetto gravel.

! Fuller, M. L., Geology of Long Island, New York, U.S. Geol. Surv. Prof. Paper 82, pp. 80-92, 1914.

CAPE COD GEOLOGY 163

This deposit, which consists of rounded pebbles of quartz in a quartz matrix,
is the only one in the Pleistocene series that precedes the Jameco, from which
it is separated by a marked unconformity representing a long period of erosion.
According to Fuller,! the Mannetto does not exist on Marthas Vineyard, having
probably been removed by post-Mannetto erosion. The Jameco gravel, accord-
ing to Fuller, is the oldest Pleistocene deposit on Long Island. To this deposit
he assigned the well-exposed gravel that lies below the Gardiners clay in the
Nashaquitsa cliffs. The present writers, however, believe that four older Pleisto-
cene beds lie below the Jameco gravel.

Sections In Gay Hap CLIFFs

Aquinnah conglomerate.—In the Gay Head cliffs, directly below the light-
house, there is a large quadrangular fold in which the lower members are beds
of Upper Cretaceous sand and clay. Above these beds, according to Wood-
worth, there is a thin bed, formerly thought to be of Miocene age, called by
Hitchcock the osseous conglomerate. The larger constituents of this bed are
small, well-rounded, white quartz pebbles, chert pebbles, and cetacean bones.
The bones and some shark teeth, as well as the fact that the deposit was formerly
supposed to lie below undoubted Miocene greensand, led to the belief that it
also was of Miocene age. Later, however, a metacarpal of a Pliocene camel
and an astragalus of a Pleistocene horse were found in this bed * (Plate 22). It
must therefore be regarded as a Pleistocene deposit formed before the ice
reached the region. The presence of Tertiary fossils in the bed is due to the
erosion and redeposition of preéxisting deposits. Woodworth has given to this
osseous conglomerate the name Aquinnah, the Indian name for Gay Head.

Dukes boulder bed.—Above the Aquinnah conglomerate in the Gay Head
cliffs there is a remarkable bed of boulders, entirely free from clay, which
was described by Woodworth in 1897,3 and by Shaler in 1889. This bed at
one time contained boulders as much as 8 feet long, weighing about 4 tons. The
boulder bed is composed of granite, diorite, and gneiss from the mainland and
includes also a small boulder of peridotite from Iron Mine Hill, in Cumberland,
Rhode Island, 60 miles away. The bed is locally cemented by limonite and
contains pebbles of Cretaceous sand and clay. Many of the boulders are much
decayed and can be broken up readily with a hammer. The nature of this bed,

1 Op. cit., pp. 219-220.

2 Woodworth, J. B., Glacial origin of older eas in ee Head cliffs, with a note on fossil horse
of that section, Bull. cL Soc. Am., 11, pp. 455-460, 1

3 Woodworth, J. B., Picouioenitics of Marthas wea ond of Block Island, Bull. Geol. Soc. Am.,
8, p. 205, 1897.

164 CAPE COD GEOLOGY

and especially the glacial striae on one of the boulders, shows that it was formed
by the action of ice, and it is therefore regarded as the product of an early ice
sheet at a time not far from the beginning of the Pleistocene epoch. To this
bed Woodworth has here given the name Dukes boulder bed.

Mannetio formation.—_Immediately above the Dukes boulder bed in the
quadrangular fold, directly below the lighthouse, is a bed of stony blue clay
till not noted in previous reports and first seen in 1916. This bed is exposed
also at another place in these cliffs, south of the quadrangular fold. This material
is clearly an ice-laid till, and it differs from the underlying boulder bed in con-
taining no boulders and some clay. It was probably formed by a later ice advance
than that which deposited the boulder bed, and it is here assigned to the Man-
netto stage.

Overlying the stony blue clay is a bed of gravel somewhat thicker than either
of the lower beds. This is the uppermost member that is involved in the quad-
rangular fold, and, with the exception of a thin Wisconsin coating, it forms
the highest part of the cliffs. Whether this gravel belongs to the Jameco or to
the Mannetto stage is not certain, but it is here assigned to the Mannetto be-
cause the Jameco deposits succeeded the folding and erosion.

Evidence of pre-Gardiners age of deposits.—The beds exposed in this part
of the Gay Head cliffs are all older than the Gardiners clay, a fact shown by the
relations between the older beds and the Gardiners clay where the clay is ex-
posed at the north end of the cliffs. In the Gay Head section the Cretaceous,
Tertiary, and oldest Pleistocene beds are all closely folded and are overlain
uncomformably by a thin veneer of Wisconsin drift except at the end of the
section. At the north end of the section the Gardiners clay is exposed, lapping
up unconformably on the underlying beds, as if these beds had formed an island
at the time the Gardiners was laid down. The Gardiners clay has been slightly
folded, but much less than the older beds. Exposures at Nashaquitsa cliffs
and elsewhere attest this fact.

The post-Mannetto period of folding— According to earlier reports on
Marthas Vineyard most of the dislocation of the beds in the Gay Head cliffs
antedated the deposition of what was then known as the ‘Tisbury beds,” on
the north shore of the island. As defined, these beds included the Gardiners
clay and certain younger deposits. The sections now exposed on Block Island
and Marthas Vineyard indicate that most of the folding and overthrusting of
the Cretaceous and Tertiary beds preceded the deposition of the Gardiners

1 Note by J. B. Woodworth.

f CAPE COD GEOLOGY 165

clay and the Jameco gravel or of the boulder beds at that horizon in certain
sections. If the strata were distorted by pushing or dragging at the margin of
an ice sheet advancing from the north, the earliest competent ice advance
would have shoved the beds into a position of approximate equilibrium, so that
subsequent ice advances would leave no marked signs of their work. This ap-
pears to be true, and we are therefore led to believe that the ice advance of the
Jameco stage was the greatest that had taken place since the beginning of
5 Pleistocene time, but the nature of the folding alone does not indicate that
. this ice advance was less vigorous than those which followed it. In the typical
| section of the beds that were folded and overthrust at this time, both on Block
Island and Marthas Vineyard, the overthrust moved from the landward side
toward the sea. The deployment to the southwest, over the Gay Head section,
as compared with the overthrust to the southeast, over Marthas Vineyard east
of Menemsha Creek, indicates the existence of a small lobe or tongue that
pushed southward through the depression occupied by Menemsha Pond. This
depression, along with the rest of the island, has been an area of deposition and
erosion, but probably its original cause lies in its axial position in reference
to the ice push at this time.
The deposition of the Gardiners clay about what appear to have been
} islands or shoals of Cretaceous clay has already been noted. The precise char-
acter of the topography impressed upon the coastal plain by the ice sheet is
not known. Probably much of the inequality of the surface is a result of differ-
ences in the resistance of the beds to crowding and dislocation. The surface of
the deformed mass was highest where the clays permitted packing, which
foreshortened the section and consequently forced the moving ice to ride over

the rising obstruction. Whether this action took place beneath sea level or
) above cannot easily be determined. The general character of the Jameco gravel
suggests shallow water or the action of streams on a plain above sea level. The
immediately succeeding Gardiners clay was evidently laid down during a period

of submergence.

Nasuaquitsa Currrs. (Plate 23, fig. 1)

Weyquosque formation.—At the east end of the Nashaquitsa cliffs the pre-
Gardiners beds are exposed, although the complete series seen at Gay Head
is not shown. The east end of these cliffs consists of Cretaceous sand and clay,
against which abut the older Pleistocene beds. (Fig. 11.)

The lowest Pleistocene bed grades from brown gravel up into a dark sand,

166 CAPE COD GEOLOGY

the upper part of which has a greenish cast. At its base this material consists
of coarser feldspathic sand containing shark teeth, phosphatic nodules, and
fragments of lignite. The organic remains appear to have been reworked and are
derived entirely from Tertiary and earlier strata. The bed has been so much
disturbed that it is now upturned into a nearly vertical position. This is the
Weyquosque formation of Woodworth.

Note by J. B. Woodworth: In July, 1920 my attention was called to an opening in a gravel knoll
on the land of Mr. Ernest Flanders, in Chilmark, about three-fourths of a mile south of the North \
Road and half a mile west of Menemsha Pond. This opening exposed Weyquosque gravels containing [
shark teeth, waterworn pieces of cetacean bone, phosphatic nodules, and some Miocene greensand, a
mixture of glacial gravel and organic débris from the Aquinnah or osseous conglomerate and the Miocene
greensand. The red sandy ground west of the opening and along the shore of the pond appears to be
a broad outcrop of the Jacob sand. On the shore south of Mr. Arthur A. Brigham’s land outcrops of the
Montauk till form the higher bluffs.

Moshup till member of Jameco formation and overlying beds. —Above the
lowest Pleistocene (Weyquosque) gravel, and separated from it by an un-
conformity, is a conspicuous bed of till containing boulders, some as much as
8 feet in diameter, embedded in a stony clay matrix. Boulders that were once
a part of this bed but that fell out of it because of the removal of the matrix
by the waves form a small point on the beach known as Boulder Point. The
former extent of the bed is marked by a train of boulders that extends out into
the water. The contact between this boulder bed and the lower Pleistocene '
(Weyquosque) gravel is nearly vertical, and the boulder bed itself stands in a \
vertical position. This bed, unlike the bed of gravel below it, contains clay and \
boulders. These beds therefore resemble the Pleistocene beds in Gay Head, |
where a bed of stony blue clay simulates a deposit of till, but the stony blue
clay in the Gay Head section is regarded by Professor Woodworth as an older
deposit, of Mannetto age. The stratigraphic relations here are described more
fully by Professor Woodworth. The positions of the beds both in Nashaquitsa }
cliffs and in Gay Head indicate a vigorous ice advance before the deposition x
of the Gardiners clay.

Against this conspicuous boulder bed rests the Gardiners clay, but obviously
not as it was originally laid down, for it is folded in small plications, which in-

dicate that it has been thrust against the boulder bed, probably by later ice
action, and possibly that which deposited the Montauk till and forced the
plastic clay against this resistant bed of boulders. The typical Jameco type of
gravel is not exposed here, but it may be concealed by the beach. Professor
Woodworth regards the Moshup till as the correlative of at least the upper
part of the Jameco gravel of Long Island.

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UPPER CRETACEOUS
SANDS AND CLAYS

PRE-GARDINERS
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GARDINERS CLAY

|

CAPE COD GEOLOGY 167

Norton Point
Near the northeast end of the section at Norton Point there is exposed
a bed of tough, compact, stony blue clay, which underlies the Gardiners clay.
This bed, which is about 10 feet thick, is exposed at the very tip of the point,
where the surface of the bed has a steep shoreward dip. Its relation to the
overlying beds makes it appear to have an eroded surface, on which the later de-

posits were laid down unconformably.

E Ww

Fra. 12.— Section at Norton Point, showing old till below Gardiners clay.
pre-Gardiners till; B, Gardiners clay; C, Jacob sand; D, Manhasset ee

OTHER EXPOSURES
Other exposures of beds of gravel that are lithologically like the lowest
Pleistocene gravel but that do not show their relations to other beds, have been
found at a few places, but these beds cannot be safely employed in the interpre-
tation of the geology. One of these beds, which is seen in a cut on the state road
near the top of Longview Hill, in Chilmark, consists of bedded gravel similar
to that in the anticline at Nashaquitsa cliffs. Another is in a shallow gravel
pit a few yards north of the state road, due north of the west end of Chilmark
Pond, where the gravel is like that in the bed just described. Another bed is
in the Indian Hill region, on the south side of the 275-foot hill. Here a gravel
pit discloses greenish sand such as that at the boulder point on Nashaquitsa
cliffs. Still another bed is in the cliffs just west of the mouth of Roaring Brook
where some gravel may be seen below the Gardiners clay. The section here is
so much disturbed, however, that the stratigraphic position of the bed cannot
be determined exactly.
GARDINERS CLAY
(See Plate 23)
NAME
~The Gardiners clay was named from Gardiners Island, which lies between
the north and south flukes at the east end of Long Island. On this island several
beds of oe that include some sand are well exposed at a number of places.'

1 Fuller, M. L., op. cit., p. 92.

168 CAPE COD GEOLOGY

CHARACTER
On Marthas Vineyard the Gardiners clay consists entirely of fine, grayish-
black silt or clay, which in places has a bluish tint, giving rise to the local name
of ‘‘blue clay.”’ (Plate 23, fig. 2). On this island it lacks inter-bedded sand except
near its top, where it grades into the Jacob sand. Its color is probably due in
part to organic matter, for fragments of lignite have been found in it at several
places. These fragments appear to be considerably waterworn. When wet the
clay is very plastic; when dry it may be reduced to a light-colored powder by
slight rubbing or pressure.
THICKNESS
The thickness of the Gardiners clay on Marthas Vineyard cannot be deter-
mined accurately because it has been greatly disturbed, but it is probably not
more than 35 feet thick, much thinner than it is near Brooklyn, on Long Island,
where, according to Fuller,! its aggregate thickness (including layers of sand
and gravel) is 150 feet. Wherever its thickness on Martha’s Vineyard is greater
than about 30 feet, it has been highly contorted.

Source or MATERIAL

Fuller holds that the Gardiners clay is of interglacial origin because the
marine fossils it contains indicate a moderate climate and its thickness indi-
cates a long period of deposition. On Marthas Vineyard only one fossil has been
found in it and its thickness is much less than that on Long Island. On Cape
Cod Woodworth has found large lenses of clay of possible Gardiners age, a
fact that does not indicate extensive interglacial deposition.

The evidence obtainable on Marthas Vineyard and elsewhere therefore
shows that the Gardiners clay along the south shore is of marine origin. Whether
the clay is of interglacial or glacial origin cannot be determined, but it is not
necessarily interglacial, for all the conditions requisite to its deposition would
have existed when the ice front stood some distance back of this area. The
distribution of the clay and its marine origin indicate that the Gardiners stage
was a time during which the main shore line lay somewhat back of the area
in which clay was deposited. On this shore line the waves and currents were
working on deposits left by the retreat of the ice and were carrying away the
finer part of these deposits from the shore and depositing it as clay. Thus the
Gardiners clay is considered a glacial or an interglacial marine deposit, which

' Fuller, Mo. op. cit, p, 93.

CAPE COD GEOLOGY 169

is composed largely of reworked glacial and perhaps of some reworked Cretaceous
material, laid down at a time of considerable submergence.

RELATION TO OLDER Deposits

The Gardiners clay probably rests conformably on the gravel near the mid-
dle of the Nashaquitsa cliffs section, but unconformably on the deposits at the
east end of Nashaquitsa cliffs and at Norton Point. At Gay Head cliffs the
Gardiners clay does not form a part of the section, except at the north end, but
it is found on the shore east of the cliffs, where it dips away from the cliffs.
It therefore seems that the Gardiners clay was deposited around the area now
occupied by the cliffs at a time when they probably formed an island. This same
relation is seen at Norton Point. Thus the clay lies conformably upon earlier
deposits at some places and unconformably at other places. This fact seems to
show that when the deposition of the Gardiners clay began the region was only
partly submerged, and that the water in which the clay was deposited was
not very deep.

The beds of Gardiners clay have, of course, been considerably distorted by
later advances of the ice and the evidence shown by their relations to older
deposits is therefore not altogether reliable. At the boulder point on Nashaquitsa
cliffs the clay has been thrust against the older beds, and at many places it has

been overthrust on itself, or even on later beds.

STRUCTURE

At many places the Gardiners clay shows a laminated structure, due to its
original bedding. The laminae average about half an inch in thickness. With-
out these laminae it would be a dense, homogeneous clay throughout, except
in some places near the top, where it is interbedded with layers of fine sand.
The larger structural features of the Gardiners clay are folds and overthrusts.
At some places the clay bed is nearly horizontal; at others it has been closely
folded; and between these two extremes there are all gradations. At some places
where the clay has been subjected to lateral pressure the beds have been thick-
ened and thrown into small folds. Small faults that have slickensided faces have
also been seen in the clay, but these are probably due to. landslips. At some
places where another formation has been pushed over the clay both beds have
been dragged. Where a large exposed surface of the clay is alternately wet
and dry, parting planes have been formed both on the bedding planes and at

right angles to them.

170 CAPE COD GEOLOGY

The folding in this bed is in places greatest along the northwest shore, where
the strike is generally northeastward. The folding occurs where the action of
the ice would naturally be strongest. It is not easy to explain why overthrust-
ing without close folding took place farther southeast of the strongly folded
area. Possibly the ice cover here was thin and allowed the whole bed to be
pushed southeastward as a more or less rigid layer. The fact that the Gardiners
clay has been overthrust on itself tends to give this theory more weight than
the theory that the low, gentle warping of the clay bed is due to the weight of
the ice, although such action may have occurred elsewhere, or perhaps even
here to some extent, for under sufficient pressure this clay would doubtless

have been compressed and otherwise molded.

Date OF THE FOLDING OF THE GARDINERS CLAY

The folding that the Gardiners clay has undergone was caused by the Mon-
tauk ice sheet. It is most pronounced along the northwest coast, where the
ice probably actually pushed and shoved both the Gardiners clay and the Jacob
sand. The distortion of the clay elsewhere is such as would be caused by a heavy
mass of overriding ice. The clay, being plastic, would be squeezed out where the
pressure was greatest and would accumulate where the pressure was least. The
deformation was not due to Wisconsin ice, for the pre-Wisconsin topography of
the Vineyard interval was not perceptibly altered by this final glaciation.

CONDITIONS DURING DEPOSITION

The conditions under which the Gardiners clay was deposited have already
been suggested. The nature of the material alone indicates that it was deposited
in water in an area that lay rather far from the shore, for it includes no coarse
material. The main evidence of its mode of deposition, however, lies in its fossils.
These are marine forms which, according to the senior author, lived when the
clay was being deposited, for they were found in the position of growth and
showed no signs of transportation. Submergence and the active work of wave
and current were therefore necessary to supply and transport the material. It
is possible that silt-laden rivers may have supplied some of the fine sediment.

DISTRIBUTION

The Gardiners clay is found only in the western part of the area. It proba-
bly does not underlie the whole area, as do the Cretaceous deposits, and it is

doubtless absent wherever the earlier deposits rise as high as 100 feet. Sections
at Gay Head and Norton Point indicate that the clay was deposited around

CAPE COD GEOLOGY 171

remnants of the earlier Pleistocene and Cretaceous beds. The clay is found
under the Vineyard Sound margin of the western area and is exposed at many
places along the shore. Later action of the ice has undoubtedly removed the
clay from some places where it was originally deposited and has thickened it
} in others, but as it was deposited on the lowlands of that time it was to some
extent protected by the remnants of older formations that stood at a higher level.
Along the southwestern margin of the western area the clay is not so well
\ exposed, except in Nashaquitsa cliffs. Northeast of these cliffs the outwash gravel
and morainal material cover nearly all places where the clay might be expected.
However, the clay probably lies along the southeast side of the morainal region
and flanks the earlier deposits there in much the same way as it does along the
northwest side.
OUTCROPS

In Gay Head cliffs the Gardiners clay is conspicuously absent except at
their north end. The only other clear exposure in the town of Gay Head is
along the west shore of Menemsha Pond, where the clay is seen at the base of
low cliffs, slightly above the level of high tide. Other doubtful exposures can
be seen in the eastern part of the town, along the state road.

The clay is found at places along the south shore of Menemsha Pond. The
exposures are the same as those along the west shore. In both localities the clay
is overlain by the Manhasset formation.

In an anticline near the center of the section seen in the cliffs at Squibnocket
the Gardiners clay is exposed for a short distance below the Manhasset.

The Gardiners clay is one of the most conspicuous beds in Nashaquitsa
cliffs. It occupies a large part of the section, which affords the best exposure
of this formation on the island, for both the top and the bottom of the bed
are seen, as well as its folded and overthrust structure and its local thickening

due to compression. (See Fig. 11.) West of these cliffs the clay apparently

lies below sea level, but here it rises as high as 100 feet above the beach and

shows several gentle folds and some overthrusts. One long section of the cliffs
is made up entirely of Gardiners clay, but farther east the bed is abruptly broken
( off and the remainder of the section, except two short stretches, reveals only
older beds.

Along the shore of Vineyard Sound, between Menemsha Creek and Norton
Point, there are several exposures of Gardiners clay. The first of these, begin-

ning at the southwest end, occurs west of Prospect Hill. Here the clay is gently
folded and is overlain by the Jacob sand and Manhasset formation. About

172 CAPE COD GEOLOGY

half a mile beyond this place the Gardiners clay is exposed in the face of the
cliff as if it were nearly horizontal, but in a gully that runs at right angles to the
shore it has the form of a close anticline, the upper part of which is exposed
along the face of the cliff. A third exposure of the clay is seen immediately west
of the mouth of Roaring Brook. Here it has been so much compressed that it
is abnormally thick and full of small plications. The clay here was once worked
for making bricks, and the remains of the old brickyard are still seen at the
mouth of the brook. The clay is here overlain by a thick bed of Manhasset
gravel. In one of the gullies at this locality a bed of gravel lies below the Gar-
diners clay. The clay here has probably been overthrust on this bed, which
resembles the Manhasset and not the pre-Gardiners beds.

East of the mouth of Roaring Brook the Gardiners clay is exposed in the
cliffs more extensively than elsewhere along this coast. It is considerably dis-
turbed (see Figure 138) and is overlain by the Jacob sand and the Manhasset for-

NE Sw

c = : , A

Ftc. 13. — Section on the shore northeast of Roaring Brook. A, Gardiners clay; B, Jacob sand; C,
Herod gravel; D; Montauk till; E, Hempstead gravel; F, Wisconsin till. The Herod, Montauk, and
Hempstead are members of the Manhasset formation.

mation. Northeast of this locality, as far as the section between Lambert’s Cove
and Norton Point, the Gardiners clay is not exposed, and only a small amount
of clay can be seen at either of these two places. At Norton Point the clay
overlies unconformably a bed of old till. The relation between these two beds
at Norton Point is one of the best evidences as to the age of the till. (See fig.
12.) The overlying beds are again the Jacob sand and the Manhasset formation.

About a quarter of a mile southwest of the small long pond between Chappa-
quonsett and James ponds, and again southeast of it, there are small old pits
from which clay was once dug. This clay is said to have burned red and prob-
ably the Gardiners is a red-burning clay. The place where it occurs is not one
where it would be expected, and the deposit stands at a much higher elevation
than any other known bed of the Gardiners clay.

Form or SURFACE
Large lenses of the Gardiners clay have been variously distorted by the
action of the Montauk ice, so that their surfaces vary from nearly flat to sharply
ridged, the ridges having been caused by anticlinal folding. The amount of dis-

Er ae

CAPE COD GEOLOGY 1/3

tortion, and therefore the irregularity of the surface, varies, for at some places
the clay was exposed to the full force of the ice action and at others it was
protected by remnants of older and more resistant beds. The weight of the
overriding ice also modified the surface, partly by abrasion, but even more be-
cause the plasticity of the clay allowed it to be flattened out where the pressure
of the overlying ice was greatest. In places a whole mass of the clay was evi-
dently pushed or dragged from its original position over itself or over other
beds. Thus at some places the Gardiners clay presents a level, undisturbed sur-
face and is overlain by the later Jacob sand, and at others its surface is a
well-defined ridge, which may or may not include the Jacob sand. At still other
places the surface was kneaded into undulations by the overriding ice and the
Gardiners clay is usually accompanied by the conformably overlying Jacob sand.
At still other places the surface was originally broken, but its irregularities
were smoothed off by the action of the ice.

Fossits AND AGE

The Gardiners clay is of Pleistocene age, a fact shown by its relation to
earlier deposits of unmistakable glacial origin at the north end of Gay Head
cliffs, at Nashaquitsa cliffs, and at Norton Point. This clay also overlies earlier
Pleistocene deposits on Long Island. As it was laid down later than two earlier
beds, one of gravel and the other of till, and probably later even than a second
bed of gravel, it evidently does not belong in the earliest Pleistocene. The
Gardiners clay overlies these beds unconformably, so that it was probably laid
down after a period of erosion in addition to periods of deposition.

Since the Gardiners clay was deposited, the Jacob sand, the Manhasset
formation, and the Wisconsin moraine and outwash have all been formed,
and there has been also the Vineyard period of erosion. Thus the Gardiners
clay, according to the stratigraphic evidence in this region, appears to be of
about mid-Pleistocene age.

No fossils have been found by the present writer in the Gardiners clay
in this area. One is mentioned by Dall,! — Modiolaria nigra (now known as Mus-
culus nigra), which he stated had been found at ‘‘Chilmark, in gray clay.”
Professor Woodworth has told the writer that this fossil came from the Gardiners
clay. Musculus (Moditolaria) nigra, a marine form, is clearly Pleistocene and
Recent. Fossils consisting chiefly of marine shells have been found in the
Gardiners clay on Long Island.

1 Dall, W. H., Notes on the Miocene and Pliocene of Gay Head, Marthas Vineyard, Mass., etc.,
Am. Jour. Sci., 3d ser., 48, p. 297, 1894.

174 CAPE COD GEOLOGY

Stratigraphic evidence shows that the Gardiners clay is of the same age
as the similar clay on Long Island, Gardiners Island, Block Island, and Nan-
tucket. It cannot be correlated certainly with the Pleistocene deposits of the
Mississippi Valley, although Fuller,! who considered it an interglacial formation,
has suggested with much caution that it may be assigned to the Yarmouth
interglacial stage.

JACOB SAND
NAME

The name Jacob sand, according to Fuller,? its author, is derived ‘‘ from
Jacob Hill, a high point on the north shore of Long Island, 8 miles northeast of
Riverhead, near which the formation is well exposed.’”’ On Long Island the
Gardiners clay grades upward through interlaminated clay and sand into the
fine silty sand of the Jacob formation, whose deposition followed that of the
Gardiners clay without a break. Nevertheless, this sand and clay show suf-
ficient lithologic difference from the Jacob formation to permit their recogni-
tion throughout Long Island and the islands farther east. The position and
character of this sand on Marthas Vineyard establish its identity with that
on Long Island.

CHARACTER

The Jacob formation is composed of extremely fine sand, made up of grains
of quartz and of some flakes of muscovite and grains of dark minerals. This
silty sand is somewhat plastic when wet and thus resembles the Gardiners
clay. In color the Jacob sand is usually a light gray, but at some places it
shows yellowish shades and grades into a buff sand. It is generally well strati-
fied. At some places the sand contains interbedded layers of clay; at other
places it contains beds of coarser sand. The Jacob sand is rarely over 12 or 15
feet thick, but as it is transitional from the Gardiners clay its limits are not
everywhere easily established. Wherever it is seen it rests on the Gardiners

clay, whose irregularities and distortions it follows closely.

SourckE oF MATERIAL
A slight change of conditions from those that prevailed when the Gardi-
ners clay was formed would cause a gradual change from the deposition of clay
to the deposition of the fine sand of the Jacob formation. Fuller * suggests that
the change might be due to any one of three causes: a change in level, a change

1 Fuller, M. L., The geology of Long Island, N. Y., U. S. Geol. Survey Prof. Paper 82, p. 106, 1914.
t., p. 107.

2 Op. cit.,
3 Op. cit., p. 107.

a

———

CAPE COD GEOLOGY 175

in the direction and strength of the currents, or the advent in the region of
the finer material from the outwash of an advancing ice sheet, or to any com-
bination of the three. The sequence of the deposits is suggestive. The Jacob
sand overlies clay and is overlain by the lower coarser gravel, and that by the
Montauk till of the Manhasset formation, a sequence suggesting that the material
was laid down by an advancing ice sheet that deposited it more rapidly as it
came nearer to this area.
STRUCTURE

The Jacob sand has suffered the same deformation as the Gardiners clay
and the deformation took place under the same conditions except, that as the
sand lay above the clay, it was subject to greater erosion by the overriding ice
sheet. This fact explains why the Jacob sand is absent in places above the
Gardiners clay, which is thus left directly in contact with one of the members
of the Manhasset formation. As the Jacob sand is fine grained and is plastic
when wet, and as it overlies a bed whose upper surface was very unctuous and
slippery, it acted exactly as part of the underlying clay. At a few places where
it was more directly exposed to the ice, the sand has been more deformed
than the clay.

CONDITIONS DURING DEPOSITION

The conditions that prevailed during the deposition of the Jacob sand were
similar to those that prevailed during the deposition of the Gardiners clay,
except that deposition was more rapid, probably because of the advance of the
ice sheet, and that the material laid down was slightly coarser. In addition,
there must have been a slight progressive elevation of the area, so that in the
period during which the deposit was laid down the water was somewhat shal-
lower than it was in the preceding period. In the main, the period of deposi-
tion of the Jacob sand was a time in which the greater part of the area was
under water.

DISTRIBUTION AND EXPosuRES

The Jacob sand is everywhere underlain by the Gardiners clay, and its
distribution is therefore practically the same as that of the Gardiners clay.
At some places, however, the Gardiners clay is not overlain by the Jacob sand,
which had been removed by erosion, largely by the Montauk ice. Thus,
although the. distribution of the Jacob sand is nearly the same as that of the
Gardiners clay, its area is somewhat smaller.

The Jacob sand is therefore exposed in the same places as the Gardiners

176 CAPE COD GEOLOGY

clay, namely, in the Squibnocket and Nashaquitsa cliffs, along the shore of
Menemsha Pond, and along the shore of Vineyard Sound. In the central part
of the Nashaquitsa cliffs the Gardiners clay for some distance is not overlain
by the Jacob sand. In places on the northwest coast, particularly at the mouth
of Roaring Brook, the Jacob sand is absent and the Gardiners clay is present,
but in practically all places where the Gardiners clay is exposed the Jacob sand
overlies the greater part of the clay. The best exposures of the Jacob sand,
both in development and in variation of structure, are seen in the Nashaquitsa
cliffs. In places here it has been very much disturbed and compressed and it is
locally overturned and removed from the Gardiners clay. Where the lateral
compression has been great it has been thrown into small plications, and where
it has been exposed to the action of the wind the thin beds, which contain more
clay, stand out in relief, so that the deposit has a fluted appearance.

The general distribution of the Jacob sand on Marthas Vineyard may like-
wise be considered the same as that of the Gardiners clay. The Jacob sand
flanks the northwest and southeast sides of the western area, surrounding a core
of the older, more highly folded beds that form the backbone of this area. It
is not seen in the town of Gay Head, and it probably lies below sea level in the
northeastern part of the island. It has not been found below the outwash gravel
of the great plain area, where there are no exposures deep enough to display

it, but it may exist in this area.

Form OF SURFACE

The form of the surface of the Jacob sand is due largely to the action of
the Montauk ice. In places where the sand has been but slightly disturbed it
passes upward gradually or fairly abruptly into the Herod gravel member of
the Manhasset. In such places the surface of the Jacob has been undulated by
the weight of the overlying ice. Where the Herod gravel was removed by the
Montauk ice, or where it may never have been deposited, the upper surface ~
of the Jacob sand is usually more irregular. In such places the action of the
Montauk ice has been stronger and the Jacob sand has been pushed and drag-
ged as well as eroded. At a few places till overlies the sand conformably, but
generally the Jacob beds are greatly disturbed, as in the Nashaquitsa cliffs.
As the Jacob sand overlies the Gardiners clay it was more exposed to the action
of the ice and so has been more disturbed than the clay, but, owing to its con-
tent of silt, it acted in much the same way as the clay, being bent and folded

rather than crumbled, as a coarser sand would have been.

\
f
\
\
4
f

ees eee

CAPE COD GEOLOGY qi

Fossi~s AND AGE

The deposition of the Jacob sand immediately followed that of the Gardiners
clay. The sand underlies the Manhasset formation without any sign of a break,
and the deposition of these three formations was apparently fairly continuous.
There is thus clear structural evidence that the Jacob sand is post-Gardiners
and pre-Manhasset, or, in other words, that it is of about mid-Pleistocene age.
It is a transitional formation between clay and gravel, but it is regarded by
Fuller! as a deposit laid down during the Illinoian stage, in spite of the long
time which intervened between its deposition and the actual invasion of the
Montauk ice. Woodworth (pp. 37, 69 of this report) correlates it with the Yar-
mouth interglacial stage.

No fossils have been found in the Jacob sand on Marthas Vineyard, but
some have been found in it on Long Island. Nearly all the forms found are still

living in the waters of this region.

MANHASSET FORMATION
Name

The name Manhasset formation is applied collectively to a series of glacial
deposits of post-Jacob and pre-Vineyard age. Although the formation is com-
posed of three distinct members, formed by the ice that deposited the Montauk
till, the deposits may be considered a unit. The top and bottom beds are of
essentially the same character and would constitute a continuous bed were it
not for the intervening bed of till. Regarding the origin of the name Fuller!
writes: ‘‘The name is derived from Manhasset Neck [Long Island], along the
shores of which, in the immense gravel pits on the Hempstead Harbor side, are
to be seen exposures of these beds more than 100 feet in height. The name was
first applied by J. B. Woodworth, who described and mapped in detail the
deposits in a part of the west end of the island (Long Island).’’ The succession
and nature of these beds on Marthas Vineyard, as well as their stratigraphic
position, are in every way similar to those of the Manhasset formation on
Long Island, and the same names are therefore here adopted for them. The
term ‘‘Tisbury beds” was once used by Woodworth for a part of the Manhasset
that was found along the northwest coast and that was approximately horizontal,
but Woodworth’s ‘‘Tisbury beds” included also the Jacob sand and Gardiners

clay, and the name was abandoned by him.

1Op. cit., p. 118.

178 CAPE COD GEOLOGY

SUBDIVISIONS

The Manhasset formation is divided into three members —a lower bed,
known as the Herod gravel, a middle bed, known as the Montauk till, and an
upper bed, known as the Hempstead gravel. The upper and lower members
are beds of similar glacial sand and gravel, and where the till bed is not present
it is impossible to distinguish the Herod from the Hempstead. The Montauk
till is easily recognized both by its position and its nature, the Wisconsin till
being usually quite different, unless it lies directly on the Montauk till or has
been formed of reworked Montauk material. These subdivisions of the Man-
hasset are the same as those on Long Island, and they are of essentially the
same nature.

GENERAL DisTRIBUTION

The Manhasset formation is best seen along the shore of the western area
and in Squibnocket, Stonewall Beach, and Nashaquitsa cliffs. It probably exists
all along the shore of the western area and extends well up on the older core of
the morainal highland. It also occurs in the northeastern area, but there it is
not so well displayed and probably only its upper members are ever exposed.
It doubtless underlies all the moraines of this area, although a large part of it
is below sea level. Under the great plain the Manhasset no doubt underlies the
outwash gravel, although it has not been clearly seen. Even if its upper member
were exposed in this area it would probably be indistinguishable from the out-
wash gravel. From the great plain the Manhasset extends well up the southeast
side of the core of the morainal highland in the western area.

Herrop GraveL MemBer

Name.—‘‘The name Herod gravel member is applied to the sand and
gravel beds constituting the lower member of the Manhasset formation, or that
part lying below the middle or Montauk till member. The name is taken from
Herod Point, near Wading River, on the north shore of Long Island, where
the gravel is well exposed.””! The position and nature of these beds being exactly
the same on Marthas Vineyard as on Long Island, the same name is here used
for them.

Character.— On Marthas Vineyard the Herod gravel varies from a fine
gravel to a sand. The change from gravel to sand in the vertical succession
takes place abruptly, but the beds do not everywhere hold their character for

1Fuller, op. cit., p. 121.

CAPE COD GEOLOGY > 179

any great distance horizontally. The gravel and sand are typical waterlaid
glacial deposits derived from granitic rocks. The material in the gravel consists
of quartz, fairly fresh feldspar, and other minerals. In addition to these finer
constituents there are small pebbles, chiefly of igneous and metamorphic rock,
and a small percentage of pebbles of sedimentary rock. Some of the pebbles
were obviously derived from the earlier Pleistocene deposits and show consid-
erable weathering, but the greater part of them are fresh and are typically
waterworn. The sand in the Herod gravel consists largely of grains of quartz
but includes small amounts of other minerals. Where the Herod gravel overlies
a depression in the surface of the Jacob sand or the Gardiners clay it has been
strongly stained, because the relative imperviousness of the underlying beds
has allowed the water that seeped down through the overlying beds to collect
and remain long enough to deposit some of the material that it contained in
solution. Much of the material carried in solution by this water was probably
derived from the Montauk till, some of whose constituents are very finely ground
and evidently somewhat soluble. Even at present the water in wells in the region
where the Montauk is found contains oxides of iron. The staining material is
usually brown or red, but at some places, as at Norton Point, its color may be
a bright orange-yellow, or it may be nearly black.

Thickness.— The thickness of the Herod gravel differs greatly from place
to place according to the extent of its erosion by the ice, as well as according to
the probable original differences in it at the time of its deposition. Where no
Montauk till overlies the Herod gravel it grades imperceptibly into the Hemp-
stead gravel, which at such places cannot be distinguished from the Herod.
The combined thickness of the two beds may therefore be mistaken for the
thickness of the Herod alone. The maximum thickness of the Herod gravel,
seen in Nashaquitsa cliffs, is about 100 feet. Elsewhere its thickness is much
less.

Structure.-—The Herod gravel is usually bedded, the beds consisting of layers
of coarser and finer material. Many of the beds are horizontal, but where the
whole member has been disturbed the beds conform to the distortion of the
formation as a whole. The Herod gravel is probably made up of lenses of gravel
and sand. The sand is in places 20 feet thick and contains no layer of gravel.

The Herod gravel as a whole, especially on the Vineyard Sound side of the
western area, has been deformed by the Montauk ice, the deformation consisting
largely of gentle folding and warping. The beds do not show the well-defined
small foldings shown by beds of clay, their tendency under pressure being to

en)

J

180 CAPE COD GEOLOGY

crumble rather than to fold. For this reason folding is less common in the
Herod gravel than in the underlying Gardiners clay and Jacob sand, and the
sharp folds seen in those formations are not found in the Herod. The Herod was
probably disturbed by the ice in two ways— first, by its push and drag, which
would be especially effective where an escarpment in the gravel was exposed
to the advancing ice; second, by the weight of the overriding ice, which caused
unequal settling of both the Herod and the underlying clayey beds. In other
words, much of the Herod gravel was exposed to both lateral and vertical pres-
sure, to which it adapted itself as best it could in view of its loose and friable
nature and its relations to the underlying formations. The Herod gravel that
lies under the outwash gravel which covers the great plain area has probably
been somewhat disturbed, for there is no reason to suppose that the Montauk
ice sheet stopped before reaching this region. However, the ice probably did
not encounter a rough surface, and it therefore probably overrode the Herod
member without causing much deformation.

Source of materials.—The immediate source of most of the material of the
Herod gravel is probably the older Pleistocene or earlier deposits of the same
region and the region now occupied by Vineyard Sound. The original source
must have been the mainland north of Marthas Vineyard. The granitic and
gneissic pebbles, which are relatively fresh, may have come directly from the
mainland.

Relation to other deposits —At some places the Herod gravel grades down
into the Jacob sand; at others it changes rather abruptly from coarse sand
above to fine sand below. It therefore rests conformably on the Jacob sand and
follows the undulations of its surface. Where the Jacob sand does not lie below
it the Herod gravel may rest directly on the Gardiners clay or it may lie uncon-
formably on earlier deposits, for the Herod gravel is a more extensive deposit
than the Jacob or the Gardiners. The upper contact of the Herod gravel with
the Montauk till is usually less disturbed and less irregular than would be
expected. At some places there is an apparent conformity between the two
beds, the unconformity seen at other places being due to erosion by the ice
before it began to form deposits. In places the Montauk ice removed the Herod
gravel entirely and the till rests on older beds. Where the Herod is in contact
with the Montauk till the contact is sharp. At places where the Montauk ice
did not deposit any till the upper surface of the Herod is in contact with the

Hempstead gravel. At such places there must be an unconformity between the
two, although it cannot be detected.

CAPE COD GEOLOGY 181

Conditions during deposition.— The conditions during the deposition of the
Herod gravel were those due to an invading ice sheet. In addition there may
have been a slight shallowing of the water, as the type of deposit formed suggests
that the water was shallower than it was during the deposition of the Jacob
sand; but the change in the type of deposit may perhaps be better explained
by the change in conditions due to the approach of the ice. Deposition was
greatly accelerated by the increase in the volume of water pouring from the
melting ice and by the increase in the amount of material fed to the water by
the ice. The climate was probably colder and precipitation was probably greater
in Herod than in Gardiners and Jacob time. The currents were stronger, and
other agencies were more active. Near the end of Herod deposition the water
in this region had grown much shallower, largely because of the great quantity
of gravel laid down.

Distribution.— The Herod gravel is the most widely distributed member of
the Manhasset formation, the Montauk and Hempstead members being of smaller
areal extent. The Herod probably covers a larger area than any other Pleistocene
deposit on Marthas Vineyard. The smaller areal extent of the two later Man-
hasset members is not due to their smaller areal deposition but to their greater
erosion during the Vineyard stage, which preceded the Wisconsin stage. The
Herod gravel flanks both sides of the western area and doubtless underlies
both the northeastern area and the great plain. It is well exposed in the Stone-
wall Beach (fig. 15), Nashaquitsa, Cedar Tree Neck (figs. 14 and 16), and Gay
Head cliffs. Along the northwest shore it is seen in nearly all the cliffs, es-

N S

Unexposed

Fie. 14.— Section one mile south of Cedar Tree Neck. Man-
hasset formation in morainal topography. A, Herod
gravel member; B, Montauk till member.

pecially north of Prospect Hill and at Norton Point. As the Herod gravel
is much like the Hempstead and the Wisconsin gravel, it cannot easily be
distinguished from these in the interior of the island, for exposures are scarce
and more than one formation must be exposed in order to permit identification
of any one. Where the Montauk till and an underlying gravel are exposed the
gravel is usually the Herod. Some such exposures are seen along the State road
in Gay Head and Nashaquitsa, but very few are seen on the roads in the rest

of the western area.

182 CAPE COD GEOLOGY

Age.— The position of the Herod gravel, which lies above the Jacob sand
and below the Montauk till, shows that it is one of a series of beds that are
connected with the advance of the Montauk ice. These beds, including the
later Hempstead gravel, all form a larger unit. On Long Island these beds,
which compose the Manhasset formation, are regarded as equivalent to the
Illinoian by Fuller,! whose view seems to be supported by the evidence on
Marthas Vineyard.

SW NE

oe x —

Fic. 15.— Section at Stonewall Beach cliffs. A, Montauk till; B, Herod
gravel; C, Wisconsin till; D, clayey phase of Montauk till.

Montauk Titt MEMBER

Name.—The Montauk till was named from Montauk Point, Long Island,
where it is well exposed. The name is applied to the middle of the three sub-
divisions of the Manhasset formation.

Character—The Montauk till is the most conspicuous of the Pleistocene
deposits, and it differs greatly from all the others. It is made up of a mixture
of clay, sand, pebbles, and boulders, which form a very compact tough bed of
unmistakable till. (See Plates 24 and 25, fig. 1). Its composition on the whole is
fairly uniform, but in places it is very clayey, particularly near the Gardiners
clay, where it is composed of material reworked from that bed. In some of its

NE SW

20 FT. es

100 YDS.
Fic. 16.— Section exposed southwest oi Cedar Tree Neck. A, Herod gravel; B,
Montauk till; C, gravelly phase of Montauk till; D, either Wisconsin or
Hempstead sand.

exposures the Montauk is banded, in others it is massive. Its toughness, which
is one of its most notable features, is undoubtedly due to compression and
partial cementation, which have produced a bed of hard pan that cannot be
penetrated with a shovel. A secondary feature is its mode of erosion. Where it
has been eroded by rain it has been cut into steep-sided gullies separated by pin-
nacles. (See Plate 25, fig. 1). Some areas of eroded Montauk resemble badlands.

1 Fuller, M. i., op. czt., p. 1382.

I
‘i
|

CAPE COD GEOLOGY 183

Fresh exposures of the till are bluish-gray, but this color is seen only in the
lower part of a bed. The upper part is usually brownish, or even chocolate-
colored, a shade due to the oxidation of some of the iron in the till. Where
the till is made of largely reworked Gardiners clay it has the dark gray or nearly
black color of that bed. Most of the boulders in it are granite and gneiss, but
it contains many other kinds of rock. Some of the boulders and pebbles are
angular and show strong glacial striation. The largest boulders are 6 feet in
diameter, but many exposures show scarcely a boulder over a foot long.

Thickness —The maximum thickness of the Montauk till on Marthas
Vineyard is 40 feet.

Source of material—The material of the Montauk till is obviously glacial.
The heterogeneous mixture of boulders, gravel, and clay and the shape of the
larger constituents and their characteristic markings show conclusively a glacial
origin. The coarser constituents of this till must have come from the mainland
on the north, for such rocks are not found in place nearer than the north side
of Buzzards Bay. The finer constituents were probably derived from the older
Pleistocene beds, all of which show considerable erosion by the Montauk ice.
The gravel must have been in large part derived from the Herod gravel, and
perhaps in less amount from earlier gravel. The clayey elements and the rock
flour produced by the Montauk ice were probably derived from the Gardiners
clay and the Jacob sand; in fact, parts of the Montauk till closely resemble
the Gardiners clay and are undoubtedly made up of reworked clay of that
member. It is impossible, however, to determine the sources of all the material.
Some of it may have been brought from the area now occupied by Vineyard
Sound and Nantucket Sound.

Relation to other deposits—At some places the Montauk till rests con-
formably upon the Herod gravel; at others it rests unconformably upon the Jacob
sand or the Gardiners clay. The contact is usually marked by disturbances
such as would be made by an ice sheet overriding unconsolidated beds. These
disturbances consist of the removal of some part of the lower beds and the
warping, folding, and even faulting of the part of the bed that lies directly in
contact with the till.

The Hempstead gravel rests conformably on the Montauk till. This gravel,
however, is not nearly so extensive as the Herod, and at some places the Mon-
tauk is overlain directly by the Wisconsin. At many places where the contact
between the two cannot be seen it is impossible to distinguish the Hempstead
from the Wisconsin. If the contact is conformable the gravel must be the

184 CAPE COD GEOLOGY

Hempstead; if it is unconformable it is the Wisconsin. A long period of erosion
followed the deposition of the Hempstead, and where the Wisconsin till rests
upon the Montauk it may be difficult to tell where the Montauk ends and the
Wisconsin begins.

Structure.— The Montauk till is gently warped and folded, but many of
its variations from horizontality are no doubt due to irregularities in the surface
on which it was deposited. It was not laid down horizontally, as were the water-
laid deposits. Such deformation as it has undergone must be due to the action
of the Wisconsin ice sheet, which was relatively weak on Marthas Vineyard,
owing to the interlobate axis there, and could not have caused the disturbances
found in the beds below the Montauk in other regions. The surface in the
Vineyard interval was overridden by the Wisconsin ice but was not greatly
disturbed.

Conditions during deposition.— The conditions that prevailed during the
Montauk stage of the Manhasset were those that are associated with a vigorous
continental ice sheet. The area that now forms Marthas Vineyard was covered
by a thick glacier, which extended at least to the southern limit of the island
and probably beyond. The extent of the deposits of Montauk time indicates
a much more vigorous or longer action of the ice than that in Wisconsin time.
The great thickness of the ice is indicated by the distortion of the older beds,
which may be attributed to the downward pressure of overlying ice without
horizontal pressure. The region must have remained buried under the ice for
a long time, for the till laid down is thick and there is nowhere any evidence
that it accumulated rapidly. Toward the end of this stage there naturally
must have been a stage when the ice was stagnant and melting—a stage at the
beginning of Hempstead time. After this great ice sheet had disappeared the
region must have presented a picture that surpassed in desolation and barren-
ness anything now in existence.

Distribution.— The Montauk till probably underlies the greater part of
Marthas Vineyard, but it is exposed only in its western part, except in two
areas. These areas are in the northeastern part of the island, near Edgartown,
and on Chappaquiddick Island. The first exposure indicated is in a gravel pit
at the side of the State road about a mile from Edgartown, where a lower tough
bed of till lies beneath bedded gravel, which is in turn overlain by sandy Wis-
consin till. The second exposure is on the east side of Sampson Hill, on Chap-
paquiddick Island, where a small gravel pit exposes the tough till below the

Wisconsin, In addition to these exposures there are a few places in the north-

CAPE COD GEOLOGY 185

eastern area where the Montauk may be exposed. In Edgartown village a man
who has dug many wells says that a bed of tough hard pan containing pebbles
lies beneath several feet of loose gravel. South of the Edgartown-Vineyard
Haven road, a little more than a mile west of Edgartown, there is an area of clayey
till, used for road material, which is distinctly different from any Wisconsin
material. Unfortunately, its relations to the other deposits cannot be deter-
mined. Its striking characteristic is its reddish color. In its nature it is more
like Montauk than Wisconsin. This exposure is in what the natives call ‘‘the
red ground.” This red ground is elsewhere poorly exposed, but traces of it
found in the northeastern area extend somewhat north of west from this locality
along the northern edge of the great plain, especially near the superintendent’s
house on the State game reservation. The same material is found just north
of the State road about a quarter of a mile west of the head of Chappaquonsett
Pond, in the western area.

. The Montauk till is exposed at many places in the western area. The best
exposures are in the cliffs, and those at Squibnocket are the most noteworthy.
(See fig. 17). Here the cliff is made up largely of this member and shows zones
of different color. The upper part here is brownish, a color quite different from
that of the chocolate-colored till below it. Below the chocolate-colored till there
is a grayish till. Some of the coloration here is undoubtedly due to weather-
ing, but some is original, for near its base the till is at some places composed of
Cretaceous clay and at others of the Gardiners clay. At the west end of the
Squibnocket cliff the Wisconsin overlies the Montauk. Elsewhere in the section
it is hard to make out any Wisconsin covering. It may exist here, but it is
probably similar to the Montauk.

In about two-thirds of the section at Squibnocket cliff the Montauk till
overlies the Herod gravel, below which, for a short distance, the Jacob sand and
Gardiners clay are seen. The typical erosion forms of the Montauk are seen
here better than anywhere else, and on this account this shore closely resembles
the south shore of Block Island. The formation is eroded into sharp gullies,
intervening pinnacles, and minaret-like forms, such as are seen in badland
topography. (See Plate 25, fig. 1.) Here and there large boulders are imbedded
in the till, and the whole shore here is a bouldery beach, which owes its character
to these erratics from the Montauk.

Other exposures of the Montauk till are seen in the Stonewall Beach cliff,
at the west end of Nashaquitsa cliffs, and on Gay Head. The Montauk is
probably rather widely distributed through the town of Gay Head and lies

186 CAPE COD GEOLOGY

very near the surface. It is seen in several exposures along the State road. (See
Plate 24.) Along the north side of Gay Head the till is covered by more gravel
than elsewhere.

Along the northwest shore of the main island there are many exposures
of Montauk till. In the Norton Point cliffs it is not well exposed, although it is
seen at some places. It is exposed immediately west of Paul Point, and at Cedar
Tree Neck there is a small cliff composed entirely of the Montauk till which,
however, presents a nearly vertical face, without the typical erosion forms.
This peculiarity is due to the fact that no streams flow over the cliff, the rainfall
from the cliff flowing down the slope to the small pond back of the shore. The
cliff is therefore eroded only by the waves. From Cedar Tree Neck to Cape
Higgon practically all the bluffs expose Montauk beds. At Cape Higgon itself
very little is seen, but in the cliffs northeast of Roaring Brook the till is seen
again above the Herod gravel and Gardiners clay. From Roaring Brook to
Menemsha the Montauk till appears in places, especially west of Prospect Hill.
For the details of the occurrence of the Montauk till along the shore, reference
should be made to the diagrams showing sections of the cliffs.

Age.— The stratigraphic position of the Manhasset formation, of which
the Montauk till is the middle member, can clearly be established as post-Jacob
and pre-Vineyard. It overlies the Jacob sand at many places, yet it was subject
to extensive erosion during the Vineyard interval. There is no evidence of an
ice advance between the Montauk till and the Wisconsin moraine. The erosion
during the Montauk interval was deep and must have been rather long as
compared with the post-glacial erosion of the beds of clay and sand of the
island by streams and rainfall. The Manhasset and its included bed of Montauk
till are clearly the products of a glacial stage prior to the Wisconsin stage and
separated from it by a long interglacial stage of fluvial conditions. The Man-
hasset may be the eastern representative of the Illinoian drift. The Man-
hasset and its intercalated bed of Montauk till constitute the thickest glacial
deposit on Marthas Vineyard, agreeing in thickness with the Illinoian drift of
the Mississippi valley, which is somewhat greater than that of the Wisconsin.

Hemepstuap GRAVEL MEMBER
Name.—“After the Montauk invasion and its attendant [ice] erosion, de-
position, and folding, the ice retreated from Long Island and a series of gravels
were laid down, doubtless derived from the ice, which appears to have lingered

in the vicinity. For these gravels, which represent the uppermost of the three

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WISCONSIN DRIFT GARDINERS CLAY & JACOB SAND

Fie. 17.— Section in cliffs at Squibnocket.

CAPE COD GEOLOGY 187

subdivisions of the Manhasset formation, the name Hempstead gravel member
is here introduced, from Hempstead Harbor, along the west side of which the
gravel is finely exposed in the upper parts of many large gravel pits.”’! The
conditions of deposition and the stratigraphic position of the gravel on Marthas
Vineyard seem to have been the same as on Long Island, and the same name is
therefore retained for this deposit.

Character.— Of the upper divisions of the Pleistocene the Hempstead is by
far the most indefinite. At many places it cannot be distinguished from the
Herod or from the Wisconsin. Over the greater part of the island it appears
to be lacking. A few sections, however, seem to prove its presence.

The Hempstead gravel on Marthas Vineyard is lithologically exactly like
the Herod. What has been said here in regard to the character of the Herod
applies equally well to the Hempstead. This member, however, is not so widely
distributed, because much of it was removed during the following period of

erosion. Were it not for its position above the Montauk till this member could.

not be distinguished from the Herod, and where the Montauk or other key beds
are absent or not exposed it is impossible to distinguish them.

Thickness.— The thickness of the Hempstead gravel cannot be given
positively on account of the erosion it has undergone and the scarcity of the
exposures. The section at Cape Higgon, if correctly interpreted, shows the
greatest thickness exposed anywhere. Here there are about 40 feet of gravel
whose base is exposed only where a large amount has obviously been removed
from the surface. In other words, this figure may be no more than a minimum
one.

Source of matervals—The source of the material of the Hempstead is essen-
tially the same as that of the Herod. Both were abraded from the same region
and by the same ice sheet. The glacial front in Hempstead time, however,
was retreating, whereas in Herod time it was advancing.

Relation to other deposits—The Hempstead gravel overlies the Montauk
conformably, and the contact is fairly sharp. The Wisconsin drift lies uncon-
formably upon the Hempstead. This unconformity is due to the normal erosion
of Vineyard time, which preceded the advent of the Wisconsin ice and lasted
long enough to remove much of the Hempstead gravel and to develop a mature
system of drainage.

Structure.— The Hempstead gravel has been much less disturbed than any
of the preceding deposits. Indeed, owing to its thinness or its short duration,

1 Fuller, M. L., op. cit., p. 150.

188 CAPE COD GEOLOGY

the Wisconsin ice sheet was so weak that the beds which it overrode were practi-
cally not deformed by it. The only places where any distortion could possibly
be made out would be those where the ice front encountered a cliff or other
abrupt topographic feature. Being a waterlaid deposit, the gravel shows bedding
wherever it is exposed. It contains no beds of till that might have been formed
by re-advances of the ice, such as are found in parts of Long Island. Some
thin layers of clay, however, are found in beds of gravel that probably belong
to the Hempstead.

Conditions during deposition — The Hempstead gravel was laid down when
the ice was retreating, a fact that suggests a somewhat milder climate than
that which prevailed during the Montauk stage, although the retreat may have
been due solely to a slackening in the speed of the advancing ice. At any rate,
the time was one of melting; water from the ice was washing materials out
of it and depositing them. Vegetation was probably very scarce, so that the
deposits were subject to rapid erosion.

Distribution and outcrops.— The Hempstead gravel is found only along the
northwest and northeast shores of Martha’s Vineyard and in the inland areas
that border these shores. Beds of gravel of this age may lie below the outwash
gravel in the great plain area, but they have not been recognized; in fact, it would
be impossible to distinguish them from the overlying outwash unless an uncon-
formity could be recognized between the two.

Northeast of Menemsha Creek, in the cliffs along the shore, some beds of
sandy gravel that are supposed to be Hempstead are exposed above the Mon-
tauk till. Farther northeast no beds of gravel that can be placed at this horizon
are seen until the section northeast of Roaring Brook is reached. Near the
northeast end of this section there is a small patch of sandy gravel, which over-
lies the Montauk till conformably and is in turn overlain by the Wisconsin till.
The largest exposure of probable Hempstead gravel is at Cape Higgon. Here
some beds of sandy gravel, exposed to a thickness of 40 feet, seem to overlie
the Montauk. This gravel is exposed for about 500 feet along the cliff. Another
exposure occurs a little more than a third of the way from this point to Cedar
Tree Neck, where gravelly sand and laminated fine sand and clay overlie the
Montauk till. In the cliff just south of Cedar Tree Neck there is an obscure
section showing bedded sand, probably of Hempstead age, overlying the Mon-
tauk till. The sandy gravel northeast of Cedar Tree Neck is also probably Hemp-
stead. In the Norton Point section some of the uppermost beds of gravel are

perhaps Hempstead, although the Montauk till is but poorly exposed.

CAPE COD GEOLOGY 189

West Chop and East Chop cliffs are probably composed largely of beds of
Hempstead gravel and overlying Wisconsin till. These beds have been only
slightly disturbed. As the Montauk is nowhere exposed, and as it appears at
successively lower levels east of Norton Point, it probably lies below these beds
of gravel. It is possible, however, that these beds are Wisconsin deposits that
accumulated in the interlobate area as the ice front was retreating. The cliffs
on both sides of Lagoon Pond are also probably composed of beds of Hemp-
stead gravel, although the beds are overlain by considerable sandy and gravelly
till. This till is of Wisconsin age and seemed to be composed largely of reworked
Manhasset gravel, but the contact between the two is obscure. :

The cliff on the north shore of Chappaquiddick, about 2 miles east of
Edgartown, shows thick beds of gravel that are here also regarded as Hemp-
stead.

Age.— The Hempstead gravel represents the closing stages of Manhasset
deposition, when the Montauk ice front was retreating. Its deposition followed
closely that of the Montauk till, but antedated by a long time the deposition
of the Wisconsin. According to the correlation indicated previously in this
report, the Manhasset is Illinoian; and as the Hempstead is the uppermost
member of the Manhasset it is therefore late Ilinoian.

VINEYARD INTERGLACIAL STAGE

At the end of Manhasset deposition, before the advance of the Wisconsin
ice sheet, there was a long period of normal subaerial erosion, during which a
mature system of drainage was developed on Marthas Vineyard. The topography
of that time is still preserved in the western area, and, though less completely,
in the northeastern area. During this period of erosion the land evidently stood
higher than it stands now, for its eroded surface now lies below sea level. This
period was obviously long, much longer than the time that has elapsed since
the Wisconsin ice invasion, for the erosion then was much greater than that
which has taken place since Wisconsin time.

Shaler! presented the evidence of this period of erosion in 1888 and again
in 1890, and Woodworth? called the period the Vineyard interval in 1896. In
regard to its age Woodworth? writes:

This erosion epoch, which may be known as the Vineyard interval, corresponds to the.
long inter-glacial epoch which has been so often pointed out by various evidences outside of

1 Shaler, N. S., Report on the geology of Marthas Vineyard, Seventh Ann. Rept., U. 8. Geol. Survey,
p. 345, 1888; Tertiary and Cretaceous deposits of eastern Massachusetts, Bull. Geol. Soc. Am., 1, p.
448, 1890.

2 Woodworth, J. B., in The glacial brick clays of Rhode Island and southeastern Massachusetts, by
N. 8. Shaler, J. B. Woodworth, and C. F. Marbut, Seventeenth Ann. Rept., U.S. Geol. Survey, pt. 1,
pp. 979-980, 1896.

3 Woodworth, J. B., op. cit., pp. 208-209.

190 CAPE COD GEOLOGY

New England. It constitutes the last and the most marked unconformity by erosion on
the island of Marthas Vineyard.

The Vineyard interval was mainly a period of erosion, but a few small beds
of peat were then formed. These beds seem to lie below the Wisconsin and
recent deposits and above the Manhasset. Such beds of peat, which contain
stumps of trees, have been seen at places on the southwest shore of Gay Head,
on the northwest shore, and on Squibnocket. All these beds except those on
Squibnocket lie nearly at sea level. Similar beds at this horizon on Long Island
are mentioned by Fuller. !

WISCONSIN DRIFT
SUBDIVISIONS

The WeoAc drift is the last glacial deposit laid down and is therefore
the highest division of the Pleistocene series. Its type area is in Wisconsin, from
which it was named. Chamberlin,? Wright,? and others have traced it from this
region to Wisconsin and have established its identity in the intervening country.
As it is the uppermost glacial formation it is not concealed by overlying deposits
and can therefore be studied much better than any of the others. Its diversity
here is greater than that of any of the earlier Pleistocene beds, because during
one stage of the Wisconsin glaciation this region was occupied by the ice front.
It includes three distinct types of deposits, (1) the sheet of till or ground mo-
raine; (2) the frontal moraine, here part of the terminal moraine, the outer-
most frontal moraine of this ice sheet; (3) the outwash from the ice along the
frontal moraine.

Tue TILu SHEET

Character.—The till or ground moraine is a deposit laid down beneath the
ice. It is composed largely of unassorted gravel, which was of local origin and
was dragged along under the ice or liberated from the bottom of the ice by melt-
ing. The till on Marthas Vineyard contains very little clay; it is composed mainly
of granitic gravel, which is at many places difficult to distinguish from gravel
of different origin, whose bedding has been obliterated by overriding ice or
for some other reason is not apparent. When it is closely examined, however,
an occasional pebble that shows faint glacial striae may be found. To some
extent the Wisconsin till varies in its nature according to the deposits which it

10Op. ci. p. 157.

2 Chamberlin, T. C., Preliminary report on a terminal moraine of the second glacial epoch, Third
Ann. Rept., U. 8. Cook Survey, pp. 291-402,

3 Wright, 1883, G. F., The glacial tee in a Pennsylvania, Ohio, Kentucky, Indiana, and
Tllinois, Bull. U. S. Geol Survey, 58, pp. 39-110, 1890.

am, — pacino

CAPE COD GEOLOGY 191

has overriden, but as these consisted predominantly of gravel, the till is also
mostly gravel. Where it rests on the Montauk till it partakes to some extent
of the nature of that bed.

The Wisconsin till is at some places at least 10 feet thick, and in certain
small areas it may be thicker, but it is almost absent at many places where one
would expect it to be thickest. Such places are especially numerous in the
western area. The till contains no clay and has a loose gravelly structure, differ-
ing strikingly from the Montauk till, which is always tough and compact and
shows no tendency to slide where it is exposed in cliffs or banks. Exposures of
the Wisconsin till that have been opened for only a short time are usually covered
with talus. The till is usually not very coarse, the diameter of most of the
pebbles being less than 2 inches and the matrix usually being sandy. It con-
tains some boulders, but they form only a small part of it. The greater part of
the boulders on the island belong not to the till but to the frontal moraine.

Source of material—RMost of the material of the Wisconsin till was derived
from the Pleistocene beds over which it moved, and as these beds consist mostly
of unconsolidated gravel and sand the till is loose and gravelly. Its boulders,
except those that were picked up from the Montauk deposits, must have come
from a greater distance. All its material, both coarse and fine, before it was
transported and deposited in earlier Pleistocene time, must originally have been
brought from the mainland on the north.

Relation of the Wisconsin to earlier deposits—The Wisconsin till lies un-
conformably upon the Manhasset formation and other earlier deposits. The
surface formed during the Vineyard interval is thus covered by this thin mantle,
irrespective of hills or valleys, except at some places in the higher parts of the
western area, where the till is either lacking or is so thin as to be indistinguish-
able. The sheet of till shows no disturbances such as are seen in all the earlier
deposits, having apparently been laid down very gently. The contact between
the till and the beds on which it lies is at few places sharp, or at least it cannot
be clearly seen, because the underlying bed and the till are very much alike and
the uppermost layers of the lower bed have been somewhat dragged, and so, in
a sense, incorporated in the till. Where the till overlies a bed of different nature,
such as the Montauk or the Gardiners, the contact may be sharp.

Distribution.— The Wisconsin till is found only in the western and north-
eastern areas and in a zone along the northeast edge of the great plain, where,
near the end of its stay, the ice extended temporarily over the outwash. In the

northeastern area the till is very sandy, but it is fairly well distributed among

192 CAPE COD GEOLOGY

kame deposits. It is seen in typical form in exposures along the banks of Lagoon
Pond and in East Chop cliffs, although it is rather thicker at these places than
elsewhere. In the western area the till is somewhat coarser and is rather widely
distributed. It can be seen in almost any of the cliffs along the shore of Vineyard
Sound. In the region south of the middle road it is very thin, and was at one
time even thought to be absent. The history of late Wisconsin time in this
region seems to have been similar to that in the northeastern area. Near the
end of the Wisconsin stage the ice advanced temporarily, as is shown by the
ice-contact slope north of West Tisbury post office and by several exposures
of till along the border of the great plain, as well as by occasional surface boulders.
During this advance a thin coating of till was laid down, which in some places,
especially on the higher ground, may now be almost removed.

NANTUCKET MORAINE

Origin and character.—'The deposits that form the Nantucket moraine
were laid down along the ice front. They were in part deposited directly by the
ice, but most of them show bedding and were therefore laid down in water.
The gravel in them is typical coarse granitic glacial gravel, which seldom occurs
in horizontal beds because it was “dumped” in masses in front of the ice. The
form of the surface of these deposits is peculiar and is one means of identifying
them. The numerous large boulders that cover the surface of these morainal
deposits are perhaps their most conspicuous feature. These boulders are obvious-
ly ice borne and must have come from a great distance, or at least from parts
of the mainland where bed rock of the same kind is found in place. Some of the
boulders have probably traveled 60 miles from their parent ledges.

The most conspicuous part of the Nantucket moraine lies between Chap-
paquonsett and Nashaquitsa and was formed by the Buzzards Bay lobe of the
Wisconsin ice sheet. The materials in this part of the moraine are coarser and
the boulders are more numerous and larger than those in the limb of the moraine
formed by the Cape Cod Bay lobe, which extends from the head of the inter-
lobate angle southeastward along the shore of Nantucket Sound to Edgartown
and across Chappaquiddick Island. The material in this part of the moraine
usually consists of gravel and sand and till. The source of the material of both
. parts of the moraine was the mainlaid on the north, but as the two lobes of
ice came from different parts of the mainland they brought somewhat different
materials.

The western limb of the moraine rests on the eroded surface of older Pleis-

po eemntnng cameennee eee

RESP snp

CAPE COD GEOLOGY 193

tocene deposits and on Tertiary and Cretaceous beds. These older deposits
in this region form an elevated plateau on which the moraine is superposed.
The northeastern limb of the moraine probably lies on the Manhasset forma-
tion, but this formation is exposed at but few places. This part of the mo-
raine does not rest on an elevated tract, as does the other. The morainal
deposits vary in thickness because they consist of ridges. Their average thick-
ness is probably not more than 5 or 10 feet.

Disiribution.—The morainal deposits in the town of Gay Head consist of
bedded gravel and sand, which form ridges that overlie the Manhasset and
older beds. The moraine here is not so conspicuous as it is in Chilmark, but on
Nashaquitsa there are prominent typical morainal ridges and knobs. Many
of these ridges are distinctly kamelike; and the bedding also suggests kames.
The deposits in Stonewall Beach cliffs rest on the Manhasset formation, and
those along the shore of Menemsha Pond rest on the Gardiners clay.

The most extensive morainal area and the largest frontal moraine is in
Chilmark. The deposits begin on the east side of Menemsha Pond and rise
rapidly to a height of more than 300 feet in Prospect and Peaked Hills, from
which they extend northeastward, with interruptions, as far as the region about
Norton Point. Their higher parts stand well above 200 feet. Prospect Hill is
the most striking morainal ridge on the island, standing up as an isolated hill.
A ridge that runs parallel to the north road, southeast of Prospect Hill, is also
typical. The best example of general morainal topography may be seen in the
region east of Peaked Hill, and here also Cretaceous deposits are exposed at the
base of the ridges in the high area. In Chilmark the moraine is separated
longitudinally into two parts by the north road valley. (See Plate 16, fig. 1.)
The moraine south of this valley is continuous from Peaked Hill almost to North
Tisbury and is a remarkable morainal highland. The moraine north of this
valley extends from Menemsha Creek through the town of Chilmark and be-
yond, nearly to Chappaquonsett Pond. The topography of this moraine is more
accentuated than that of the other and is, perhaps, best shown near the Chil-
mark-West Tisbury town line. (See Plate 15, fig. 1.) The deposits here form
two sharp ridges that run parallel to the shore and that contain many boulder
belts. (See Plate 17, fig. 2.) This moraine is interrupted by several pronounced
breaks. One of these breaks, if Nashaquitsa or Gay Head is considered a part
of this moraine, is made by Menemsha Pond; another is made by Roaring Brook;
and a third by Howlands or Paint Mill Brook. The fact that these two streams
were able to maintain their courses in spite of the deposition of the moraine is

noteworthy.

194 CAPE COD GEOLOGY

In West Tisbury the moraine reaches its best development in the Indian
Hill region. Beyond this it is interrupted by James Pond and the valley south-
east of it.

In the region about Chappaquonsett Pond the direction of the morainal
belt was changed by the interlobate re-entrant in the ice front, and there the
character of the topography and the nature of the deposits are somewhat
modified. Between Lagoon Pond and the State road on the west there are
sandy morainal deposits but no sharp ridges. Similar deposits are seen on the
east side of Lagoon Pond and farther southeast, where the morainal area grows
narrower, especially near Sengekontacket Pond. (See Plate 17, fig. 1.) Expos-
ures are scarce in this whole region, and the till cannot easily be separated from
the bedded deposits. The difference in the topography and the morainal de-
posits here and those in the western area is probably due to a re-advance of the
ice after the moraine had been formed. The morainal deposits of the Cape Cod
Bay lobe have been described as ‘‘kame-moraines.”” The ice that moved over
the moraine modified the form of the ridges and converted much of the surface
material to a sandy till, which overlies the morainal deposits that have the
bedding of kames.

The moraine continues beyond Sengekontacket Pond but is interrupted
at Edgartown by the narrow strait that connects Edgartown Harbor and
Katama Bay. On Chappaquiddick the moraine grows much broader and
finally it becomes lower and disappears under the sea at the east side of the
island.

OutwasH Deposits

The outwash deposits of the Wisconsin stage lie in the great plain south
of the Nantucket moraine. (See Plate 15, fig. 2). The material of this out-
wash varies from coarse gravel containing rather large pebbles to sand, and it
is coarsest along its northern boundary. In the southern area the upper layers
are coarser than the lower ones. No boulders are found in the outwash gravel,
which contains pebbles of many kinds of rock. Exposures of the outwash are
very scarce, for its deposits are flat and the area it occupies has not been in-
habited by man. The beds of outwash seen in the banks of the ponds in the
southern part of the plain appear to lie nearly horizontal, although they prob-
ably dip gently to the south.

The material of the outwash was brought to this region by the ice, from
which it was carried out and deposited by glacial streams. Most of these streams

issued from the base of the ice and therefore contained a larger proportion of

CAPE COD GEOLOGY 195

local material than the morainal gravel. Much of the outwash gravel was prob-
ably derived from the earlier Pleistocene deposits of this region from those of
the region just to the north. Most of the after outwash probably came from
the Cape Cod Bay lobe, for all branches of Tisbury Great Pond and the ponds
east of it head toward this lobe and not toward the Buzzards Bay lobe, although
that was much nearer. The main streams, at least near the end of Wisconsin
time, came from the northeast, and as they were the means of transportation
the material doubtless came from the same direction.

The Manhasset formation probably underlies most of the outwash, and no
doubt early Pleistocene deposits as well as the Cretaceous beds underlie in
places both the Manhasset and the outwash. The surface of the Manhasset
must have been considerably eroded during the Vineyard interval, and probably
the great volume of water issuing from the Wisconsin ice further eroded and
re-deposited parts of that series. Thus the outwash deposits must rest uncon-
formably on the older beds, although the form of the general surface of those
beds may not have been much different from that of the surface of the present

outwash.

196

1793.

1793.

1823.

1824.

1826.

1829.

1832.

CAPE COD GEOLOGY

BIBLIOGRAPHY OF MARTHAS VINEYARD
By Epwarp WIGGLESWORTH

Bayes, Wiii1am. Description of Gay Head: Mem. Amer. Acad. Arts and Sci.,
pp. 150-155.

West, Samueu. A letter concerning Gay Head: Mem. Amer. Acad. Arts and Sci., 2,
pp. 147, 150.

The papers of Baylies and West are of historical interest as the first published ac-
counts of Gay Head. The contorted beds and fossils are mentioned, but the cliffs are
supposed to have been formed by a volcano.

Fincy, Joun. Geological essay on the Tertiary formations in America: Am. Jour. Sci.
and Arts, 7, pp. 31-48. Paper read before Acad. Nat. Sci., Philadelphia, July 15,

2,

883

aes the beds and Gay Head to the Tertiary system and compares them to
those at Alum Bay, on the Isle of Wight.

Hircucocx, Epwarp. Notices of the geology of Marthas Vineyard and the Elizabeth
Islands: Am. Jour. Sci. and Arts, 7, pp. 240-248.

Recognizes three formations at Marthas Vineyard: (1) Alluvium (the outwash
plain); (2) diluvium (the morainal area); and (3) plastic clay formation. Places the
plastic clay in the Tertiary system.

DerarBorn, H. A. S. Sketch of the mineralogy of Gay Head and of Bird Island: Boston
Jour. Philos. and Arts, 3, pp. 588-590. In letter to one of the editors.

Contains a description of the clays of the western area. Notes the presence of
glacial drift and fossils.

Morton, S. G. Geological observations on the Secondary, Tertiary, and alluvial for-
mations of the Atlantic Coast of the United States of America, arranged from the
notes of Lardner Vanuxem: Jour. Acad. Nat. Sci. Philadelphia, 6, pt. 1, pp. 59-71.
Paper read January 8, 1828.

Includes Marthas Vineyard in his Tertiary formation.

Hircucocx, Epwarp. Report on the geology of Massachusetts lete.]: Am. Jour. Sci.,
22, pp. 1-70, map. Published also as report of the State Survey for 1832 and as Part 1
in report for 1833.

arthas Vineyard is one of the two places in Massachusetts where the Tertiary
is found. Lignite found. First geographic map of Massachusetts showed the island
as Tertiary and diluvium.

ee . Report on the geology, mineralogy, and zodlogy of Massachusetts, 700

pp., map, oe (in atlas), Amherst. The map was issued separately in 1832.
A fuller account of the geology of the island. Contains a section showing the rela-
tion of the older and younger beds on Gay Head. Figures the fossils found at Gay

5. ------------ . Report on the geology, mineralogy, botany, and zoélogy of Massa-

chusetts, 2d ed., 702 pp., Amherst.

Notes the striking appearance of the “diluvial” topography in the western area.
Describes the plastic clay and gives a section of the clay at Chilmark. The atlas ac-
companying this report gives figures of a fossil crab (Archacoplax signifera) and of
leaves from Gay Head.

| ——_——_——. Report on a reexamination of the ecoliomical geology of Massachu-

setts: House Document 52, 139 pp., Boston, State Printers.
Gives analysis of clay and greensand from Gay Head and an estimate of the
quantity of peat at Chilmark.

1843.

1845.

1849.

1852.

1854.

1863.
1870.

1871.

1872.

1875.

1876.

1876.

1878.

1879.

1872.

CAPE COD GEOLOGY 197

- Sessa . Final report on the geology of Massachusetts; Vol. 1 contains economi-

cal geology, scenographical geology, pp. 1-xii, 1-299, map, Amherst; Vol. 2 contains
scientific geology, elementary geology, pp. 301-831, ills., map, Northampton.

Includes a section and a stratigraphic description of the cliffs. Regards the beds of
clay as Eocene, the age of the clays of the London Basin.

LYELL, Str CHarzes. On the Tertiary strata of the island of Marthas Vineyard in
Massachusetts: Proc. Geol. Soc. London, 4, pp. 31-33; Philos. Mag., 3d ser., 28, pp.
187-189; Geologist, pp. 160-163; Am. Jour. Sci., 46, pp. 318-320 (1844).

ee . Travels in North America in the years 1841-48, with geological obser-
vations on the United States, Canada, and Nova Scotia, 1, pp. 2038-207, New York.

Regards the Gay Head series of deposits as Miocene Tertiary, because of the fossils
that he found there. These fossils include the skull of a walrus, teeth of shark, a tooth
of a seal, vertebrae of Cetacea, remains of crustaceans, and casts of Tellina and Mya.

Desor, Epovarp, and Cazor, E. C. On the Tertiary and more recent deposits in the
island of Nantucket: Quart. Jour. Geol. Soc. London, 5, pp. 340-344.

Correlates the clays at the base of Sankaty Head, Nantucket, with those at Gay

ead.

Desor, Epovarp. Post-Pliocene of the Southern States and its relation to the Lauren-
tian of the North and the deposits of the valley of the Mississippi: Am. Jour. Sci., 2d
ser., 14, pp. 49-59.

Rejects the glacial hypothesis to explain scattered boulders on the surface of
Marthas Vineyard, Long Island, and Nantucket, and attributes them to ice rafts.
Wuitine, H. L. Paper in report of the Superintendent of the Coast Survey for 1853,

p. 30, Washington.
Estimates the rate of recession of the Nashaquitsa cliffs.

Stimpson, Wiuitam. On the fossil crab of Gay Head: Boston Jour. Nat. Hist., 7,
pp. 583-589.

Lerwy, Josern. [On Graphidon vinearius from Marthas Vineyard, Mass., and on Cro-
codilus elliotti|: Proc. Acad. Nat. Sci. Philadelphia, 1870, pp. 113-114.

Hitcucock, C. H. Geological description [and geologic map] of Massachusetts. In
Walling & Gray, Official topographical atlas of Massachusetts, pp. 18-19, Boston.

The map shows the western area of Marthas Vineyard as Miocene and the rest
of the island as drift and alluvium. Describes the clays, lignite, and fossils of Gay
ead.

Mircue.i, Henry. Report on physical surveys made at Marthas Vineyard and Nan-
tucket during the summer of 1871: U. 8. Coast Survey Rept. for 1869, pp. 254-259.

Considers shore-line changes south of Chappaquiddick Island.

SHaER, N.S. In Proc. Boston Soc. Nat. Hist., vol. 15, p. 219.

Gives evidence of recent depression along the coast of Marthas Vineyard.

Dana, J. D. Manual of geology, etc., 2d ed., pp. 494-495.

Contains statement that Marthas Vineyard consists almost entirely of Miocene
deposits.

Buaxe, W. P. Notes on the occurrence of siderite at Gay Head, Mass.: Trans. Am.
Inst. Min. Eng., 4, pp. 112-113.

Crossy, W. O. Report on the geological map of Massachusetts (Massachusetts Com-
mission to the Centennial Exposition), 42 pp.

The map shows that the west end of the island is Miocene.

Haut, James. [Observations on the geological structure of Marthas Vineyard and
adjacent islands, Mass.|: Proc. Albany Inst., 2, pp. 148-149.

Upnam, WarreEN. ‘Terminal moraines of the North American ice sheet: Am. Jour. Sci.,
3d ser., 18, pp. 81-92, pp. 197-209.

198

18/0

1883.

1884.

1886.

1887.

1888.

1888.

1889.

1889.

1889.

CAPE COD GEOLOGY

Shows that Marthas Vineyard is a part of the great terminal moraine. Describes
the glacial deposits but recognizes no divisions of the drift into older and younger
deposits.

———. The formation of Cape Cod: Am. Naturalist, 13, pp. 489-502, 552-565.

A second discussion of the geology of Marthas Vineyard and other islands. In
neither paper does the author recognize the presence of Cretaceous beds. Thinks that
all pre-Pleistocene beds on the island are Tertiary and probably Miocene. Gives an
account of the later glacial geology.

CHAMBERLIN, T. C. Preliminary paper on the terminal moraine of the second glacial
epoch: U. S. Geol. Survey, Third Ann. Rept., pp. 291-402

Makes the first announcement of the law of lobation, which played an important
part in shaping the island. Shows the relation of Marthas Vineyard to the rest of the
terminal moraine.

Hetterin, ANGELO. Contributions to the Tertiary geology and paleontology of the
United States, p. 1, Philadelphia.

States that the Tertiary beds on Marthas Vineyard are probably a continuation of
those in New Jersey. The map shows the whole of the island as “Marylandian
(lower Atlantic Miocene).”

Merrit, F. J. H. On the geology of Long Island: Annals, New York Acad. Sci., 3,
pp. 341-364. Paper read November 7, 1884.

Attributes the folding of the beds on Long Island and the New England islands
to the action of ice and the morainal highlands of the western area of Marthas Vine-
yard partly to deposition of gravel and sand and partly to the upheaval of stratified
beds by the ice.

Wurtine, H. L. Report of changes in the shore line and beaches of Marthas Vineyard
as derived from comparisons of recent with former surveys: U. S. Coast and Geodetic
Survey Rept. for 1886, Appendix 9, pp. 263-266
Contains data on shore-line changes along the south shore.

Penrose, R. A. F., Jr. Nature and origin of deposits of phosphate of lime, with an
introduction by N. S. Shaler: Bull. U. S. Geol. Survey No. 46, p. 78.

Describes the nature and occurrence of the “amorphous aie phosphates of
Marthas Vineyard” found in the Tertiary greensand at Gay Head.

Sater, N.S. Report on the geology of Marthas Vineyard: U. S. Geol. Survey Seventh
Ann. Rept., pp. 297-363.

The first thorough study of the geology of Marthas Vineyard. Does not, however,
separate the Cretaceous from the Tertiary beds and thinks the deformation of the
older beds is due to mountain-building forces. Recognizes the series of beds between
the Tertiary and the Wisconsin deposits but does not place it definitely in the
Pleistocene, preferring to regard it as Tertiary.

Cuarke, F. W. [Analyses of clay, sand, etc., from Marthas Vineyard, Mass., collected
by N. S. Shaler]: Bull. U. S. Geol. Survey, 55, pp. 89-90.

Suauer, N.S. On the occurrence of fossils of Cretaceous age on the island of Marthas
Vineyard, Mass.: Bull. Mus. Comp. Zoél. Harvard Coll., 16, No. 5, pp. 89-97, ills.

Considers the fossils found in the drift. Suggests that the lower part of the Gay
Head section may be Cretaceous. The fossils are the first found in New England
that are regarded as of Cretaceous age.

Wricut, G. F. The ice age in North America, 622 pp., New York. Review by W. M.
Davis in Science, 14, pp. 118-119.

Describes Marthas Vineyard as a part of the terminal moraine underlain by
Tertiary deposits. Calls it a part of “one of the most remarkable true terminal mo-
raines in the world.”

CAPE COD GEOLOGY 199

1890. Ciarx, W. B. The geological features of Gay Head, Mass.: Johns Hopkins Univ.
Cire., 10, p. 28.

1890. Manat, F. J. H. [On the stratigraphy of the Gay Head section at lee Vineyard]:
Bull. Geol. Soc. America, 1, p. 556; Am. Naturalist, 24, pp. 563-56

1890. SHater, N.S. Tertiary and Cretaceous deposits of eastern ee Bull. Geol.
Soc. America, 1, pp. 443-452.

Modifies several views expressed in his “Report on the geology of Marthas Vine-
yard.” A section of Gay Head worked out by J. B. Woodworth shows closely folded
beds, from which he infers that similar folding may be found elsewhere in the island.
Recognizes two divisions of the oldest strata at Gay Head—a lower one, which may
be Cretaceous, and an upper one, which is probably Tertiary (Miocene). Recognizes
above these another series, which he places in the late Tertiary. Notes also evidence
of pre-Wisconsin glaciation.

1890. Warp, L. F. The age of the Gay Head Bluffs at Marthas Vineyard: Bull. Geol. Soc.
America, 1, pp. 555-556; Am. Naturalist, 24, pp. 562-563; Glimpses of the Cosmos,
4, pp. 198-219 (1915).

1890. Warp, L. F., and Merriit, F. J. H. The age of the Gay Head Bluffs at Marthas Vine-
yard: Am. Naturalist, 24, pp. 562-564.

Points out that the presence of Cretaceous leaves does not exclude the possibility
of the presence of some Tertiary beds.

1890. Waits, C. D. On Cretaceous plants from Marthas Vineyard: Am. Jour. Sci., 3d ser.,
39, pp. 93-101. Abstract, with discussion by J. S. Newberry, L. F. Ward, and F. J.
Merrill, in Bull. Geol. Soc. America, 1, pp. 554-556.

Corrects the current supposition that the older beds are all of Tertiary age. A
study of the flora indicates that the age is “ decidedly Cretaceous, probably middle
Cretaceous.”

1890. Wuirine, H. L. Topographical resurveys on Marthas Vineyard, etc.: U. S. Coast and
Geodetic Survey Rept. for 1889, appendix 14, pp. 459-460

Describes changes in the shore line at the east end of the south shore.

1891. Wuirr, C. A. Correlation papers: Cretaceous—a review of the Cretaceous formations
in North America: Bull. U. S. Geol. Survey No. 82, pp. 86-87, 93-96.

States that the fossils found by Shaler and White show that Cretaceous deposits
exist on Marthas Vineyard.

1892. Dati, W. H., and Harris, G. D. Correlation papers: Neocene: Bull. U. S. Geol.
Survey No. 84, p. 36.

Recognizes the presence of Tertiary deposits above the base of the Eocene and
below the summit of the Miocene.

1892. Unter, P. R. A study of Gay Head, Marthas Vineyard: Trans. Maryland Acad. Sci.
new ser., 1, pp. 204-212.
I . Gay Head: Science, 20, pp. 176-177.

In these two papers the author applies existing knowledge of the Cretaceous and
Tertiary deposits in the Middle Atlantic States to the series of deposits at Gay
Head. Believes that the Potomac clay, the Raritan formation, and the Cretaceous
greensand marl are represented at Gay Head, and that the structure is not due to
mountain building.

1892, ------------ . Observations on the Cretaceous at Gay Head: Science, 20, pp. 373-374.

Restates views expressed in his previous paper.

1892. Wuirr, C. Davin. The Cretaceous at Gay Head, Marthas Vineyard: Science, 20, pp.
332-833. In letter to the editor.
Does not accept Uhler’s correlations of the terranes.

200 CAPE COD GEOLOGY

1892. Woopworts, J. B. Note on the occurrence of erratic Cambrian fossils in Neocene
gravels of the island of Marthas Vineyard: Am. Geologist, 9, pp. 243-247. ;

Announces the finding of fossiliferous chert pebbles in the osseous conglomerate at
Gay Head and West Tisbury. These were later shown to be of Silurian age. See U. S.
Geol. Survey Mon. 33, p. 113.

1893. Bryson, JoHn. The glacial geology of Marthas Vineyard compared with that of Long
Island: Am Geologist, 11, pp. 210-212

Points out the striking similarity between the two areas. Differs with Shaler in
regard to the origin of the outwash plain and its channels—hbelieves these were formed
by waters flowing from the glacier. Thinks that the submerged tree stumps do not
necessarily indicate submergence.

1893. Houck, C. Artur. Observations on the geology and botany of Marthas Vineyard:
Trans. New York Acad. Sci., 13, pp. 8-22.

Reviews the previous descriptions of the geology of the island and adds results of
his own observations. Compares the geology of Staten Island and Long Island with
that of Marthas Vineyard. Ascribes the structure of the beds on all three islands to ice
shove.

1894. Dati, W. H. Notes on the Miocene and Pliocene of Gay Head, Marthas Vineyard,
Mass., and on the “land phosphate” of the Ashley River district, S. C.: Am. Jour.
Sci., 3d ser., 48, pp. 296-301.

Gives a list of Miocene and Pliocene fossils from Gay Head and Chilmark, which \

he has identified. Describes two species. |

~ 1894. Hoxnicx, C. Artuur. Dislocations in certain portions of the Atlantic Coastal Plain
strata and their probable causes: Trans. New York Acad. Sci., 14, pp. 8-20. Abstract,
with discussion by N.S. Shaler, in Bull. Geol. Soc. America, 6, pp. 5-7; Am. Geologist,
14, pp. 197-198

Upholds Merrill’s view that the dislocations of the Coastal Plain strata are due to
the action of ice. Gives several arguments in support of this view.

1894. Suater, N.S. Pleistocene distortions of the Atlantic seacoast: Bull. Geol. Soc. America,
5, pp. 199-202. Abstract in Am. Geologist, 18, 143-144; Am. Jour. Sci., 3d ser., 47,
p. 188.
Contends that the folding in the older beds on Marthas Vineyard can not be at-
tributed to the action of ice, because there was a well-developed pre-glacial topogra-
phy, now identified as pre-Wisconsin. Does not admit the possibility of an earlier ice
advance.
1894. WoopwortH, J. B. Postglacial eolian action in southern New England: Am. Jour.
Ser, 3d ser, 47, pp. 63 (1.
Describes several places on the island where postglacial seolian action occurs.
1895. Hoxiicx, C. Artaur. Marthas Vineyard Cretaceous plants [abstract]: Bull. Geol. \
Soc. America, 7, pp. 12-14; Am. Geologist, 16, p. 239; Science, new ser., 2, p. 281. [
Describes about a hundred species of fossil plants; which he assigns to middle
Cretaceous time. Regards them as closely related to those collected from deposits
on Long Island and Staten Island equivalent to the “ Amboy clay series.”
1895. Warp, L. F. The Potomac formation: U. S. Geol. Survey Fifteenth Ann. Rept., pp.
307-397.
Regards the Cretaceous deposits on Marthas Vineyard as the latest phase of the
Potomac.
1896. Marsu, O. C. The Jurassic formation on the Atlantic Coast: Am. Jour. Sci., 4th ser.,
2, pp. 443-447; Science, new ser., 4, pp. 805-816.
Believes that the clays exposed on Marthas Vineyard are Jurassic, because of their
resemblance to the clays of Wyoming and Utah.

CAPE COD GEOLOGY 201

1896. SHater, N. S., Woopworrts, J. B., and Marsut, C. F. The glacial brick clays of
Rhode Island and southeastern Massachusetts: U. S. Geol. Survey Seventeenth Ann.
Rept., pt. 1, pp. 951-1004.

Establishes the age of the older beds. Describes the nature and succession of the
Pleistocene deposits. Shows that the glacial epoch included three great periods of ice
action, which were separated from one another by long intervals.

1896. Warp, L. F. Age of the island series: Science, new ser., 4, pp. 757-760.

States that the fossil flora of the clay beds give indisputable evidence of their age.

1897. Woopwortn, J. B. Unconformities of Marthas Vineyard and of Block Island: Bull.

eol. Soc. America, 8, pp. 197-212. Abstract in Jour. Geology, 5, pp. 96-97; Science,
new ser., 5, pp. 86-87.

Describes in detail the structure and succession of the beds at Gay Head. Lists
seven unconformities. Gives a section of the Gay Head cliffs. Discusses the cause
of the folding and overthrusting and states that absolute proof of the theory of ice
thrust is lacking. States that if this theory is to be accepted the supposed results
must be attributed to two ice advances, which were separated by a long interval.
Both of these advances must have preceded by a long time the last advances.

1898. Dati, W. H. A table of the North American Tertiary horizons correlated with one
another and with those of western a with annotations: U. S. Geol. Survey
Eighteenth Ann. Rept., pt. 2, pp. 327-3

Includes the “Gay Head sands under ae Pleistocene and the “ Gay Head gravels”
under the Miocene. The tables show the relative position of these beds and those of
the same epochs in other parts of North America and Western Europe.

1898. SHaLER, N.S. Geology of the Cape Cod district: U. S. Geol. Survey Eighteenth Ann.
Rept., pt. 2, pp. 497-593.

Contains one chapter presenting a brief summary of the geology of Marthas Vine-
yard. Adheres, in the main, to his previous views.

1898. Woopworts, J. B. Some glacial-wash plains of southern New England: Bull. Essex
Inst., 29, pp. 71-119, Salem, Mass.

Includes description of the Marthas Vineyard plain, which appears to have risen
in the angular space between the two lobes of the ice front.

1899. Upnam, Warren. Glacial history of the New England islands, Cape Cod, and Long
Island: Am. Geologist, 24, pp. 79-92. See U. S. Geol. Survey Mon. 33, p. 118

1900. Packxarp, A. 8. A new fossil crab from the Miocene greensand bed of Gay Bead
Marthas Vineyard, with remarks on the phylogeny of the genus Cancer: Proc. Am.
Acad. Arts and Sci., 36, pp. 1-9.

Describes a new fossil crab, Cancer proavitus.

1900. Woopworts, J. B. Glacial origin of older Pleistocene in Gay Head cliffs with note on
a fossil horse of that section: Bull. Geol. Soc. Amer., 11, 455-460. Abstract in Science,
new ser., £1, p. 102.

Summarizes the evidence that the older Pleistocene bed is of glacial origin. Corre-
lates it with the Columbia because of its stratigraphic position and lithologic char-
acter. Announces the finding of an astragalus of a horse in beds supposed to be
Miocene.

1902. Hoxiick, C. Artur. Geological and botanical notes, Cape Cod and Chappaquiddick
Island, Mass.: Bull. New York Bot. Garden, 2, pp. 381-407.

Includes observations on the topography, glacial deposits, and fossils of Chappa-
quiddick Island. The fossils consist of fragments of mollusks and plants found in the
drift. The plants include several well-known Cretaceous species. The mollusks are
not of the same age as those found at other places, but, according to Grabau, are
probably more recent. Includes a list of the fossil plants, with descriptions.

202
1903

1903

1903
3

1903.

1904.

1905.

1905

CAPE COD GEOLOGY

_ Fuuzer, M. L., and Veatcn, A. C. Results of the resurvey of Long Island, New York:

Science, new ser., 18, pp. 729-731.

_ Ries, Hernricu. The clays of the United States east of the Mississippi River: U. S.

Geol. Survey, Prof. Paper 11, pp. 150-151.

A summary of the economic value of the clays of Marthas Vineyard. Concludes
that the Cretaceous clays are of little value because they occur in highly folded beds.
The glacial clays, which warp in burning, are not well adapted to brick making.

. Veatcu, A. C. Notes on the geology of Long Island: Science, new ser., 18, pp. 2138, 214.
Se . The diversity of the glacial period on Long Island: Jour. Geology, 11,
pp. 762-776.

These two papers by Veatch and that prepared by him in conjunction with Fuller
bring out the following points: 1, That the Cretaceous deposits of the New England
islands generally form the cores of what had been considered morainal ridges; 2, that
there are few, if any, Tertiary beds on Long Island; 3, that several separate ice ad-
vances, with corresponding interglacial intervals, occurred in Pleistocene time; 4,
that the older beds were folded by the action of ice; 5, that the topography of the
last interglacial interval can still be recognized, and that the Wisconsin deposits are
thin.

Cusuman, J. A. Miocene barnacles from Gay Head, Mass., with notes on Balanus
proteus Conrad: Am. Geologist, 34, pp. 293-296.
Barnacles found in connection with the fossil crabs referred to Balanus concavus.
Brown, T. C. A new lower Tertiary fauna from Chappaquiddick Island, Marthas
Vineyard: Am. Jour. Sci., 4th ser., 20, pp. 229-238. Abstract in Science, new ser.,
21, pp. 990-991.

Gives results of a study of the mollusks that Hollick regarded as post-Cretaceous
and classifies them as Eocene. Describes the species as new and different from the
fauna of the Atlantic slope.

. Cusuman, J. A. Fossil crabs of the Gay Head Miocene: Am. Naturalist, 39, pp. 381-390.

Notes the occurrence of concretions in the greensand and describes the fossil crabs
found in these concretions as well as two genera found in other material collected at
Gay Head. A plate shows a restoration of Archaeophax signifera.

1906. Cuapp, F. G. Evidences of several glacial and interglacial stages in northeastern New

England: Science, new ser., 24, pp. 499-501.

1906. Futter, M. L. Clays of Cape Cod, Mass.: Bull. U.S. Geol. Survey No. 285, pp. 482-441.

Correlates on lithologic grounds the clay deposits of Cape Cod with those of Long
Island.

1906 . Glacial stages in southeastern New England and vicinity: Science, new

ser., 24, pp. 467-469.
Announces a scheme for the differentiation of the Pleistocene deposits of Long

Island and southeastern Massachusetts. Finds eight distinct epochs of deposition,

four of which were glacial, and two well-defined long epochs of subaerial crosion.

1906. HoxurcK, C. ArtHuR. The Cretaceous flora of southern New York and New England:

U. S. Geol. Survey Mon. 50, 219 pp.

Reviews the progress of geologic investigation of the Cretaceous deposits of the
region, describes and correlates the plant-bearing beds, and gives systematic descrip-
tions of the plant remains. Describes 222 species of fossil plants and figures many of
them. Assigns part of the flora to the Raritan formation and part to the “ Cliffwood
formation” [Magothy] of the Cretaceous system of the Atlantic Coastal Plain.

1906. Vearcu, A. C. Outlines of the geology of Long Island: U.S. Geol. Survey Prof. Paper

44, pp. 15-52.

1906.

1909.

1910.

1910.

1OLL
1914.

1915.

1917.

1919,

CAPE COD GEOLOGY. 203

The first complete account of the geology of Long Island, in which the author reiter-
ates his previous conclusions. A very helpful paper in the interpretation of the
geology of Marthas Vineyard, whose geologic features are similar to those of Long
Island.

Wuson, J. H. The glacial history of Nantucket and Cape Cod, with an argument for
a fourth center of glacial dispersion in North America, 90 pp., New York, Columbia
University Press. Abstract in Science, new ser., 23, p. 389; Bull. Geol. Soc. America,
17, pp. 710-711 (1907); Annals, New York Acad. Sci. 17, pp. 624-625 (1907).

Summarizes, in two pages, the geology of Marthas Vineyard, and shows by dia-
grams the positions of the Wisconsin ice lobes.

Brssins, A. B. Occurrence of the Magothy formation on the Atlanticislands [abstract]:
Science, new ser., 29, p. 634; Bull. Geol. Soc. America, 20, p. 672 (1910).

Concludes, from recent investigations, that the Magothy formation extends
northward as far as Marthas Vineyard.

Soe ee ee . Magothy formation of the Atlantic Coast [abstract]: Bull. Geol. Soc.
America, 21, p. 780.

JEFrreY, H.C. A new Prepinus from Marthas Vineyard: Proc. Boston Soc. Nat. Hist.,
34, No. 10, pp. 333-338.

Describes a new species of fossil conifer from Gay Head.

Wricut, G. F. The ice age in North America, 5th ed., 763. pp. Oberlin, Ohio.

Futier, M. lL. The geology of Long Island, N. Y.: U.S. Geol. Survey, Prof. Paper 82,
231 pp.

The most complete work on the geology of the northeastern part of the Atlantic
Coastal Plain. Describes the same deposits that are found on Marthas Vineyard.
Establishes the Pleistocene succession not only for Long Island but for Cape Cod and
the other New England islands. Makes possible a satisfactory interpretation of the
geology of Marthas Vineyard.

Berry, E. W. The age of the Cretaceous flora of southern New York and New England:
Jour. Geology, 23, pp. 608-618.

Gives a brief review of the literature on the age of the Cretaceous beds in this
region. Classifies the beds carrying Cretaceous fossil plants as Magothy. Finds no
evidence of the Raritan formation east of Brooklyn

Auten, G. M. The whalebone whales of New England: Mem. Boston Soc. Nat. Hist.,
8, No. 2, pp. 282-285.

Describes the fossil bones found at Gay Head and refers some of them to one
species. Notes the occurrence of fossils, and classifies them according to age. A
plate shows some of the specimens.

Fatrcuitp, Herman L. Postglacial uplift of southern New England: Bull. Geol. Soc.
America, 30, pp. 597-636.

204 CAPE COD GEOLOGY

CHAPTER III
GEOLOGY OF NO MANS LAND

By J. B. WoopwortH

LOCATION

No Mans Land is a small island of glacial drift that lies nearly due south
of Gay Head light and about 4 miles south by west of Squibnocket Point, the
southernmost part of Gay Head. The island rises above the submerged surface
of a broad ridge that extends southward from Gay Head, as if it were a structural
continuation of the island of Marthas Vineyard. The submarine contours of
this ridge are shown on the charts of the U. 8. Coast and Geodetic Survey ' (See
Plate 26). About halfway between the island and Gay Head two large rocks,
known as Lone Rock and Old Man Rock, lie on shoals and are visible in the

water from small vessels plying between Menemsha and the island.

GEOGRAPHIC FEATURES

No Mans Land has a maximum length of 1.6 miles from east to west and a
maximum width of 1 mile from north to south. Owing to the existence of a
small sandspit on its north coast and the incurving of its south coast toward
its northwest point its average width is about half a mile. Its present area is
somewhat less than 1 square mile. At a few places its surface rises to a height
of 100 feet, but most of it lies below this level. The surface is decidedly undu-
lating, consisting of knobs and hollows simulating the morainal deposits of many
typical frontal moraines. The coast of the island on its east and south sides
consists of steep cliffs of boulder clay, other clay, and sand, which are being
rapidly worn away by the sea. The small sandspit that runs out near the middle
of the island on its north side encloses a little lagoon on its eastern flank. This
sandspit appears to have been in nearly its present position in 1602, at the time
of Gosnold’s landing, but according to Brereton’s account, the lagoon on the east
side of the island was then larger, probably extending eastward behind a flying
beach, which has been driven backward and inward with the retreat of the
cliffs at the east end of the island. An old sea cliff, largely grassed over, may

be seen on the north coast west of the sandspit.

1 See chart of Marthas Vineyard, No. 112, 1914, 1/80,000; also chart 1107, showing Southwest Shoal
and neighboring waters.

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CAPE COD GEOLOGY 205

The island is now treeless, but it was forested when Europeans first visited
it. Its surface is strewn with glacial boulders, and the hollows contain small
swamps and beds of peat. In 1915-16 a single farmhouse stood back of the
sandspit, and a few fishing stages or temporary huts on the cliff were being
taken down. The present proprietor of the island has constructed, on the west
side of the sandspit, a breakwater suitable for the protection of a small yacht.
During recent years the island appears to have been used chiefly for grazing sheep.

DESCRIPTIVE GEOLOGY

EARLIER INVESTIGATIONS

Owing to the inaccessibility of the island it has seldom been visited by
geologists. It appears not to have been examined during the first State survey,
made under Edward Hitchcock. It was referred to by Wright ! as the ‘extreme
terminal moraine,” but it was first described by Shaler in his report on the
geology of Marthas Vineyard, published in 1888,” which contained a geological
map of the surficial Pleistocene deposits.

Shaler found that the island consists wholly of glacial drift. He recognized
a lower till or boulder bed, which was overlain by beds of blue clay. Above a
series of beds of fine sand and gravel he found another bed of till, which was
capped in turn by deposits of gravel that he compared with kames. Much of
this surface material, as he noted, ‘‘seems to have been shoved about in the
forward movement of the ice in front of which it was formed.”

The authors visited the island on September 11, 1915, and again on June
14, 1916, in company with W. C. Alden, of the U. 8. Geological Survey.

A walk eastward around the beach of the island from the landing place on
its north side affords an excellent view of the complicated structure of the
folded beds in the cliffs and shows that the form of the surface is independent
of the stratigraphy of the island. This surface truncates formation after formation
from point to point about the island. It shows striking morainal relief in its
hollows and hillocks, but these, like those of the central submarginal moraine
on Nantucket, are the effects of the corrugation of an older surface of erosion,
which cuts across the underlying Pleistocene deposits.

1 Wright, G. F., The Ice Age in North America, p. 123, New York, 1891. (Contains reference to
earlier publications.)

2 Shaler, N. W., Report on the geology of Marthas Vineyard, Seventh Ann. Rept., U. S. Geol. Survey,
pp. 352-353, fig. 63, 1888.

206 CAPE COD GEOLOGY

Pre-Wisconstin DEPOSITS

The deposits in the cliffs may be separated into stratigraphic units below
the uppermost beds of gravel and sand, which are the ‘‘kames”’ described by
Shaler. These beds, however, are remnants of the Hempstead gravel, which
overlies the Montauk till. The Montauk till is strikingly displayed and con-
tains boulders, the largest 6 feet across. This till is hard and compact and
withstands erosion so well that in places it forms projecting buttresses in the
face of the cliffs (See Plate 27, fig. 2). In a part of the cliffs that faces south-
west two beds of such till and intervening deposits of stratified sand and clay
may be seen (Plate 28, fig. 1), but here there may be some duplication by over-
thrust. The Gardiners clay is well exhibited at several places. At one place on
the south coast (see Plate 27, fig. 1), the Gardiners clay, as seen in 1915 and

Fiq. 18.— Contorted Pleistocene beds on the east coast of No Mans Land. A, Moshup till member, 10 feet thick, exposed
above the beach; B, laminated blue Gardiners clay; C, sand, apparently at the horizon of the Jacob sand. The Moshup
till is regarded as a till phase of the uppermost part of the Jameco gravel.

1916, rested on a boulder clay, evidently the lower till mentioned in Shaler’s
report of 1888. This till bed beneath the Gardiners clay should be compared
with the section at Nashaquitsa, where a similar bouldery bed (the Moshup till)
has been exposed for several years in an upturned position, apparently uncon-
formably below the Gardiners clay. (See fig. 18, and Plate 23, fig. 1). The till
at both these places seems to replace the Jameco gravel as the foundation on
which the Gardiners clay rests. The accompanying plate (Plate 27, fig. 1), re-
produced from a photograph taken in 1916, gives an imperfect view of the con-
torted beds.

The cliffs reveal considerable diversity in the direction in which the con-
torted beds are overturned. Many small folds in the upper part of the section
display what appears to be overthrusting to the south or to the west.

As the corrugated surface of the island truncates all the formations exposed

CAPE COD GEOLOGY 207

in the cliffs along its coast, that surface should be regarded as a product of the
erosion of the area since the latest pre-Wisconsin deposit was laid down. As
stated above, the highest beds recognized in the cliffs are the deposits of the
Hempstead gravel, which overlies the Montauk till. In this respect the surface
corresponds in date with that of Marthas Vineyard during the Vineyard interval.
The relation of the peculiar wrinkling of the surface, the pits, and the mounds
to the underlying structure is more clearly shown here than on any other island
in the group. This peculiar configuration may perhaps be a result of the action
of the ice sheet of the earlier Wisconsin advance. What part of the deformation
of the surface should be attributed to shoving, as suggested by Shaler in 1888,
and what part to the differential settling of the underlying deposits is hard to
determine, for some parts of those deposits consist mainly of clay and others

mainly of sand or boulders.

Wisconsin Drirt

The correlation of the upper, highly folded bouldery bed with the Montauk
till and of the overlying beds of sand and gravel with the Hempstead member
leaves little or no drift to be referred to the Wisconsin ice sheet. A rubbly
layer a few inches thick forms the subsoil, and numerous boulders are scattered
over the surface, but their origin is not certainly known. (See Plate 28, fig. 2.)
It seems as reasonable to suppose that they were left on the surface after the
erosion of the contorted beds of boulder clay of the older Pleistocene, as to
refer them to the more recent Wisconsin ice sheet. To those who, considering
only what may be seen on this island, would hold that all these beds of till are
of Wisconsin age, the problem seems very simple; but when we attempt to cor-
relate the formations and the nature of the surface with clearly equivalent phe-
nomena on a larger area, such as Marthas Vineyard, we see that the details of
the topography worked out on the folded beds prior to the deposition of the
Wisconsin moraine on that island indicate that the entire series of folded beds
belong to periods long anterior to the time of the deposition of the surficial
glacial drift of the mainland to the north.

The front of the Wisconsin ice sheet may have extended many miles beyond
No Mans Land. The deposits that have been called the Montauk till and the
Moshup till (the Moshup underlying the Gardiners clay and locally replacing
the Jameco gravel) likewise are products of ice advances that extended beyond
the present island. The broad submarine ridge on which the island stands

may be a morainal accumulation piled up by deposition and displacement in
more than one advance of the ice to this part of the coastal plain.

208 CAPE COD GEOLOGY

The boulders and pebbles on the beaches are commingled derivatives from
the Moshup till, from the Montauk till, and possibly from the Wisconsin de-
posits. No reliable conclusions can be drawn from these erratics regarding the
general drift of rocks at any one ice invasion. These materials may have been
brought to the island during several successive stages. Among the pebbles on
the beaches there were seen red felsite like that which crops out in the Carbon-
iferous area from South Attleboro northward toward North Attleboro; gray
Carboniferous conglomerate; red sandstone of the Carboniferous type seen in
North Attleboro; gray Carboniferous sandstone, probably from the northern
part of the Narragansett Bay region; porphyritic granite; gneiss; black schist,
probably from the western part of the Narragansett Bay region; and quartzite.
One slab of the red Cretaceous sandstone was seen. This fragment must have
been dragged out of Cretaceous beds that lay between the island and the eastern
entrance to Narragansett Bay. A piece of greenish-white slaty quartzite, re-
sembling certain rocks in the Blackstone valley was also seen.

MarRINE ACTION

The eastern and southern coasts are evidently in rapid retreat. The north
coast west of the sandspit appears to have become largely covered with vegeta-
tion owing to a cessation of the attack of the waves and currents on that side —
an attack which apparently went on when the island was larger and its shape
different. Unfortunately no accurate charts of the island are available to permit
a comparison of the old coast line with the present and to show the rate of loss
of land. The boulders derived from the beds of till greatly retard the retreat of
the cliffs and account in part for the preservation of this small island to the

present day.

CAPE COD GEOLOGY 209

CHAPTER IV

GEOLOGY OF BLOCK ISLAND

By J. B. WoopwortH

HISTORY AND GEOGRAPHY

Block Island, or New Shoreham, lies off the coast of Rhode Island, from
10 to 16 miles southwest-by-south of Point Judith. Its southwest point is about
15 miles northeast of Montauk Point, on Long Island, and its eastern coast is
about 37 miles west by south of Gay Head, the western extremity of Marthas
Vineyard. The island is about 6 miles long from northeast to southwest and in
its southern broader part is about 43 miles wide from east to west. (See Plate 29.)

Block Island was known to the aborigines as Manisses, a name preserved
in Whittier’s poem on the wreck of the Palatine. Verazzano gave the island
the name of Claudia in 1624, as certain early maps testify. After the island was
explored by Adrian Block, the Dutch navigator who visited this coast in 1614,
the name Adrian’s Eyland was placed for a time on Dutch maps. Later the
surname of the old navigator became the name of the island. In 1672 a town
charter granted to the island by the Rhode Island Assembly provided that the
“said town of Block Island . . . shall be called New Shoreham, otherwise Block
Island.” The English village name, New Shoreham, which appears in numerous
records and on maps of the island, attests the English settlement of an island
that once lay within the territory of the Netherlands in the New World.

As the English settlement of the island was followed by certain changes
in its features and life that are related to the surficial geology and to certain
geological conditions that are now in part effaced, it seems well to relate briefly
the history of the island.

When Endicott’s expedition visited Block Island in September, 1636, it
‘<wag all overgrown with brushwood of oak,” according to Winthrop’s History
of New England, but there was no good timber on it. Winthrop reports that
the island was said to be about 10 miles long and 4 miles broad, and full of small
hills. We may safely assume that the length thus given was too great, even if
we make allowance for the loss of the small island at Sandy Point, on the north
shore, and for the retreat of the cliffs on the south shore. In the 280 years since
this estimate was made, the south shore, if we assume that it has retreated 3
feet a year, would have stood about 900 feet south of the present Mohegan

210 CAPE COD GEOLOGY

Bluffs. Undoubtedly the island has been greatly reduced in size since the sea
reached its present attitude to the land, a few thousand years ago.

The casual visitor to Block Island is at once impressed by the almost com-
plete absence of trees. Here and there groups of trees planted about houses appear
to enjoy protection from the buildings rather than to shield them from the
wind. These trees were planted in an attempt to restore a condition that existed
long ago. When the island was discovered it was evidently clothed with a
forest that afforded timber and wood to its first settlers. Its deforestation was
a consequence of over-population. The early records mention the forest and
give certain details concerning it, and the remains of trees found in swamps
prove its former existence.

In his “‘history of Block Island,” Livermore,! to whom we are indebted
for much information concerning it, tells of a tradition of the forest, that had
been retained in the memory of the inhabitants as late as 1877, and his research
in documents concerning the inhabitants disclosed several instructive particu-
lars concerning the vanished forest. Thus, the inventory of Robert Guthrige’s
estate in 1692 mentions ‘‘forty-two acres in the west woods at 20 shillings per
acre.” According to Livermore, local regulations made in the first. quarter of
the eighteenth century indicated a growing scarcity of trees available for use
as timber and fuel. By the year 1750, however, the use of small glacial erratics
for the construction of stone fences and of peat taken from local beds for fuel
relieved the anxiety of the inhabitants concerning their vanishing forests. From
this time onward, at least, wood for constructing houses and boats was brought
from the neighboring mainland.

Thus the destruction of the native forest led to the removal of the glacial
boulders from the field and to their incorporation in the remarkable network
of stone fences that now divides the farms. (See Plate 31, fig. 1.) A writer
has estimated that there are about 300 miles of such stone fences, an estimate
which affords some idea of the number or quantity of glacial boulders that were
once scattered over the surface. The forest appears to have been destroyed
mainly by the quest for fuel. Peat, locally called ‘‘tug,’” was not used until
1721, but its use became general about 1750 and it remained the chief fuel used
on the island for fully a century.

The history of the forest is paralleled by that of the aborigines. From a
native population of about 1,000 in 1662, the date of the English settlement

1 Livermore, 8S. T., History of Block Island, Hartford, Conn., 1877. I am indebted to this book for
several notes on the history and condition of the island in past shies as well as for references to changes
which are not apparent to the casual explorer of the island.— J. B. W.

CAPE COD GEOLOGY 211

on the island, the number of Indians had dwindled to 51 in 1774, and a century
later only a single survivor of the race was alive. An occasional stone arrow
or celt found in the soil of the island is now the only witness of their one-time
lordship.

In addition to the map that accompanies this report (Plate 29) there is
available for reference a large-scale map published by the U. 8. Coast and
Geodetic Survey, which shows the topographic features of the island in great
detail! Were it not for the cordons of beaches and strips of marsh land that
connect the several parts of Block Island, it would appear on the map as two
larger and several much smaller islands. The northern part of the island, known
as “Corn Neck” or ‘‘The Neck,’’ rises gently from the western coast to the
steep bluffs of Clay Head and Balls Point, on the east coast. This part of the
island is extended into the waters of the Sound by a sandspit of recent formation,
known as Sandy Point. A dangerous shoal lies farther north, on the site of an
isle that disappeared within historic time.

The main southern part of the island, including the highest elevation,
Beacon Hill, which reaches an altitude of 210 feet above mean sea level, ends
abruptly on the south coast in steep cliffs, 110 to 150 feet high, known as Mohegan
Bluffs, a wall of boulder clay, other clay and sand, which, from the ravages
of sea waves below and rainfall above, displays fallen masses or the gullied slopes
of mountains in miniature. The boulder-strewn beach at the base of these
bluffs is one of the most desolate tracts on the eastern coast of the United States,
an ever-changing ragged coast, the terror of shipwrecked mariners and the
despair of the owners of the land along the brink, who from time to time witness
the fall of their land into the sea.

GEOLOGY

The formations exposed above sea level in the cliffs of Block Island consist
of beds of gravel, boulder-clay, other clay and sand, ranging in age from Upper
Cretaceous to and through Pleistocene. The glacial deposits include boulders
of granite and gneiss derived from the ancient crystalline rocks of the adjoining
mainland. The formations that lie below sea level near the island and the main-
land probably include several hundred feet of beds of Cretaceous clay and sand,
which lie upon the seaward sloping surface of a basement of ancient crystalline

rocks.

1U. S. Coast and Geodetic Survey, Chart 356, scale 1/10,000.

212 CAPE COD GEOLOGY

Pre-CrRETACEOUS BASEMENT

The thickness of the unconsolidated material that lies upon the crystalline
basement rocks is unknown. The only available method of determining the
depth of this basement below the level of the sea is to project beneath the island
the average slope of the remnants of an old surface of these rocks from the
south coast of the mainland. This surface dips about 20° south of east at the
rate of about 30 feet to the mile, whence it is presumed that the bedrock lies
about 540 feet below sea level under the north end of the island, and about 810
feet below it under the south end. This estimate, however, takes no account
of valleys in the surface of the bedrock; it indicates only the general depth.
Faulting along the coast or warping of the ancient rock surface may increase
considerably this estimate of the depth.

The rocks of this crystalline basement, so far as they can be determined
by observing the crystalline rocks on the neighboring mainland, consist of
gneisses, schists, and later granitic intrusives of Carboniferous age or older.
The coal beds of the southern extension of the Narragansett coal field should
lie at similar depths between 10 and 30 miles east of Block Island, under a cover
of Cretaceous sand and clay, upon which lie glacial deposits.

Upper Cretaceous Deposits
CHARACTER AND DISTRIBUTION
The beds of light clay and of dark lignitic Upper Cretaceous clay, found
under most of the islands off the south coast of New England, crop out in small
exposures as beds of white clay on the east coast of the island and at Clay
Head, on the north coast, and as dark lignitic clay at a place back of the beach
near Old Harbor, in the southern part of the island. Nodules containing the
leaves of Cretaceous plants have been found in the glacial drift, showing that
they were derived from Cretaceous beds that lay far north of the site of the
island. |
THE WHITE CLAY
The beds of kaolinite, or white clay, and the associated beds of white quartz
gravel that are folded in with beds of glacial sand and gravel in the cliffs at Clay
Head contain no fossils but are presumably like the neighboring beds of lignitic
clay found at the horizon of the Magothy formation in the lower part of the

Upper Cretaceous series. These beds are found at but few places, and as all the

t
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CAPE COD GEOLOGY 213

beds on Block Island are greatly contorted little can be said of their strati-
graphy or their probable extension from the cliffs into the interior of the island.
The beds of clay seen in Clay Head probably extend for some distance back
from the cliffs beneath the thick beds of gravel and boulders, but the complex
interfolding of the beds of Cretaceous clay with beds of glacial sand and gravel
prevents any reliable theoretical projection of the underground structure.

The higher marine Cretaceous beds that are found on Marthas Vineyard
and in New Jersey, as well as the Tertiary beds seen in the cliffs at Gay Head
on Marthas Vineyard, are not found on Block Island. This series of beds probably
suffered much erosion in this region during pre-glacial time.

THE LIGNITIC CLAY

Beds of lignitic clay are exposed, though poorly, beneath a coating of till in
the low cliff at Old Harbor. Some years ago, when they were better exposed
than they are now, the beds showed anticlinal structure, being much crumpled
on their northern limb. The beds cropped out for about 100 feet along the
shore. The anticlinal fold contained a layer of friable lignite 6 inches thick.
In the northern crumpled part of the section a nearly vertical bed, 3 feet thick,
was then seen. Chunks of lignite showing the structure of wood are occasionally
found in this cliff. Overlying the bed of dark clay there were beds of sandy
clay, which were in places cemented so as to form a reddish, micaceous argilla-
ceous sandstone resembling the fragments of drift found in the overlying Pleisto-
cene formations. Livermore! states that a substance which appears to have
been lignite was found in dredging the harbor many years ago. Beds of lignitic
clay and of white kaolinite like that seen in the bluffs at Clay Head probably

underlie the island not far below sea-level.

FOSSIL FLORA
Hollick ? has collected from the drifted fragments of Upper Cretaceous beds
found in the Pleistocene deposits of the island a dozen species of plants, viz.:

Gleichenta gracilis Heer. (Plate I, fig. 9.)

Protophyllocladus subintegrifolius (Lesq.) Berry (Plate V, figs. 1-6).
Dammara minor n. sp. (Plate II, figs. 35-37.)

Ficus Krausiana Heer. (Plate X, figs. 1-3.)

Magnolia woodbridgensis Hollick. (Plate XX, fig. 7.)

Laurus plutonia Heer. (Plate XXVIII, figs. 1-2.)

1 Livermore, op. cit.,
2 Hollick, Arthur, The Cretaceous flora of southern New York and New England, U. S. Geol. Survey,
Mon. 50, 1906. (See tables on pages 120-128 and the plates and figures indicated in the list.)

214 CAPE COD GEOLOGY

Celastrophyllum grandifolium Newb? (Plate XX XIII, fig. 8.)

Eucalyptus nervosa Newb. (Plate XX XV, fig. 16.)

Eucalyptus Geinitzi Heer. (Plate XX XV, figs, 1-8; 10-12.)

Tricalycites papyraceus Newb. (Plate V, figs. 8-12.)

Widdringtonites subtilis Heer. (Plate IV, figs. 2-5.)

Cyparissidium gracile Heer? (Plate III, fig. 11.)

This flora includes ferns (Gleichenia), coniferous trees (Protophyllocladus,
Dammara, Widdringtonites, Cyparissidum), fig-trees (Ficus), the magnolia, a
laurel (Laurus), probably two species of eucalyptus, a shrub related to the bitter-
sweet (Celastrophyllum), and plant remains of doubtful affinities (T’rycalycttes).
This flora indicates a mild, temperate climate, more like that of the Carolinas
today than the present climate of southern New England. These plant remains
are not marine, but were laid down on a coastal plain like that now seen farther
south. This plain extended along the southern coast of New England, reaching
for an unknown distance out toward the edge of the present continental shelf
and spreading inland over the ancient crystalline rocks of the present mainland.
Meandering streams charged with the products of the weathering of the crystal-
line and other hard rocks of the interior, already much worn down by erosion,
slowly built up a vast plain along a smaller Atlantic basin than that of the
present day. Soon after these plant-bearing beds were deposited the land sank
beneath the sea or the sea rose upon the land and marine beds were laid down,
but these beds have not been found on Block Island.

TERTIARY MATERIAL IN PLEISTOCENE GLACIAL DRIFT

Deposits of the Tertiary system, comprising the Eocene, Oligocene, Miocene
(known on Gay Head), and Pliocene series (found at Gay Head and on Long
Island) have not been found on Block Island. Tertiary deposits are to be sought
along the line of contact between the upper surface of the Cretaceous beds and
the base of the Pleistocene or glacial deposits. This line at Clay Head clearly
marks an unconformity between the Pleistocene and the Cretaceous.

MIOCENE BOULDER
The existence of Miocene deposits on Block Island prior to the glacial
epoch is indicated by a fossiliferous boulder found by W. O. Crosby on the
beach near Clay Head, though possibly this boulder may have been brought
to the beach by some boat.!

1Shimer, H. W., Fossiliferous Miocene boulders from Block Island, R. I, Am. Jour. Sci., 41, pp.
255-256, 1916,

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CAPE COD GEOLOGY 215

EOCENE MATERIAL IN RECENT WRECKAGE

Fossiliferous phosphatic pebbles from a formation having no counterpart
in New England were left on the beach near Southwest Point on July 17, 1877,
by the wreck of the schooner William S. Skull, bound from Port Royal to Vine-
yard Haven. These pebbles, which are light yellow, rather porous, and contain
numerous cavities from which shells had been weathered out, were at first
thought to be peculiar to some Miocene formation not exposed on the island,
but inquiry proved that they came from the Eocene Cooper marl of South
Carolina.

Coal often washes ashore from wrecks on or near the coast of Block Island,
and some pieces of crystalline rock foreign to southern New England may
have been carried to the beaches of the island from wrecks such as that of the
barkentine Alexander Campbell, laden with paving blocks from Maine, which
sank 7 miles southwest of Block Island on November 27, 1888.

PLEISTOCENE FORMATIONS
CLASSIFICATION

Everywhere except along the strand and in the marshes Pleistocene or glacial
formations make up the great mass of Block Island, forming its surface material,
entering into its soil, and constituting its subsoil. These formations are exposed
in the Mohegan Bluffs, on the south coast, and at Clay Head, on the northeast
coast. They were early recognized as mainly of glacial origin and, together with
the surface boulders, were indicated on geological maps as part of the terminal
moraine that is traceable from Nantucket westward across Marthas Vineyard
to Long Island and thence far into the interior of the Continent. Later geologic
work showed that the glacial deposits of the island are divisible into several
beds of boulders, gravel, sand, and clay, and that the surfaces of these beds
show traces of old land forms that were in their time as distinct as the present
surface of the island.

All the boulders, cobbles, pebbles, and granitic sands of the island except
the Cretaceous fragments already described appear to have been carried from
the mainland on the north, several varieties of rock having been identified
with those of ledges that lie as far north as Cumberland, R. I., and George’s
Hill, in Leominster, Mass., The succession of glacial events has been set forth
in the introductory chapters of this report. What is here stated concerning them

1 Dall, W. H. On the “land phosphate” of the Ashley River district, South Carolina, Am. Jour. Sci.,
48, pp. 300-301, 1884.

216 CAPE COD GEOLOGY

presents more local detail. The succession of deposits is shown in the following
list:
Wisconsin till
Submarginal ground moraine of Nantucket substage
Vineyard erosion interval or interglacial stage
Manhasset formation:
Hempstead gravel member
Montauk till member
Herod gravel member
Jacob sand
Gardiners clay
Jameco gravel
Post-Mannetto unconformity
Weyquosque formation
Dukes boulder bed

CHARACTER OF THE FORMATIONS

The Dukes boulder bed consists of waterworn, rearranged, partly cemented
boulders and stones found on Block Island only at Clay Head. The type locality
of this bed is at Gay Head, Marthas Vineyard.

The post-Manetto unconformity is an irregular surface of contact between
the beds just described and the overlying Pleistocene formations. This incon-
gruity is shown on Block Island at Clay Head, on Corn Neck, but is well dis-
played at Gay Head, on Marthas Vineyard.

The Jameco gravel is glacial outwash that in places carries boulders at its
base, if it has been correctly identified at Clay Head. It is believed to be the
product of glaciation that profoundly disturbed and folded the older Pleistocene
and Cretaceous beds at Clay Head.

The Gardiners clay is typically displayed on Gardiners Island, where it
carries marine fossils in its lower part. The beds are extensively exposed in the
lower part of Mohegan bluffs, on Block Island.

The Jacob sand is nearly everywhere a fine sand composed of grains of
quartz, feldspar, and other minerals, such as are produced by the levigation of
glacial material by off-shore waves or gentle currents. In places, beds of fine
gravel lie at the base of the formation.

The Manhasset formation consists of glacial gravel below, known as the
Herod gravel member, followed above by a very thick bed of boulder clay (the
Montauk till member), which in places on Block Island forms two beds separated
by beds of gravel. Upon the Montauk lie the gravel and sand of the Hempstead
member, less well preserved on the island as the result of their erosion.

} : CAPE COD GEOLOGY rae

The Vineyard interval was an epoch of stream erosion prior to the advent
of the last or Wisconsin ice sheet, during which the island was considerably
modified in contour.

The Wisconsin stage of glaciation is represented by the surface boulders
and rubbly till seen in the tops of the bluffs and by a peculiar rolling topography

Siig las rs Seana eas

that masks the stream lines of the Vineyard erosion interval except where those
features were strongly developed. Eskers, true kames, and typical frontal
moraines are wanting on the island.

The distribution of these deposits is described in the text on Clay Head and
the Mohegan bluffs, where they form the chief features in the coastal scenery.

BASAL PLEISTOCENE OF THE CLAY HEAD SECTION
The oldest Pleistocene on the island is exposed in the sea cliff at Clay Head.
In the summer of 1892 the section showed two overturned folds of the beds of
white clay containing granitic gravel and sand, infolded in synclines.!. The
deposits were regarded as Pleistocene because of the fresh feldspar they con-
tained and their lithological similarity to other beds of gravel of glacial origin,
either in the kames, eskers, and sand plains of the mainland or, reworked by the
sea, on existing beaches. No Tertiary deposits were seen between the Pleistocene
} and the Cretaceous beds.
| In the summers of 1915 and 1916 the cliff at Clay Head had worn back
| considerably and the. beds, being comparatively free from talus, were much
better exposed than in 1892. The infolded oldest Pleistocene beds exposed in
clear relations to the Cretaceous deposits consist of fine sandy gravel composed
of subangular bits of feldspar-bearing rocks and quartz of vein origin, derived
from the mainland, along with reddish felsite — an assemblage indicating an origin
from the region about eastern Rhode Island and the adjacent part of Massachu-
| setts as far northeast as the town of Attleboro, where red felsitic rocks now crop
} out. Part of the granitic pebbles are somewhat decomposed and the entire
deposit has a peculiar drab color, which recalls the lower sand beds at the base
of the Pleistocene in Nashaquitsa and Gay Head cliffs, on Marthas Vineyard.
| . In the region to the east this drab color is usually associated with oxidized and
hydrated glauconite or greensand derived from the subjacent Miocene beds, and
it probably has the same significance at Clay Head. At least four closely ap-
pressed overturned synclines inclosing beds of these gravelly sands were exposed

1 Woodworth, J. B., Unconformities of Marthas Vineyard and Block Island, Bull. Geol. Soc. Am.,
8, 1897, pp. 197-212. (See fig. 3, p. 210.)

|

218 CAPE COD GEOLOGY

between similarly overturned anticlines of Cretaceous beds. The isoclinal struct-
ure has a northerly dip of about 45°, and the bottoms of the synclines, or their
turns, were not exposed above the beach. In 1892 the bottom turn of a syn-
cline then exposed stood a few feet above the beach. It appears that as the
cliff retreats these folds, which dip steeply inward, carry their inferior turns
below sea level. The beds may have been overthrust on each fold, but they
are so greatly crushed as to prevent a satisfactory determination of details as
well as of thickness. No traces of fossils were seen.

A mass of rather consolidated gravel and boulders, which appears to be an
extension of the gravel bed shown in the syncline figured by Woodworth? in
1897 was exposed here in 1915. This mass as now exposed is a boulder bed of
glacial origin. It lies in such a position that it may be interpreted as a basal bed
in the syncline in which it is evidently infolded. It shows a gradation from large
boulders at the bottom to gravel at the top, upon which lies finer gravel and
sand. The bed contains numerous ironstone concretions derived from the
Cretaceous formations and small boulders of hardened drab clay derived from
near-by deposits. This bed has evidently been eroded by an ice sheet, but
practically every stone is waterworn, as if it had been exposed to the action
of sea waves. Similar boulder beds are involved in the early highly folded de-
posits at Gay Head. This bed may be modified drift of the earliest ice advance,
a local deposit at the base of the Pleistocene deposits. It is older than the
Gardiners clay, the Jameco gravel, and the icesheet whose thrust folded the
beds that included these early Pleistocene deposits. It is the local representative
of the Dukes boulder bed.

A few rods north of the section just described the blue Gardiners clay
may be seen in an anticline, but its contact with the highly folded mass is not
exposed. Perhaps it may be wrapped unconformably around an uplift composed
of the highly folded beds of the older series. The more significant part of the
section, so far as it could be understood in 1915 and 1916, is shown in fig. 19. The
section is not less important in the investigation of the first glacial invasion
in southern New England than that at Gay Head cliffs. It should be examined
from year to year as Clay Head is cut back by the sea, and the parts now covered
by a deep talus are exposed to view, in order to obtain a more complete record
of an obscure group of deposits, which have been seen only at three or four
places in the New England Islands.

The beds of boulders, gravel, and sand that lie north of the overturned

1Op. cit.

CAPE COD GEOLOGY 219

folds rest unconformably upon them, and the upper boulder bed, which is
probably of Wisconsin age, extends over beds of sand and clay that lie upon
gravel of the same age as that on which these supposed Wisconsin boulders
rest in areas farther south. These beds of sand and clay are older than the
Gardiners clay and the overlying Jacob sand and Manhasset formation, which
come into view still further north in unmistakable character and which have
nothing in common with the beds here considered. On the other hand, although

Ss N

Fic. 19.— Cross section of Clay Head in 1916, showing overturned compressed anticlines
or isoclines accompanied by overthrust. A. Upper Cretaceous white clay; B, Dukes
boulder-bed; C, Weyquosque formation (gravel and drab sand); D, unconformity (post-
Mannetto interval); H, bouldery gravel; F’, glacial sand; G, Wisconsin (?) bouldery drift;
H, subsoil of sand and clay. The beds lettered # and F probably represent the Jameco
formation.
the Manetto stony blue clay till of the Gay Head section has not been recog-
nized in the folded beds at Clay Head, it may antedate the strong overturning
shown at Clay Head, as it does at Gay Head, and the overturning, the erosion
of the folds, and the consequent unconformity may be of the same age in both
sections. As the folded beds in the section at Clay Head lie below the horizon
of the Gardiners clay and do not include the Jameco gravel, the sand and
gravel of the beds lettered E and F in fig. 19 may represent the Jameco forma-
tion, at the base of which is a glacial bouldery deposit not shown so well else-
where.
Just north of the Clay Head folds there is a broad anticline in which the

220 CAPE COD GEOLOGY

Gardiners clay, seen in the axis, is overlain by the Jacob sand, which is in places
contorted. About three feet of fine glacial gravel, which rests on the Gardiners
clay, forms the base of the Jacob sand in this anticline, so that the sand there
is not a transitional deposit.

On the northern gently sloping limb of this anticline an excellent exposure
of the succession above the Jacob sand was seen in 1916. The overlying Herod
gravel included a bed of stony unstratified blue clay or till. Above this glacial
coarse material there is a bed of sand, which passes up into a bed of gravel
about 20 feet thick, upon which lies a typical boulder clay containing a lenticular
bed of gravel, the Montauk till. The surface cuts across this fold, which therefore
antedates the pre-Wisconsin surface of erosion recognized on the island. The
Montauk till also is folded down into the section just north of the Cretaceous
exposures in Clay Head, and is there underlain by the Herod gravel in such
manner as to raise the question whether the opinion that the Jameco gravel
lies upon the Cretaceous folds should not be replaced by the opinion that the
gravel lies at the Herod horizon. Certain details can be learned only after
the slumped part of the cliffs, at the most critical position for exhibiting structural
relations, has been cut back so as to afford fresh exposures.

South of the Clay Head section folded beds of sand, sandy clay, blue clay,
and gravel were exposed in 1916, and south of a small valley that comes to the
coast at that place there was exposed a section of bouldery gravel in a sandy
and clayey matrix, overlain by about six feet of gray clay, the stratigraphic
relations of which are not perfectly clear but which may be an extension of one
of the beds seen farther north.

The Mohegan Bluff section.— Excellent exposures of the older Pleistocene
from the Gardiners clay up through the Jacob sand into the Manhasset for-
mation, with its subdivisions of Herod gravel, Montauk till, and overlying Hemp-
stead gravel, make up Mohegan Bluff (Plate 30) at Southeast Point. The beds
have been thrown into rather gentle folds. No overturned folds such as are
seen at Gay Head in the older basal Pleistocene are commonly found in the

middle Pleistocene.

VINEYARD INTERGLACIAL STAGE

A cursory examination of the summit line of the cliffs of the island reveals
the fact that the beds of Montauk till and the associated beds of gravel (Herod
and Hempstead members) of the Manhasset formation, which form the highest
of the well-developed glacial deposits on the island, are everywhere truncated

|
\
{

CAPE COD GEOLOGY 221

or eroded at the present surface, which bears a thin coating of till, some rubbly
drift, and here and there beds of sand or clay, as well as embedded boulders,
most of them presumably brought here during the last glacial invasion. An
examination of the interior of the island gives some clue to the nature of this
erosion prior to the last glacial stage, after the Manhasset beds were laid down,
for the massive contours of the higher ground show traces of slopes and masked
gullies running down in the manner of the vales left in incoherent strata by the
action of running water. The structure of the Manhasset beds, as shown in
the cliffs, particularly at Clay Head and north of Balls Point, indicates that
the Wisconsin ice sheet deformed them and pushed up, at least to a certain
extent, the highland on Corn Neck; but despite this action and the masking
effect of the glacier upon the antecedent topography, there remains here and
there the appearance of a land surface typical of the Vineyard interval, the
full nature of which is well shown in the upland part of Marthas Vineyard.

The traces of old drainage lines are best seen around the northern slopes
of Beacon Hill, especially on the northeast versant of the hill, where a well-
defined groove widens out downward and the contours of stream work are
slightly masked by subsequent glaciation. Over the greater part of the island
all semblance of the sculpture accomplished by streams is entirely obliterated
by glacial erosion and the deformative work of the Wisconsin ice sheet. (Plate
31, fig. 1.) Owing to this defacement of the pre-Wisconsin topography it is not
possible to say whether the depression between the northern and southern
parts of the island represents the depth of erosion during the Vineyard interval
or whether it was made by the Wisconsin ice sheet.

The flattish areas in the southern part of the island north and west of
Sands Pond, which stand at an elevation of about 120 feet and another area
north of Fresh Pond, standing above 100 feet, appear to be remnants of a
plain or terrace, which was probably larger during the Vineyard interval. Traces
of a pre-Wisconsin surface at about this elevation (100 to 120 feet) are also found

in the eastern part of Marthas Vineyard.

NANTUCKET MORAINE
CHARACTER AND EXTENT
Aside from the beaches and dunes along the coast and the marshes formed
in the shallow, protected embayments, chiefly between the northern and south-

ern parts of the island, the entire surface is covered with a thin mantle of
bouldery drift of the Nantucket moraine of the Wisconsin stage of glaciation.

222 CAPE COD GEOLOGY

The glacial boulders and other drift of this sheet appear to be rather uni-
formly distributed over the island, the mounds, ridges, and hollows of the
surface being possibly due in part to irregularities in the thickness of the drift
but more likely to the effect of the deformation of the surface by the kneading
of the incoherent largely clayey beds by the overriding ice. Neither in the align-
ment of these ridges and hollows nor of such boulders as have not been gathered
into walls is there indication of any considerable frontal moraine. Such deposits,
if formed at all, must have accumulated south of the present land area on a
surface that has been cut away by the sea or that now lies below sea level. The
surface of the island, which may be called a corrugated moraine, is very similar
to that of the northern half of Nantucket, where this type of topography was
developed half a mile to a mile or more back of the ice front. Therefore, although
Block Island was moulded beneath the ice sheet in the manner described, the
front of the ice at the time its surface was formed may have been 1 to 5 miles
south of the existing south coast of the island.

The axes of the corrugated moraine of the island in Corn Neck, north of
the central depression, extend nearly westward, but those in the main body
of the island, farther south, particularly in its western half, trend southward.
These features are brought out best by the detailed chart of the island published
by the United States Coast and Geodetic Survey.

The westward trend of the ridges and hollows on Corn Neck coincides with
the trend of the axes of the folds seen in the cliffs at Balls Point. The beds in
Mohegan Bluffs, on the south coast, show several rather gentle folds, which
have axes nearly normal to the coast line and are essentially in agreement with
the trend of the formations of the inland surface.

The corrugations on Corn Hill thus appear to be the effect of pressure
acting from north to south, in the general direction of the motion of the ice.
This direction is shown not only in the older folded beds below the Jameco
formation but in the broadly folded Manhasset formation. The folding in
the area south of the depression occupied by Great Salt Pond seems to have
been produced by pressure acting from the east or west, and as this folding
is more clearly shown’ in the west half of that area the pressure probably came
from the west. This conclusion is borne out by some small folds in Mohegan
Bluffs, which have been overturned toward the east. As Upham many years
ago pointed out, Block Island lies in an interlobate position, in the axis between
the Narragansett Bay lobe and a broad lobe on the west. The moraines near

1U. 8. Coast and Geodetic Survey, Chart No. 356, scale 1/10.000.

|
|

ser

)
|
j
:

CAPE COD GEOLOGY 223

Exeter and Slocum, R. I., show that the interlobate axis lay about in longitude
71° 32’ W. when the ice front had retreated to that locality, and that the axis
was but slightly west of that position on the west side of Point Judith when
the ice front stood at the Charleston moraine, trending west of south, toward
Block Island. Thus the push from the ice lobe moving over the island from
Block Island Sound caused the topographic trend noted. The accentuated
area lies west of a line skirting from north to south the west coast of Corn Neck,
on which there are traces of a topographic trend from northwest to southeast,
parallel to the western border of an ice lobe that issued from the Narragansett
Bay depression.

A number of small shoals that lie off the south coast, where the bottom
is from 12 to 14 fathoms deep, may be wave-levelled tracts of submerged frontal
moraine. A shoal extends southwestward from Southwest Point to Southwest
Ledge. It has a minimum depth of 43 fathoms and the sea breaks on it in
heavy weather. This shoal is produced by an extension of the glacial formations
of the island toward Montauk Point; but the materials on Southwest Ledge may

be largely pre-Wisconsin.!

GLACIAL BOULDERS

The surface of Block Island, according to all accounts, was originally thickly
strewn with glacial erratics of all sizes. The largest boulder seen by the writer lies
on the northern slope of Pilot Hill, about half a mile from its summit. As meas-
ured in 1893 it rose 6 feet above the surface of the ground and was 15 feet 10
inches across. About in the middle of the eighteenth century the scarcity of
wood for fences, combined with the increase of agriculture, led to the clearing
of the fields and the construction of stone fences. Many cartloads of stones that
were too small for use in making fences were thrown into the kettles and hol-
lows at the bottoms of the hills, so that only a few small tracts were left in
something like their natural state.

The boulders on the surface of Block Island were perhaps brought to their
present positions from the mainland by the Wisconsin ice sheet. Although these
erratics were derived from the mainland, it is not certain that any particular
boulder was carried to the island during the last ice invasion, for the erosion
of the older folded boulder beds on the island suggests that boulders from these
beds became commingled with the latest drift from the mainland. For this
reason particularly it is impossible to determine whether the boulders and

1See U. S. Coast and Geodetic Survey Chart No. 1211 (Block Island Sound) July, 1912.

224 CAPE COD GEOLOGY

pebbles now on the beaches of the island were brought in during one ice advance
or another, for the material in all the boulder beds and pebble beds is very similar,
the chief difference being that many kinds of rocks in the older boulder beds
are much disintegrated, although their disintegration is not everywhere apparent.
Boulders found on the beaches, therefore, even if they certainly came from
the cliffs, have little significance in determining the direction of movement
or the ice sheet during any particular epoch. The following observations were
made with this precaution in mind.

DIRECTION OF DRIFT SHOWN BY BOULDERS

Some boulders seen on Block Island can be traced to well-defined outcrops

on the mainland.
CUMBERLANDITE BOULDERS

One of the most distinctive rocks of southeastern New England is the so-
called Cumberland iron-ore or peridotite of northeastern Rhode Island. The dis-
tribution of boulders and fragments of this rock in areas south of its outcrop
was described in 1893 by Shaler, who had not at that time extended his obser-
vations to Block Island. In August of that year a boulder of this rock weighing
ten pounds was found on the shore of the island on the west side of the point
on Mohegan Bluffs, south of Fresh Pond. Another boulder, 2 feet long, 18 inches
wide, and 1 foot thick was found near by. The smaller of these two boulders
may have been brought to the island by fishermen as ballast in a boat, but the
larger boulder was probably not transported by human agency. Boulders of this
rock are found as far east as Gay Head, on Marthas Vineyard. The boulders
on Gay Head lie 30 miles east of the meridian passing through the place of their
origin, but those found on Block Island lay scarcely 10 miles west of that meri-
dian. As the ice moved, at least during the Wisconsin stage, nearly southward
through Narragansett Bay, deploying lobewise to Block Island on the southwest
and toward Gay Head on the southeast, with an axis of southward striation on
the site of Newport, it is evident that Block Island lay well within the limit of
the fan of erratics that were spread southward by the lobes of ice that moved
at different times from the Narragansett Bay region.

Glacial striae on the west shore of Narragansett Bay north of Point Judith
indicate the direction of transportation of drift to Block Island, as follows:

Narragansett Pier, on high granite bluff south of railroad

terminus ........ ee ps. 19° W.

Hose Hi, Wace bok... ee... ©. 21 WW.

\
[

CAPE COD GEOLOGY 225

Point Judith Neck, east shore, 13 miles south of Narragansett

Piet S. 19° W. and
S. 29° W.
Tittle Neck above the Natrows........ --.. = =... - «=. S. 27 W.

These glacial striae at places examined in succession southward show an
increasing trend westward, which is a normal result of the outward curvature
of the lines of flowage of the bottom ice in a glacial lobe. The island bears between
15° and 37° west of south from Point Judith, and it came well within the reach
of ice moving down the west side of Narragansett Bay and deploying as a lobe

between Gay Head and the interlobate axis described above.

UPPER CAMBRIAN QUARTZITE PEBBLES
Waterworn fragments of an Upper Cambrian quartzite or sandstone con-
taining small fossil branchiopods are found on the beaches of Block Island. Such
fragments are found also in the Carboniferous conglomerate near Newport, mi,
as well as farther north, in the Rhode Island coal field. Walcott found some
among the pebbles on the beach at Westerly, R. I.

AGATES

Fragments of impure or clouded or banded red and white agate are found
on the beaches of the island, as well as in the oldest Pleistocene deposits at
Clay Head. Some fragments as large as 6 inches in diameter have been seen
on the beach south of Clay Head. Some pieces of this agate contain a trace of
a reddish shaly country rock, which suggests that they were brought from
the area of red Carboniferous beds that are associated with volcanic rocks
and veins of quartz in the country between South Attleboro and North
Attleboro, Mass., and Diamond Hill, R. I. The mass of quartz at Diamond
Hill bears the closest resemblance to these agates, but so far as is now known
no agate has been found at Diamond Hill. The pebbles of agate are found on
the beaches on Block Island, on the north shore of Marthas Vineyard, and
as far east on the Elizabeth Islands as Tarpaulin Cove. The southward fanning
of these small erratics is like that of the Cumberland iron ore, but the fan extends
farther eastward. Cumberland Iron Mine Hill and Diamond Hill, in Rhode.
Island, lie respectively 3 and 5 miles east of Woonsocket, and the eastward
fanning of the drift tailings is consistent with the ‘positions of the Diamond

Hill quartz mass and Iron Mine Hill.
Along with the agate pebbles on the beaches at Naushon, on Marthas
Vineyard, and on Block Island there are vein quartz pebbles having the peculiar

226 CAPE COD GEOLOGY

encrusting growth of quartz that is seen on the pebbles found at Diamond Hill
and a few other places within a radius of five or six miles from it. On Block
Island there are also pebbles of vein quartz in the drift on beaches where the
country rock is a black schist, undoubtedly one of the Carboniferous rocks
that crop out in Narragansett Bay. This material confirms the impression
made by the agates carrying a reddish shaly trace of the country rock, namely,
that the source of all these veinstones lies in exposures of rock swept over by
glacial sheets moving southward through the Narragansett Bay region.

CHIASTOLITE SCHIST PEBBLES

Pebbles and glaciated fragments of the well-known chiastolite schist of
George Hill, in the town of Lancaster, Mass., are found on Block Island. A
fragment of this rock was found on the beach under Mohegan Bluffs about a
mile west of Southeast Light in 1915, and pebbles of the same material were
found on the east beach south of Clay Head in 1916. The andalusite phyllite
of George Hill is known only in boulders, but these boulders may have been
derived from rock in place there beneath the glacial drift. The distance from
George Hill to the south coast of Block Island is about 91 miles, in a direc-

tion 3° east of south

ABSENCE OF KAMES AND ESKERS
Sections along the shore of Great Salt Pond and elsewhere on the island
show stratified beds of gravel, sand, and clay, but wherever the stratigraphic
position of these beds has been determined they have proved to be pre-Wisconsin
glacial deposits. No stratified Wisconsin glacial deposits that have a distinctive
topography are found on the island.

Post-GLACIAL oR RECENT Deposits

After the Wisconsin ice sheet disappeared the vegetation of the island, in-
cluding that in the peat bogs and marshes, began to grow in sheltered positions
along the shore of the sea, but no trace of vegetation is found on the surface of
the Wisconsin drift of the island above its present swash line. Vegetal deposits
were laid down in swamps and peat bogs of fresh-water origin and in marine

marshes.

‘ For references to the andalusite and chiastolite phyllite of Lancaster, consult C. T. Jackson: An
account of the chiastolite or nacle of Lancaster: Boston Jour. Nat. Hist., 1, pp. 35-62, 1837. See
also Perry, J. H., and Emerson, B. K., The geology of Worcester, Massachusetts, p. 28, 1903.

re

CAPE COD GEOLOGY 227

FRESH WATER SWAMPS AND PEAT BOGS

Most of the swamps and peat bogs lie on the south side of the island, along
the west coast, and along the east coast between Harbor Pond and Sands Pond.
They occupy depressions that are presumably of less depth than those which
form the site of the numerous so-called ponds or glacial lakelets of the upland
parts of the island. All the depressions now occupied by swamps were originally
lakelets in which aquatic plants took root. By the addition of other plants, in-
cluding some trees as soon as the vegetable mat permitted their growth, the
depressions were filled to the level at which water will stand in them.

Nearly all the swamps yield peat. No exact estimate of the quantity of this
peat has been made, but peat was used as fuel from about 1750 until after 1875,
in which year 544 cords were dug on the island. According to Livermore * peat
has been found on the west coast from highwater mark to a line a quarter of
a mile out in the sea.

MARINE MARSHES

The vegetal deposits in tidal water are limited to small patches, most of
them along the shore of Great Salt Pond. This body of water appears to have
had no direct connection with the sea when the island was settled in 1662.
About 1686 an opening was made in the beach on the west side in an attempt
to form a harbor, which was made but not long maintained. In 1873 another
opening was made, which has been enlarged, and the water of the so-called pond
has fallen to sea level, with consequent effects on the growth and the area of the
marsh bordering it.

WAVE AND CURRENT ACTION

The striking effect of the action of the sea on the coast of the island is seen
in the steady erosion of Mohegan Bluffs, on the south coast, and of the cliffs at
Clay Head. Wave cutting has been everywhere somewhat abated by the bould-
ers and smaller erratics that accumulate on the beach. Some of these were
derived from the Wisconsin drift that lies on the surface of the island, but many
more were derived from the wasting of the bed of Montauk till. At certain
points where this bed stands at a high angle in the bluffs the boulders that have
accumulated on the beach reveal at once their source.

The large quantity of clay in the Montauk till and in the underlying Gar-
diners clay causes numerous landslides. Large slices of the bluff slip down.
Certain gullies show that rainwater helps to carry the bluffs back above the

1 Livermore, S. T., A history of Block Island. Hartford, Conn., 1877, p. 29.

228 CAPE COD GEOLOGY

reach of the waves, which undermine and remove the materials delivered by
landslides to the beach. No exact estimate of the rate of recession of Mohegan
Bluffs is available, but the Coast Survey chart of the island issued in 1914,
which shows the coast line as it existed in 1913, furnishes a basis for concise
comparisons in future years.

Sandy Point, at the north end of the island, is continued under water as a
long, narrow spit or bar to the site of an island that was tied to Block Island
by a bar that was passable on foot at low tide. According to Livermore, the land
at the end of the point, which was called ‘‘the Hummock,” was a small elevation
covered with bushes and small trees, including wild plum trees. It appears to
have been washed away about a hundred years ago. Sandy Point now stands
at the north ends of two beaches, one crescentic in form, making southeastward
past Cow Cove toward Grove Point, and the other forming the straight shore
of the west side of Corn Neck. Between these two beaches lies Sachem (Chagum)
Pond. The beach on the west side is backed by a line of dunes.

The beach on the west side, at Great Salt Pond, is tied to two small drift
‘islets, which partly inclose that body of water.

Crescent Beach, on the east coast, is the longest stretch of beach on the
island that is unbroken by headlands, and is near the center of population during
the summer. In the southern part of Corn Neck it is cut back into low bluffs,
and farther south it is thrown across what would otherwise be open passageways
into Great Salt Pond. The beach is swept by gales that veer from northeast
round to southeast and is constantly undergoing minor changes that involve
a slow gain of the sea upon the land. It is notable for its fine black sand, most
of which accumulated in the form of dunes south of its mid-point. The beach
has derived a large share of its material from Clay Head, but some pebbly
drift is fed into it from the bluffs south of Clay Head.

Were it not for the southern stretch of this beach the sea would pass freely
between the two main parts of the island. At least two or three small islets of
glacial drift that lie in or near these cordons of sand are tied by them to the
island. (See Plate 31, fig. 2.)

DUNES AND WIND ACTION

Narrow tracts of low dunes that are well tufted with beach grass lie back
of the east beach and along the west side of Corn Neck. The sand is com-
posed mainly of quartz, garnet, and black iron ore or magnetite, which are
washed by the waves out of the glacial drift. The magnetite sand deserves

special mention because of its local abundance.

CAPE COD GEOLOGY 229

THE BLACK-IRON SAND OR MAGNETITE

The east shore of Block Island, along the bathing beach, abounds in mag-
netic iron sand, which is blown up into low dunes, from which, in years past,
the market was supplied with blotting sand in the days of quill pens. (Plate 32,
fig. 1.) Many years ago a large horseshoe shaped magnetic separator was devised
and installed in a factory on the beach. The remains of this instrument, in-
cluding the huge magnets, were seen as late as 1916. (See Plate 32, fig. 2.)

In the early 90’s Edison! investigated the black sand of Long Island by
boring holes along the beach and inland. He found that along the beach in one
year there was an aggregate thickness of 12 to 15 inches of black sand for 8 or
10 miles; yet in the next year hardly any could be found. He therefore abandoned
the attempt to treat the deposits commercially.

The black magnetic iron sand of Block Island is washed out of the glacial
drift along the shore by the sea. The drift on the island carries much waste
derived from beds of magnetiferous schist of Carboniferous age in the Narragan-
sett Bay region. These beds are probably the chief source of the magnetite,
but minute crystals of magnetite are abundant in many igneous and crystalline
rocks of southern New England, and Shaler found that traces of magnetite
are very generally distributed in the glacial sand in this region.

GREAT SALT POND

The largest body of enclosed water on the island is Great Salt Pond, which
has an area of about 1,000 acres. It occupies a great depression between the
northern and southern parts of the island and in places reaches depths of 52
feet below mean sea level. The bottoms of Trims and Harbor ponds, which
lie southeast of Great Salt Pond, also lie below sea-level. Great Salt Pond is
separated from the sea on the west by a cordon of beach sand, which ties in two
small islets of glacial sand. Between these islands a navigable canal has been
dredged to a minimum depth of 25 feet. An earlier canal dug north of these
islets is now filled with sand. Crescent Beach, on the east side of Great Salt
Pond, forms a barrier extending from the Harbor to the southern part of Corn
Neck, but it includes islets of glacial material, from which much coarse debris
is eroded. Between the beach and Great Salt Pond a small islet, which has cliffs
on its west side, supports a small barrier beach that partly separates Trims
Pond from Great Salt Pond.

Great Salt Pond, by reason of a channel cut through the western barrier

1 Edison, Thomas E., Letter to J. B. Woodworth dated Nov. 22, 1893.

230 CAPE COD GEOLOGY

beach, now forms an excellent harbor of refuge for coastwise steamers and is
resorted to by naval vessels engaged in manoeuvers in the neighboring sea.
Although the northward drift of the sand along the beach threatens to close the
canal, its value will justify the occasional expense required to maintain it.!

At the north end of Great Salt Pond a small island is so tied in by crescentic
beaches as to cut off from the main body of water a small lagoon. On its north-
east side this lagoon has in turn thrown a crescent barrier beach across a yet
smaller indentation of its shore line. Both these barrier beaches were doubtless
produced by similar processes, but they came into existence in succession, the
earlier having been formed at the original head of Great Salt Pond. Both are
examples of what Gulliver has called ‘‘bay-bars.”

ECONOMIC GEOLOGY

The black-iron sand of the island was gathered and shipped at one time
for commercial use, as already noted. The white Cretaceous clay or ‘‘kaolinite”’ |
at Clay Head is not favorably located for commercial exploitation, and the |
quantity available is not certainly known.

The water resources of the island are adequate to supply the usual popu- |
lation and passing vessels. Some of the high-lying ponds on the main part of
the island furnish supplies of potable water. These ponds appear to lie in hollows
over the Montauk till, the clay of which forms an impervious bottom for water
derived from the gravel and sand that overlies the boulder clay.

A few wells have been driven on the east side of Block Island to obtain water
for the use of the summer hotels. Boulders may be encountered at three horizons. |
Beneath the upper boulder clay (Montauk) a well should encounter beds of water- |
bearing gravel (the Herod), which is underlain by beds of sand (Jacob) and
fine gravel. These beds occur at all levels from the surface to and below sea
level, and as they are in places folded and contorted no rule can be given to
determine the depth at which water-bearing gravel or sand may be found at
any given place on the island.

*C. T. Jackson’s map of Block Island, the result of a reconnaissance survey made in October, 1839,
shows an entrance into Great Salt Pond which lay north of the present canal and was known as “Old
Breach.” See report on the Geology of Rhode Island, 1840.

2 See Shore-line topography, pp. 201-206.

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CAPE COD GEOLOGY 231

BIBLIOGRAPHY OF THE GEOLOGY OF BLOCK ISLAND

Block Island was included in an official survey made in 1839 by Dr. C. T.
Jackson.t Numerous references to the geological features of the island are
made in the writings of geologists who have investigated either the Cretaceous
clays or the terminal moraine, particularly during the last quarter of the nine-
teenth century.

A few references to the literature dealing with the island may be found in
a report on the geology of Rhode Island published by the Providence Franklin
Society in 1887. This work cited no publication earlier than Jackson’s report
of 1840.

Bibliography of Block Island

1840. Jackson, C. T. Report on the geological and agricultural survey of the State of Rhode
Island, 312 pp., map, Providence. Notice by B. Silliman, Jr., in Am. Jour. Sci. and
Arts, 40, pp. 182-194 (1841).

Gives the results of a survey of Block Island made in 1839. Describes the topog-
raphy and geology. Compares the granite of the boulders to the granite in the region
about Kingston and infers that the boulders were derived from that region. Calls the
boulders and the soil in which they are embedded “ diluvial”’ and the underlying beds
“Tertiary.” Finds that this underlying formation consists of alternate beds of clay
and white sand. Notes that bog iron is mixed with gravel at the south end of the
island and at Clay Head, where the beds are folded and dip to the northwest. De-
precates the former ruinous practice, sanctioned by the town of New Shoreham, of
selling cobblestones from the shore for paving the streets of New York and the
consequent loss of land on the south coast.

1843. Matuzr, W. W. Geology of New York, Part I, comprising the geology of the first
geological district, 653 pp., ills., map, Albany.

Thinks that Long Island was once connected with Block Island.

1875. Dana, J. D. On southern New England during the melting of the great glacier: Am.
Jour. Sci., 3d ser., 10, pp. 409-438.

States that Block Island and other islands off the south coast of New England are
composed largely of unconsolidated preglacial beds, which are in places upturned and
folded. Regards these beds as probably Tertiary.

1881. Wapswortn, M. E. A microscopical study of the iron ore or peridotite of Iron Hill
mine, Cumberland, R. I.: Bull. Mus. Comp. Zoélogy, Harvard Coll., 7, pp. 183-187;
Science, 2, pp. 368-370. Abstracts in Harvard Univ. Bull. 19, p. 219; Proc. Boston
Soe. Nat. Hist., 21, pp. 194-197 (1882).

Includes chemical analyses of the rock and a petrographic description.

1887. PRovIpDENCE FRANKLIN Soctety. Report on the geology of Rhode Island, 130 pp., ills.,
Providence. Includes a paper by C. T. Jackson entitled “Catalogue of rocks, min-
erals, a soils collected during the geological survey of Rhode Island in the summer
of 183 :

a most of the references here given to the bibliography of the geology of Block
Island.

1C. T. Jackson, Report on the geological and agricultural survey of the State of Rhode Island . . .
in 1839. Providence, 1840. Contains a geological map of Rhode Island.

232

1890.

1893.

1895.

1896.
1896.

1896.

1896.

1896.

1897.

1897.

1898.

1898.

1899.

1899.

1899.

1908.

1910.

1914.

CAPE COD GEOLOGY

Dana, J. D. Long Island Sound in the Quaternary era, with observations on the sub-
marine Hudson River channel: Am. Jour. Sci., 3d ser., 40, pp. 425-437.

Discusses the evidence of a submarine channel of Hudson River between Montauk
Point on Long Island and Block Island in the light of glaciation and tidal scour. At-
tributes to tidal scour the deepening of the channel from 12 to 30 fathoms.

Suater, N.S. The conditions of erosion beneath deep glaciers, based upon a study of
the boulder train from Iron Hill, Cumberland, R. I.: Bull. Mus. Comp. Zodlogy,
Harvard Coll., 16, pp. 185-225, map.

The boulders at Iron Hill, on the south shore of Block Island, were not discovered
until after this report was published, and the accompanying map therefore does not
show those boulders.

Coun, G. L. The geology of Conanicut Island: Trans. Wisconsin Acad. Sci., 10, pp.
199-230.

Houck, C. Artuur. The geology of Block Island: Science, new ser., 4, pp. 571-572.

----------—— . Geological notes, Long Island and Block Island: Trans. New York
Aead. Sci., 16, pp. 9-18. Abstract in Science, new ser., 4, pp. 695-696.

Marsa, O. C. The geology of Block Island: Am. Jour. Sci., 4th ser., 2, pp. 295-298,
310-811.

Merritt, F. J. H. Notes on the geology of Block Island: Trans. New York Acad. Sci.,

pp. 16-19,

Suaver, N. §., Woopworts, J. B., and Marsut, C. F. The glacial brick clays of
Rhode Island and southeastern Mssseech uote: U.S. Geol. Survey Seventeenth Ann.
Rept., pt. 1, pp. 951-1004.

Crossy, W. O. Contribution to = ee of Newport Neck and Conanicut Island:
Am. Jour. Sci., 4th ser., 3, pp.

Woopworty, J. B. He = eae Vineyard and of Block Island: Bull.
Geol. Soc. America, 8, pp. 197-212, map. Abstract in Jour. Geology, 5, pp. 96-97;
Science, new ser., 5, pp. 86-87.

Eaton, G. F. The prehistoric fauna of Block Island, as indicated by its ancient shell
heaps: Am. Jour. Sci., 4th ser., 6, pp. 137-159, maps.

Houuick, C. Artaur. Notes on Block Island: Annals New York Acad. Sci., 11, pp.
55-72. Abstract in Am. Geologist, 21, pp. 200-201.

Kemp, J. F. Granites of southern Rhode Island and Connecticut, with observations on
Atlantic Coast granites in general: Bull. Geol. Soc. America, 10, pp. 36-382; Abstract
in Am. Geologist, 23, pp. 105-106; Science, new ser., 9, pp. 140-141.

UpHam, Warren. Glacial history of the New England islands, Cape Cod, and Long
Island: Am. Geologist, 24, pp. 79-92.

SHAtER, N. S., Woopwortu, J. B., and Forrste, A. I’. Geology ot the Narrangansett
Basin: U. S. Geol. Survey Mon. 33, pp. xx, 402, 31 pls.

JoHNSON, B. L., and Warren, C. H. The petrography and mineralogy of Iron Mine
Hill, Cumberland: Am. Jour. Sci., 4th ser., 25, pp. 1-38. Includes a paper by Johnson
entitled ‘“ Notes on the history and geology of Iron Mine Hill.”

The authors call the rock “cumberlandite.”

Loves, G. F. Intrusive granites and associated metamorphic sediments in south-
western Rhode Island: Am. Jour. Sci., 4th ser., 29, pp. 447-457, map.

Warren, C. H., and Powers, Smpnty. Geology of the Diamond Hill-Cumberland dis-
trict in Rhode Island-Massachusetts: Bull. Geol. Soc. America, 25, pp. 435-476.

The papers published from 1881 to 1914 relate to the igneous and sedimentary rocks
of the mainland that lay in the path of the glaciers that advanced to Block Island.

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CAPE COD GEOLOGY 233

They afford clues to the sources of many peculiar boulders and pebbles found in the
drift of Block Island.

1916. Sumer, H. W. Fossiliferous Miocene boulders from Block Island, R. I.: Am. Jour.
Sci., 4th ser., 41, pp. 255-256.

PART III

GEOLOGY OF CAPE COD AND THE ELIZABETH ISLANDS

CHAPTER I
GEOLOGY OF CAPE COD

By J. B. WoopwortH

GEOGRAPHY

Cape Cod proper is a modern sand bank built up at the north end of a remark-
able peninsula that extends as a great hook into the sea from the southeast corner
of Massachusetts, but the name Cape Cod is commonly applied to the peninsula
itself, which may be defined as including the land between Cape Cod Bay and
Nantucket Sound and even the land still farther west, between Cape Cod Bay
and Buzzards Bay. The precise boundary between Cape Cod and the mainland
may be conveniently drawn to follow the Cape Cod Canal and Manomet Creek,
but it may be drawn from the head of Buzzards Bay northeastward across the
narrow neck of land that separates Buzzards Bay and Cape Cod Bay to a point
midway between Sagamore Beach and Peaked Cliff, on the shore of Cape Cod
Bay. In the official language of the Commonwealth of Massachusetts Cape Cod
is synonymous with Barnstable County. The Elizabeth Islands, which le farther

southwest, form a part of Dukes County.

LOCATION AND AREA

Cape Cod lies between parallels of 41° 30’ and 42° 5’ north latitude, and
meridians 69° 55’ and 70° 46’ west longitude. It presents a rectangular outline
to the ocean, and its southern coast is fended from the open sea by the islands
of Nantucket and Marthas Vineyard. It has a milder climate and on the whole
warmer sea water on its southern than on its eastern and northern coasts. The
eastern coast, which trends west of north, is exposed to the waves of the Atlantic
the effect of which is moderated by an extensive offshore submarine shoal known
as Georges Bank. The southern, broader part of the peninsula, which extends
eastward from Buzzards Bay, has not inaptly been called the arm of the Cape.
The narrow extension that rises at right angles to this part has been called the
forearm of the Cape, and the incurled sand bars at the north end have been
called the fingers or hand.

The area of Barnstable County in 1894 was 434 square miles.| The area
of the coastal lands, particularly those on the forearm of the Cape from Nauset

1 Henry Gannett, A Geographic dictionary of Massachusetts, Bull. U. S. Geol. Survey, 116, p. 10,
1894.

238 CAPE COD GEOLOGY

Harbor northward to Highland Light, has been gradually reduced by the inroads
of the sea ever since the country was settled, and although small areas of beach
flats are built up from time to time between headlands or at the east side of
the end of the Cape, the total area of the Cape is reduced a few acres every year.

TOPOGRAPHY

The Cape Cod district is a partly submerged mass of glacial material, which
consists of the Plymouth interlobate moraine on the west side of Cape Cod
Bay, other interlobate glacial deposits on the east side of the Bay, and a lobate
moraine whose frontal outwash plain extends from Chatham to Falmouth and
is bordered on the west by the moraine of a glacial lobe that lay west of the
Plymouth interlobate axis. Cape Cod Bay lies in the broad, shallow depression
that was occupied by the glacial lobe about which the deposits of the Cape
are grouped.

The south side of the Cape along the shore of Buzzards and Cape Cod bays
is traversed by morainal hills, which in places in and near the town of Sandwich
reach a height of 200 feet above sea level. The plains south of this belt of morainal
country rise to the same elevation as the hills in Sandwich and decline southward
to or nearly to sea level, although they usually confront the Sounds with a low
bluff. The inner limit of the plains decreases in height both ways from the
axis of the moraine in the northern part of the town of Sandwich, south of the
Manomet creek passage.

The arm of the Cape from Nauset harbor northward consists of three well-
defined plains, which lie back of the morainal belt. Two of these tracts, the
‘‘Nauset”’ or Eastham plain and the plain in North Truro (see Plate 25, fig. 2),
stand between 60 and70 feet above sea level. Between them lies the deeply creased
high plain of Wellfleet and Truro, whose surface attains a height of 150 feet.
The tip of the Cape is formed by a large hook of beach sand and dunes, partly
enclosing Provincetown harbor. Another large sand bar, or a series of sand
bars, lies at the southeastern versant of the Cape. In the coastal lagoons and in
the inlets, particularly those bordering Cape Cod Bay, there are large tracts of
marshland.

On the side of the Cape facing the ocean there are steep cliffs of gravel and
sand, and on the arm of the Cape, in Wellfleet and Truro, on the Bay side, there
are lower cliffs. The action of the sea on the side where it has been most effective
has given a graceful curve to the coast line.

The Cape Cod peninsula forms the northeastern emerged part of the Atlantic

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CAPE COD GEOLOGY 239

Coastal Plain, but it is of more recent date than the Coastal Plain south of the
glaciated area, and some geologists would not consider it a part of the coastal
plain. J. W. Powell,” founder of the modern science of physiography in the
United States, specifically included in the region within the ‘‘Atlantic plain,”
a region lying east of the Piedmont Plateaus. Keith * assigns to the Coastal

66

Plain the Cape Cod peninsula and a ‘‘narrow tract along Massachusetts Bay

east of a line running through Onset, Kingston, and Scituate.”

HYDROGRAPHY
LAKES AND LAKELETS

The Cape includes many lakes but only a few rivers. The plains of the
southern part of the Cape are dotted over with lakes of many sizes, the largest
a mile or more in length. The bodies of water that are locally called ‘‘ponds,”’
probably because they differ from the lakes, which may be considered expansion
of streams, occupy depressions that were left by the melting of masses of former
glaciers and may be classified as ice block holes and kettlehole lakelets. A few
of the lakelets, such as those in the towns of Mashpee and Falmouth, are sources
of streams, partly because ancient channels of outflow have been so adjusted
to the water level as to permit this mode of discharge. Other basins form more or
less open channels or chains of lake-like stretches of water which open south-
ward to the sea. Bass River, which lies between the towns of Yarmouth and Den-
nis and forms an inlet into the Cape from the south, approaches within a little
less than 3 miles the north shore of the Cape. A small creek at the east side of
the entrance of Barnstable Harbor reduces the portage for small boats to about
two and a third miles. A similar short portage across the main arm of the Cape
was used by Governor William Bradford in the winter of 1627 in going to the
aid of an English ship that was wrecked on the bar at Chatham while she was
on her way with passengers to Virginia. Bradford appears to have crossed
southwest of Orleans to one of the coves at the head of Pleasant Bay.

The inlets and coves about Chatham and Orleans are unfilled depressions
in glacial deposits. A small group of lakelets lies east of Wellfleet, and there

'18ee N. M. Fenneman, ee es of the United States, Annals Assoc. American Geog-
raphers, 6, p. 45, 1917. Fenneman writes: “If it be assumed that they [the New England a are
purely necenulations of glacial drift on fhe sea bottom they are not technically coastal plain.”

: owell, Physiographic regions of the United States. Nat. Geog. Monographs, 1, No. 3, May,

1895, pp. 75-76.

3 Arthur Keith, Topography; in Surface Waters of Massachusetts, by C. H. Pierce and H. J. Dean:
Water Supply Paper 415. U.S. Geol. Survey, 1916, p. 18.

240 CAPE COD GEOLOGY

are others farther north, toward Truro, deep-set in the wooded, high glacial
plain.

Two ponds that lie close together may be separated by a narrow bar or strip
of land formed by the waves. These interlake bars are formed by the cutting
down of slender ridges of drift or knolls and the filling up of narrow passages
between the ridges. A good example of this action may be seen along the rail-
road between Harwich and Brewster, where a bar separates Long Pond from
Bangs Pond. Another such bar lies west of ‘‘Great Hill,” near Chatham.

Most of these glacial lakelets have steep banks of gravel or sand. Some
of those on the south side of the Cape once had outlets at levels several feet
above their present surfaces, and from a few of them, as noted above, the water
flows out. Several of these lakelets are more than 50 feet deep.

Mr. William Gould Vinal! gives the following figures showing the areas and
the maximum depths of several ponds on the Cape:

Estimated Greatest

area im depth in
Name Township acres feet
Moon... Provincetown. = ===... toe. 2
lous... ............ Wellflect.. 3, O48 44
Ro Hastham. 6 2. 12... 32
Mitte Cif Orleans. 207 54
Gil Brewster... 1, 81
Bakers................ Brewster.....2............. 88. 63
Cobbs Brewster... 8, Ql 11
Vell rewetel. WO. 2 9
one Horwieh = WS 66
White... Chatham... 4: OO 55
Kresh st Dennis.) 25h 9
Scarvo Lake Dennis ==. 60.52. 2. 48
LOS Centreville... .........)... 698 28
Peter's. ........5.. 20... Sandwich 9,-2.5 )..32..0 4 W607 48
Spectacle.............. Sandwich. = = Wb 39
Weshpee = Wigshpee 2... O00 68

HARBORS AND CREEKS

The only large harbor on Cape Cod is at its extreme north end, inside the
curved sand spit formed of waste worn from the cliffs and thrown up by the
winds and waves on what appears to have been, at least in part, a shoal. Pro-
vincetown Harbor, which was known to navigators on this coast before Pilgrims

1 William Gould Vinal, Cape Cod Ponds, Cape Cod Magazine, 8, Sept. 1917, pp. 9-14. The Cape
vod Publishing Co., Wareham, Mass. This article contains a brief popular account of the formation
of swamp vegetation in the shallow ponds.
2 Moon Pond is in Truro, east of the Province Lands.

inne gem een

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CAPE COD GEOLOGY 241

landed here in November, 1620, has ever since remained a convenient port of
refuge in storms because of its safe approach from the north and west and its
outlying position. A depth of more than 20 fathoms is found off the west side
of the Cape as far around as Wood End, close to the shore. Between Long Point
and Provincetown the harbor has a depth of 9 fathoms, and surveys made by
the Coast and Geodetic Survey! show that this depth is maintained by the tides
and currents.

There are no inlets on the outside of the Cape north of Nauset Harbor,
which is a crooked passage into Town Cove at Orleans and which is subject to
the encroachment of a bar that is working southward. (See Plate 1). The bays
and inlets near Chatham and north of it may be reached from the sea through
a shifting entrance across a bar. No bar of the coast is more subject to changes
in the position of beaches and bars than that near Chatham. The inside passage
from Chatham northward to Pleasant Bay is shoal and is navigable at low water
by boats of small draft only.

On the south side of the Cape there are several small ports, such as those at
Hyannis and Woods Hole, which meet local needs. They are all due to irregu-
larities in the deposition of the glacial material either in the plain, as at Hyan-
nis, or in the frontal moraine, as at Woods Hole.

Below Provincetown, on the Bay side of the Cape, there are two harbors,
one at Wellfleet and the other at Barnstable. That at Wellfleet is due to a
break in the continuity of the high glacial plain about Truro, on the north.
There appears to have been an unfilled area in the arm of the Cape between
this plain and the frontal moraine on the south, about Orleans. The water in
this area is shallow, and extensive shoals southwest of it require boats coming
from the north to make a long doubling to the south in order to enter the channel.
Barnstable Bay is formed by a barrier beach that lies off an incurved section
of the frontal moraine in which a shallow tidal inlet has been formed behind
the beach. The bottom of the bay on its south side is shallow and shelves off
gently to the 20-fathom line. At low tide the bottom is bared for half a mile
or more as a flat of sand and mud and, here and there, areas of washed glacial
gravel. Plymouth harbor does not strictly lie within the area of this report,
but it is directly connected in origin with the Cape Cod Bay glacial lobe. The
depression in the drift which the bay occupies appears to have been formed by

1H. L. Marindin, On the changes in the shore lines and anchorage areas of Cape Cod (or Province-
town) Harbor as shown by a comparison of surveys made between 1835, 1867, and 1890, U. 8. Coast
and Geodetic Survey, Appendix No. 8 to Report for 1891. Part 2, pp. 283-288, with plates Nos. 11, 12.
See also Henry L. Whiting’s report in Appendix No. 12 to the Report of the Coast Survey for 1867.

242 CAPE COD GEOLOGY

a lobelet of ice on the west side of the lobe which was formed by the resistance
offered to the ice by Manomet Hill.

CARTOGRAPHY

Before Henri de Champlain and Captain John Smith made the voyages to
New England, Cape Cod was shown very inaccurately on maps of the north
Atlantic coast. A critical essay on early maps of the coast line, with illustrative
charts, is given by Justin Winsor.!. Maps sufficiently accurate to be useful
for comparing the coast line at different dates began to appear with the
growing need for them in naval operations at the time of the Revolutionary
War. The most reliable of these maps is one of the New England coast. pre-
pared from surveys made in 1777 and published in 1780 by Joseph Friederich
Walsh Des Barres. Professor Henry Mitchell mentions a corrected edition of
this chart by Matthew Clark. James D. Graham made accurate surveys of
Cape Cod and Provincetown harbor for the United States Government in
1833-35, before surveys were made by the United States Coast Survey. Prelimi-
nary coast charts were first issued by the Coast Survey in 1857. Their scale
was 1/200,000 for Cape Cod and 1/50,000 for Provincetown Harbor. Other
harbor charts were issued for Barnstable in 1861, Wellfleet in 1853, Bass River
in 1857, and Hyannis in 1850. More recent surveys and editions of coast charts
are listed in the catalogue of publications issued from time to time by the Coast
and Geodetic Survey.

Special charts and land maps were prepared in connection with the work
in Cape Cod Canal. A history of the discussion and development of this project,
which dates from 1676, is given in an account published by the Massachusetts
commissioners in 1862.’

The topographic maps of the United States Geological Survey, which were.
made from surveys completed in 1886, were preceded by two maps of the State
of Massachusetts that included Cape Cod peninsula. The first of the state
surveys was ordered by the legislature in 1830 and made under the direction
of Simeon Borden. The manuscript map was completed in 1840 and published

1 Justin Winsor (editor), Narrative and critical history of America, Boston, 1884. For early maps
of New England, see vol. 3, pp. 381-384. The cartography of the northeast coast of America from
1535 to 1600, 4, pp. 81-102. See also Maps of the eastern coast of North America, by B. F. DeCosta, 4,
pp. 83-80 and General atlases and charts published in the Sixteenth and Seventeenth centuries, pp.
eee of the Joint Committee of 1860 upon the proposed Canal to unite Barnstable and Buzzards

bays, Public Document No. 4, Boston, State Printers, 1864, pp. 165. Maps and plates. Appendix I,
pp. 58-76, gives a list of shipwrecks around Cape Cod from 1843 to 1859.

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CAPE COD GEOLOGY 243

in 1842.1 This map was revised in 1860 by H. F. Walling? under authority of
the legislature. The map of Cap Cod published in 1871 is based on surveys
of Barnstable County made by Walling in 1858, but includes corrections of
the coast line supplied by the Coast Survey chart of 1857.

DESCRIPTIVE GEOLOGY
(See Plates 1 and 2)
EARLIER REPORTS

Captain John Smith made perhaps the first report on the geology of south-
eastern New England, including Cape Cod, in these words: ‘‘From 48. to 41.
and a half, an excellent mixed coast of stone, sand and clay*...’’ No more
complete account of the geology of Cape Cod was published until the report
of President Edward Hitchcock, undertaken for the Commonwealth, appeared
in the publications of the State survey.* One result of these official surveys
was a geological map of the State, which, in the issue of 1841, represented Cape
Cod as “diluvium,” a term having the same meaning as Pleistocene in modern
geological literature when limited to the glacial deposits. The final report ap-
peared after the publication, in the same year, of Louis Agassiz’s famous ‘ ‘Etudes
sur les Glaciers,’’ which led Hitchcock to suggest, in a postscript of his report,
the possibility of glacial action on Cape Cod. Hitchcock had already, in the
body of his report, so he states, called in the aid of ice to explain the mounds of
gravel and sand. In the application of the glacial theory of Agassiz to the Cape
Cod district the question arose whether ‘‘the whole of Cape Cod is nothing
but a vast terminal moraine, produced by a glacier advancing through Massa-
chusetts Bay, and scooping out the materials that now form the Cape.” He
then goes on to state that the moraines at Plymouth and Truro would form
a part of the lateral moraine, and that probably most of Nantucket and Marthas
Vineyard might be regarded as moraines of the same glacier when it extended
farther south. °

He considered the laminated clays on the Cape a strong obstacle to this hy-

u fs ne Morse and Breese. Engraved on copper by George G. Smith. Boston, 1842.
H. F. Walling and O. W. Gray, Official topographical atlas of Massachusetts, 1871; Plates 70-71,

fee Cone with insets of Dukes and Nantucket counties. Scale 2} miles to an inch.

3 Captain John Smith, New Englands Trials, London, 1622, 2d ed. Reprinted in Everyman’s Library,
Chronicles of the Pilgrim Fathers (1910), p. 245.

4Udward Hitchcock, Report on the geology, mineralogy, botany, and zodlogy of Massachusetts,
Amherst, 1833, 2d. ed., 1835. Report on a re-examination of the economical geology of Massachusetts,
Boston, 1838, 139 mas House Doc. No. 52. Final Report on the geology of Massachusetts, Amherst,
Northampton, 1841, 4 to 331 pages

5 Edward Hitchcock, Final report on the geology of Massachusetts 1841, p. 9a, postscript.

244 CAPE COD GEOLOGY

pothesis, as indeed they were if the theory of a single advance of the ice sheet
into the district were held. The constructive geological work on Cape Cod from
the time of Edward Hitchcock’s conception of the modeling of the features of
the region by glaciation has verified his grasp of the subject, the chief gain
consisting in the recognition of a succession of ice advances, between which
clay and other deposits that are not strictly glacial have been laid down.

In 18561 Hitcheock referred the high terraces of Truro to his group of
“moraine terraces,” which he regarded as having been heaped up and scooped
out by a glacier.

In 1871, Charles H. Hitchcock compiled the data for a revised geological
map of Massachusetts, on which Cape Cod, although properly described in the
accompanying text as wholly composed of drift, was through some error in
printing, colored and indicated in the legend as Miocene Tertiary.

In 1878 Mr. Warren Upham * published the results of a rapid reconnaissance
of the glacial deposits of Cape Cod and the neighboring islands, confirming
the view of Clarence King* that the terminal moraine of an ice sheet lay in
this region.

In 1881 Shaler,’ writing when the glacial drift was still thought to have
been deposited during a single ice invasion, estimated the amount of material
in the terminal moraine on the islands and in the drift on Cape Cod.

The correlation and explanation of the moraines of Cape Cod and the
neighboring islands on the south was finally made in the masterful generalization
of the superficial glacial deposits of the northern states by T. C. Chamberlin °
in 1883. In this paper the author developed the theory of glacial lobes with
lobate and interlobate frontal moraines, which completed the explanation sug-
gested by Edward Hitchcock as early as 1841 for the thick deposit of drift that
extends northward from the lobate moraines on the south side of Cape Cod
into the region about Manomet Hill and the Plymouth woods. This deposit
was laid down between an ice lobe west of the Cape Cod region and one in
Cape Cod Bay, and a similar deposit formed the forearm of the Cape north
of Nauset inlet.

‘Edward Hitchcock, Illustrations of surface geology, Smithsonian Contributions to Knowledge,
Washington, April, 1857, p

2. F. Walling and 0. W. eee Official topographic atlas of Massachusetts, Boston, 1871. Map
on pages 18-19, see note on

* Warren Upham, in C. H. Eric hock. Geology of New Hampshire, Concord, 1878, 3, pt. 3, pp. 300-

3.

30
4 Clarence King, See G. F. Wright, Proc. Boston Soc. Nat. Hist., 19, 1876, pp. 60-63.
°N. 8. Shaler, in Shaler and Davis, W. M., Illustrations of the Earth’ s Surface, Glaciers. Boston,
ISS, pp: bt 58.
8 poduad nary paper on the terminal moraine of the second glacial ee Third Ann. Rept. of the
Director, U. 8. Geol. Sur., 1881-82, Washington, 1883, pp. 291-402.

CAPE COD GEOLOGY 245

The geologic mapping of the Cape Cod peninsula in detail was not under-
taken until 1889, when Mr. C. W. Coman prepared maps showing the distri-
bution of the unstratified drift or till on the surface, the distribution of the
superficial stratified gravel and sand, and the changes in the swamps and marshes,
as well as the narrow areas of beach and dune sand along the coast. This work
was done under the direction of Shaler for the United States Geological Survey.

In 1897 Grabau! described the plains of Truro, Wellfleet, and Eastham
on Cape Cod. The northern of these three plains, the Truro plain, which has
an average elevation of 80 feet, he ascribed to deposition in front of the ice in
the form of a delta, but was doubtful whether it had ice-contact slopes on the
east, north, and west. The Wellfleet plain, which has an average elevation of
140 feet, he regarded as presenting a doubtful ice-contact slope in the depression
between the Truro and the Wellfleet plain. The Eastham plain he noted as slop-
ing westward from the present eastern coast, where the surface has an elevation
of 75 feet, and as showing construction by streams flowing from the east, off
the present coast of Cape Cod. He regarded the Truro plain as a product of
streams flowing from the northeast and northwest at a time later than the
formation of the highest Wellfleet plain. He favored the hypothesis that glacial
barriers held up the water in an embayment of the ice front rather than the
hypothesis of marine submergence. Grabau was the first geologist to show
that the arm of the Cape, which occupies the position of an interlobate moraine,
presented evidence that a glacial lobe once lay outside of Cape Cod and that
the deposits were mainly waterlaid instead of normal lateral accumulations of till.

In 1898 Shaler? published a report on the geology of Cape Cod in which
he recognized a series of deposits of gravel, sand, and clay beneath the surface
moraine, and hence older than it. Among these deposits he placed the dark
clay (here tentatively correlated with the Gardiners clay) which he included
in his ‘‘Barnstable series.’”’ He described other divisions (the ‘“Truro series”’
and the ‘‘Nashaquitsa series”), but as later work has shown that these divisions
include the clay of the ‘‘Barnstable series” as well as other beds, the nomen-
clature of Shaler’s report has been replaced by tentative correlations with the
deposits of Long Island and Marthas Vineyard. There is doubt as to the true
position of the beds of clay at Barnstable, and although the name ‘‘Barnstable
clay” might be useful for local designation, and although Shaler’s use of ‘‘Barn-
stable series’ has priority over the name Gardiners clay, used by M. L. Fuller

1 Amadeus W. Grabau, Science, new series, 5, 1897, pp. 384-335.
2N. §. Shaler, Geology of the Cape Cod district, Highteenth Annual Rept., U. 8. Geol. Survey for
1896-97. Part II]. Washington, 1898, pp. 497-593.

246 CAPE COD GEOLOGY

in 1905, it is not certain that the clay bed at Barnstable lies at the same horizon
as the Gardiners clay, or which of the other clay beds of the district can be
correlated with the clay bed at Barnstable.

In 1906 M. Maurice Allorge, ! then a student working under William Morris
Davis, visited the Cape, and wrote a sketch of its geography, which included
a brief account of the moraines.

In the same year J. Howard Wilson, ” in a thesis prepared for a doctorate,
described in considerable detail the glacial deposits of Cape Cod and presented
an argument for the former existence in Cape Cod Bay of a glacially barred
lake, which he named ‘‘Lake Shaler.” In the same paper he advocated the
hypothesis that the glacial drift on Cape Cod and Nantucket had been brought
to the district by a glacier that moved southwestward along the front of the
main ice sheet on the continent from a source in Newfoundland, a view that
has not received acceptance. In 1914 Fuller, in attempting to correlate the Pleis-
tocene deposits north and east of Long Island with the formations worked out
on that island, referred the bed of dark clay on Cape Cod to the same horizon
as the Gardiners clay — a horizon in the older Pleistocene. He thought that
the sandy upper part of the bed on the Cape represented, as an inseparable
member, the Jacob sand of the islands on the southwest. He referred to the
younger Herod gravel several deposits of gravel and sand in the coastal bluffs
of the Cape. The banded pebbly clay till in these bluffs, as he thought, represents
the Montauk till, and the beds of gravel overlying this till he regarded as of the
age of the Hempstead gravel. Fuller’s* paper was the first one to attempt to
correlate the various glacial deposits throughout the New England Islands,
Cape Cod, and adjacent parts of the mainland about Boston and even farther
north.

It is now believed that, so far as known, the entire district that lies above
sea level is composed of Pleistocene glacial or closely allied formations nearly
identical with those on the islands to the south.

1 Maurice Allorge, Esquisse See du Cap Cod, Annales de. Geographie, No. 84. xv® Année
15 Nov., 1906, pp. 443-448; pl. x

2J. Boy ward Wilson, The il che of Nantucket and Cape Cod, with an argument for a fourth
centre of glacial dispersion in North America. New York, The Columbia University Press, 1906. See
pp. 4-50 on upper Cape Cod; ch. VIII, at pp. 52-66, on Lake Shaler, a glacial lake in the Cape Cod
oe ch. IV, at pp. 67-89, on An argument for a fourth centre of ect dispersion in North America.

eM i EF aller, os devlony of Long Island, Prof. Paper 82, U. 8S. Geological Survey, see pp. 219-
222, and table at 0,

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CAPE COD GEOLOGY 247

THE Bep Rock BASEMENT

The bed rock of the mainland of southeastern Massachusetts passes below
present sea level along a curved line drawn from Brant Rock, on the open coast,
in the town of Marshfield, southward through Plymouth to the head of Buzzards
Bay and thence southwestward on the south side of the ledges skirting the
coast of the Bay about New Bedford. There are two means of determining the
depth of the bed rock basement beneath Cape Cod. One, the direct method,
depends on deep borings; the other depends on projecting the slope of the surface
of the bed rock on the mainland beneath Cape Cod. The first method, by reason
of the lack of more than one boring on which to rely for evidence, offers little
more than a check on the other.

In 1905 the water commissioners of Provincetown caused to be put down
in the dunes near the eastern limit of the town on ground then occupied by the
pumping station, a driven well which, according to the report of the commission,

reached a depth of 420 feet. According to Mr. J. Henry Blake, of Cambridge,

Mass., who visited the site in June and August, 1905, the well was put down
to the depth of 450 feet from the surface, where the drill encountered a rock,
a fragment of which Mr. Blake collected at the time. This specimen, which is
19 mm. long, is a fresh looking grayish-green coarsely crystalline hornblende
syenite, unlike any syenite exposed between Newport, R. I., and Portland,
Maine. Near Portland, however, as I am informed by Professor John E. Wolff,
a piece of drift rock of the same facies was found some years ago by Dr. George P.
Merrill and is now in the collections of the petrographical department of Harvard
University.

It was the opinion of the well borers, so far as could be learned by inquiries
made at Provincetown in 1915, that the rock was a boulder, because the well
borers stated that it moved when struck by the drill. Thus the only well that
has been put down on Cape Cod to a depth near the presumed position of the
bed rock floor afforded no decisive information as to the character or depth of
the rock. The depth of the floor can be inferred only from borings made at widely
separated points on the Cape, and the experience in boring deep wells for potable
water does not afford promise that such evidence can be had. ~

Any attempt to determine the depth of the bed rock floor by projecting
seaward the slopes of the neighboring land surface back of Cohasset and Plymouth
is beset with doubts and difficulties as to the surface that represents that floor.
The eastern coast of Massachusetts, from Cohasset northward at least, appears

248 CAPE COD GEOLOGY

to end abruptly in a platform that stands from 200 to 300 feet above sea level,
confronting from 30 to 50 miles eastward the floor of the Bay of Maine, which
lies about 600 feet below sea level, a difference of level of nearly 900 feet in the
latitude of Cape Ann, brought about by diastrophic movement. To what
extent this drop from the edge of the lowland affects the depth of the bed rock
floor under Cape Cod there is no positive evidence.

PreE-PLEISTOCENE FORMATIONS

No pre-Pleistocene formations have been recognized in outcrops on Cape
Cod. Beds of upper Cretaceous clay are exposed on the south shore of Nonamesset
Island, near Woods Hole, at the southwest corner of the Cape, and Cretaceous
beds probably lie not far beneath the surface in the neighboring region, in the
town of Falmouth. No deep borings have been made on the Cape to show
whether or not Cretaceous rocks lie upon the bed rock floor.

Fragments of Eocene friable shelly marl have been found by W. O. Crosby
in the gravel near the top of the bluff south of Highland Light. These drifted
fragments appear to have been brought from the north and east by glacial
action at the time the Jameco gravel was laid down and are the only known
Eocene marine sediments found in the region. They were probably brought
from the bottom of the Bay of Maine.

All the beds of gravel and boulders carry fragments derived from the
Paleozoic and older rocks of the coastal region of eastern New England. Among
these fragments are pebbles of Upper Cambrian quartzite carrying casts of
shells of brachiopods. One fragment of semi-quartzite found in 1915 in the
gravel bed beneath the ‘‘clay-pounds” or supposed Gardiners clay at Highland
Light carried Devonian fossils. Fossiliferous Devonian rock has since been
found in place in the town of Rowley, Mass.

Drift derived from conglomerate like that .of the Carboniferous areas
around Boston and in the Narragansett Basin, found in the glacial deposits of
the arm of Cape Cod, show that such rocks may form a part of the floor of the
Bay of Maine and the outer part of Massachusetts Bay, if not also the floor
of Cape Cod Bay.

PLEISTOCENE FORMATIONS

The Pleistocene formations of the Cape Cod district include series com-
parable to those that form the middle and upper part of the series exposed on
Marthas Vineyard and Nantucket. Beds of fossiliferous sand at the lower part

f
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CAPE COD GEOLOGY 249

of the known section in the Sankaty sand of Nantucket are here placed in the
Pleistocene. The formations recognized in the Cape Cod district are shown
below in descending order.

Wisconsin glacial deposits:

Falmouth substage: Falmouth moraine and associated outwash plain.

Nantucket substage: Deposits of gravel and till and kames; ice-block holes on south
side of Cape Cod.

Vineyard interglacial stage: Represented by erosion phenomena.

Manhasset formation:

Hempstead gravel member (?): Beds of sand about Pleasant Bay and Chatham,
which rest on dark clay that may represent Montauk till; also beds of gravel
overlying boulder clay (Montauk?) in Barnstable and areas farther east.

Montauk till member (?): Boulder clay near and east of West Barnstable; deposits
forming Great Hill; and pebbly till at Nauset head.

Herod gravel member (?): Beds of gravel and sand that lie beneath morainal out-
wash deposits near Chatham; gravel overlying boulder clay in Barnstable.

Jacob (?) sand: Fine yellowish sand 40 feet thick, above blue clay (Gardiners?) at
Highland Light; fine yellowish sand about a mile east of Truro station, resting on
brownish clay (Gardiners?); sandy beds above clays at West Barnstable; sandy beds
overlying blue clay (Gardiners?) near Chatham.

Gardiners (?) clay: Beds of marine clay, at Highland Light, in Truro; similar beds
along the shore of Pleasant Bay at West Barnstable; about 1 mile east of Truro station;
and about. Chatham.

Jameco (?) gravel: Coarse glacial gravel at Highland Light and in bluffs south of it,
lying beneath blue clay (Gardiners?).

Sankaty sand: Fossiliferous marine sand in Provincetown well and in well at Orleans.

These deposits will now be described in detail and the evidence for their

correlation will be presented. In this account it is convenient to begin with the

lowest deposits — the oldest.

PRE-WISCONSIN DEPOSITS
SANKATY SAND

Deposits that are believed to be an extension northward along the coast
of the fossiliferous marine sand found in the cliffs at Sankaty Head, on the
east coast of Nantucket, were encountered in a well drilled in 1905 on the site
of the old pumping works of the city water board at the eastern limit of Province-
town. This well reached a depth of 420 or 450 feet, where the drill struck a rock
(syenite) that the drillers believed to be a boulder. Samples of this rock were
obtained by Mr. J. H. Blake when the well was drilled, and are now in the
geological laboratory at Harvard University. Several samples obtained from
shallow wells in the same vicinity consisted of waterworn small glacial pebbles
and broken shells.

250 CAPE COD GEOLOGY

Mr. Blake’s notes and the samples he obtained afford the following data:
A sample taken about 200 feet down consisted of broken shells, in fragments
from 10 to 12 mm. long, stained yellow to brownish with iron oxide; apparently
existing species of molluscs; also small pebbles and fragments of rock, among
which are recognizable a red shale, blue slate, granitic quartz grains, quartz |
porphyry, whitish quartzite, and a much decomposed ferruginous rock. The
rock is typically rearranged glacial gravel like that found at several horizons
in the Pleistocene series.
Dr. Dall, to whom the fragments of shells were submitted in 1915, identified \
them as follows:
Balanus sp.
Lunatia, probably L. heros Say.
Venus, doubtless V. mercenaria L.
Macoma, probably M. balthica L.
Spreula solida or similis, of the present fauna.
Echinarachnis sp.
These identifications are only tentative. According to Dall the horizon is
probably that of the upper bed at Sankaty Head, Nantucket. |
A gray sandy clay containing small grains of yellowish quartz, scales of
muscovite, and minute particles of a black mineral, probably magnetite, was
encountered at a depth of 300 feet. The clay is free from compound unde-

coiaiaanatetioinn. gene

composed minerals, such as the feldspar found in the New England glacial
drift deposits, but is apparently an intercalated member of the shell-bearing
series of coarse sand and fine gravel.

Mr. Blake collected from material brought from the depth of about 360
feet waterworn yellowish fragments of a sand dollar (Hchinarachnis sp.).

This scant record of the well at Provincetown seems to indicate that the
Sankaty sand there is at least 160 feet thick and that it lies 200 to 360 feet below
the surface. It has been reported that Arca transversa was found in an artesian
well drilled many years ago at Provincetown to a depth of 120 to 200 feet below
the surface! This well was drilled near the shore of the harbor at or near the
long wharf. Arca (Scapharca) transversa is still living in the sea about Marthas
Vineyard, Nantucket, Chatham, and Wellfleet. Its reported occurrence at a
depth of 120 feet in this artesian well — a depth about 80 feet nearer the surface
than the depth at which the shells reported from a well drilled in 1905 — is
doubtful in view of the uncertainty concerning the dip of the Sankaty sand
beneath Provincetown.

1W. G. Binney — and Augustus A. Gould, Report on the Invertebrata of Massachusetts, ‘
Boston, 1870, p. 149 |

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CAPE COD GEOLOGY 251

Mr. M. C. Atwood, Deputy Collector of Revenue at Provincetown, informed
me in April, 1916, that a well was drilled at the end of Central wharf to a depth
of 400 feet many years ago. The material passed through was a light gray
clay. No good water was found.

Mr. Elmer C. Smith told me in 1916 at Rock Harbor that in about 1890
a well was sunk on his father’s land in East Orleans, near the point where the
road branches off to go to Pochet Neck. No water was found at a depth of 70
feet, but farther down the drill passed through from 2 to 3 feet of blue clay at
a depth of 84 feet and then entered a bed of shells in ‘‘beach gravel.” The well
was drilled at a point about 50 feet above sea level. This shell bed is probably
brought up by an anticlinal fold in the Sankaty sand. The washing away of
the banks about the crooked inlets between Nauset Harbor and Namequot
Point may expose this shell bed above sea level.

The Sankaty sand occurs in Sankaty Head bluff and probably reappears
above sea level in the eastern part of Orleans. Its discovery in the wells at. Prov-
incetown between 200 and 360 feet below the surface indicates that it underlies
the arm of Cape Cod and that it is distributed along the coast of eastern Massa-
chusetts. Beds containing its fauna have not been found on Marthas Vineyard,
where, however, there are beds of Pliocene sand containing Macoma lyelli, a
species not found living elsewhere and particularly abundant in the underlying
Miocene greensand.

In his correlation table of Pleistocene formations about the coast and islands
of southeastern New England, Fuller? placed the fossiliferous beds at Sankaty
Head at the horizon of the Jacob sand, a formation that lies upon the Gardiners
clay and under the Herod glacial gravel, but the position of what appears to be
the Gardiners clay and Jacob sand in the bluff at Highland Light, a few miles
southeast of the Provincetown well, suggests that the Sankaty sand lies below
the section at Highland Light and that the Jameco gravel is the visible base
of that section. The Sankaty sand, with its marine fossils, probably lies at the
horizon of the Weyquosque glacial sand and small gravel — that is, it lies very
near the base of the Pleistocene series. Its assignment to this horizon agrees
closely with Dall’s opinion that it represents the upper Pliocene; but just as
the Weyquosque glacial sand and gravel at Clay Head on Block Island and
at Gay Head and in Nashaquitsa cliffs on Marthas Vineyard are underlain by
beds of boulders or by pebbles containing granitic material, so at Sankaty

1 Charles W. Johnson, Fauna of New England, list of the Mollusca: Occasional Papers of the Boston
Society of Natural History, 8, No. 13, Boston, 1915, p. 19. F
2 Prof. Paper 82, U. 8. Geslonical Survey, Washington, 1914, p. 220.

2052 CAPE COD GEOLOGY |

head the beds are underlain by a glacial gravel. Finally, if the rock at the
bottom of the Provincetown well is really a boulder it indicates that glacial
erratics lie beneath the Sankaty sand. If this view should be supported by
further evidence, it would place this marine invasion in an interglacial stage |
following what was probably the first ice invasion of southern New England. {
The shell beds carrying Macoma incongrua appear to lie below the blue clay
at Highland Light, which is of supposed Gardiners age, for a pebble containing
that species was found in the underlying gravel, of supposed Jameco age, in the
bluff south of the light-house.

The Sankaty sand may extend northward into Massachusetts Bay and
Boston Harbor, and may have furnished the fossil shells and pebbles of agglu-
tinated sand carrying shells such as are found in the drumlins in that region.

The deposits supplying these shells there apparently lie beneath the glacial
blue clay found in the valleys of the Mystic and Charles rivers. The Dana (
brothers! noted, as early as 1818, fragments of Mya arenaria found 40 feet
below the surface at Jamaica Plain, and the fragment of a clam shell found |
at the depth of 107 feet in digging the well at Fort Strong, an earthwork built |
at the end of August, 1814, in East Boston, at the south end of Noddle’s Island.”

JAMECO (?) GRAVEL

The end of Cape Cod peninsula from near Wellfleet to Pilgrim Heights,
which overlooks the expanded sand hook on which Provincetown stands, includes
the two plains described by Grabau as the Truro plain and the Wellfleet plain.
For several miles along the ocean side of this part of the Cape there is a bluff
whose structure is well exposed at Highland Light and at other points where
the sea is undermining it and removing the talus of gravel and sand. Distinct }
stratigraphic members in this section can be recognized only at Highland Light,
where, beneath the surface rubble and wind-blown sand, about 40 feet of fine
yellowish sand resembling the unfossiliferous Jacob sand overlies about 40 feet
of dark clay containing no stones. This clay has the appearance and stratigraphic
associations of the Gardiners clay. It rests on a coarse glacial gravel, which
Fuller regarded as the Jameco gravel, and it is overlain by fine yellowish sand |
that resembles the Jacob sand. Under the lighthouse at the ‘‘clay pounds”’

1J. Freeman Dana and Samuel L. Dana, Outline of the mineralogy and geology of Boston and its

vicinity, with a geological map, Boston, 1818, p. 96. The drifted shells are described by W. O. Crosby

Bullard: Distribution and probable age of the fossil shells in the drumlins of the Boston

Basin. Am. Jour. Sci., 48, 1894, pp. 486-496. Includes a list of 55 species of marine animals collected
by Messrs. Stimpson, R. E. Dodge, W. W. Dodge, Warren Upham, W. W. Herman, and others.

? Justin Winsor, Memorial history of Boston, 3, pp. 309-310, Boston, 1881. |

CAPE COD GEOLOGY 253

a bed of this gravel about 20 feet thick was exposed in 1915-16 above the beach.
Its components are subangular and waterworn pebbles or cobbles, the largest
8 inches in diameter, indicating very strong stream work. Ten feet below the
contact of this bed with the overlying clay there is dark-purplish felsite, felsite
breccia, and felsite having flow structure, some of it in angular blocks about a
foot long. There are also pebbles of gray quartzite, fine red shale, compact
argillite, schist, lustrous crumpled phyllite like that at Savin Rock south of
New Haven; granitite, gabbroid, and dioritic rock resembling that on the east
coast near Boston; and waterworn pebbles of a red conglomerate that resembles
some forms of the Roxbury conglomerate found near Boston. In the bluffs
north of the clay pounds or near this horizon there were seen also angular boulders
(one of felsite) nearly 3 feet long. South of the clay pounds the section changes
as it rises on a gentle northward dip to a series of alternating beds of gravel
and sand. Farther south it is difficult to trace bed to bed because of the talus.

Among the coarse fragments found in the gravel about 10 feet below the base
of the clay was a quadrangular piece of Devonian fossiliferous semi-quartzite
about 6% inches long, filled with fossil casts. Dr. Ulrich, who examined these
casts, stated that the fossils consist of brachiopods, pelecypods, and trilobites,
all poorly preserved. He furnished the following list:

Dalmanella sp. Ci. D. planoconvexa

Schizophoria sp.

Modwomorpha sp.

Homolonotus; fragments of a trilobite suggesting this genus.

The horizon at which this fragment was found is regarded by Ulrich as
Lower Devonian. The rock is made up of fine grains of light blue quartz, which
weathers yellowish. At nearly the same horizon in the gravel but farther south
and higher up in the cliff on account of the rise of the beds in a fold, a slabby
fragment containing small patches of clay was found. These patches look like
fossil shells.

In the same beds, near the top of the cliff, at the southern limit of the
government lot, I found a flattish finely stratified greenish-hued quartzite show-
ing faint ripple marks and carrying on the flat side three impressions having
a hyolithoid outline. One of these impressions was distinctly marked with
transverse lines of growth. Dr. Walcott identified this material as a species of
Hyolithes, probably but not certainly Cambrian.

In a thin patch of lag gravel on top of a bed of fine sand (Jacob?) just north
of the Weather Bureau Station, I found a weathered specimen of quartzite
showing the parallel closely set ribs of Scolithus, a form found from the Lower

254 CAPE COD GEOLOGY

Cambrian upward. A large specimen of this scolithoid sandstone or quartzite
was found several years ago on the beach at Marshfield, on the opposite side
of Cape Cod Bay

The fossilferous Cambrian pebbles that are scattered widely on the south
coast in the glacial drift or in the rearranged drift of the modern sea beaches
have doubtless been dragged out of the coarse conglomerate of the Carboniferous
rocks of southern Massachusetts and Rhode Island. The pebbles in this con-
glomerate are not only more numerous but larger toward the southern side of
the field. No such pebbles have been found in the conglomerate along the
northern border of the district, in the area about Norfolk, or in the area of
Roxbury conglomerate near Boston. These Cambrian pebbles were evidently
carried southward beyond the present coast in Carboniferous time, from a
land where quartzite crops out. The Cambrian pebbles on Nantucket and on
the outer part of Cape Cod were therefore probably brought by one or more
ice sheets from beds of Carboniferous conglomerate that lay under Massachusetts
Bay or on the floor of the Bay of Maine. The conglomerate doubtless derived
them from the lost land on the south, southeast, or southwest, which was reduced
to a peneplain in middle Mesozoic time and covered in Upper Cretaceous time
with sediment that still remains off the south coast in the New England Islands.

At least three erratic fossiliferous Devonian pebbles have been found in
southeastern Massachusetts. The first one I found in the moraine on Marthas
Vineyard as long ago as 1888. A slabby greenish-gray quartzite or semi-quartzite
found in the middle of the island just west of the village of West Tisbury, near
a pond on the Tiasquam River, was submitted to Prof. Henry Shaler Williams,
who reported on the material as follows: ”

Examination of the fossils shows two species, one an Orthis, which presents close resem-
blance to O. multistriata, and a fragment of what I take to be a Spirifera. It is less than half
of a dorsal valve, but what there is of it closely resembles that part of a form which occurs in
the Maine so-called Devonian faunas and which is generally called Sp. cyclopteris, but is shorter
than that species generally is in New York. I am inclined to think it is a representative of the
fauna found in the Gaspé sandstone. Correlated with Schoharie and Esopus of New York.

Similar rock with this fauna occurs in the northwestern part of Maine about Moosehead Lake,
and probably deposited farther south, though I know of no region for it.

1U.S. Geol. Survey Mon. 33, pp. 110, 112, 1899. On the distribution of fossiliferous Cambrian pebbles
in the Carboniferous conglomerates of the Nareagancctt area and on the beaches and in the glacial drift
south of this coal field, see also W. B. Rogers, Proc. Boston Soc. Nat. Hist., 7, 1861, pp. 389-391; W. O
Crosby and G. H. Parton, Am. Jour. Sci. 3d ser., 20, 1880, pp. 416-420; C. D. Walcott, Am. Jour. Sci.
4th ser., 1898, pp. 327-328. Crosby and Barton noted the occurrence of Scolithus pebbles in the Carbon-
iferous conglomerates near Newport, R. I., such pebbles are not uncommon on the beaches of Vineyard
Sound.

2 Letter to Director C. D. Walcott dated New Haven, Conn., April 10, 1889.

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CAPE COD GEOLOGY 255

For a time it seemed that this Devonian erratic must have been brought
by an ice sheet from Maine or from an area north of Boston to Marthas Vineyard;
but the pebble lay in the field of the lobate moraine west of the Plymouth inter-
lobate axis and was associated with striae of a glacier that swept down from
central New Hampshire across the interior of the Boston and the Narragansett
areas and lay quite out of the field of action of the glaciers that ran southeastward
across Maine. Shortly before his death Prof. A. C. Packard showed me a quartz-
itic pebble from the Carboniferous conglomerate east of Providence, in the
Taunton syncline, containing a species of Spirifera closely resembling the form
described by Williams. The Devonian pebbles of southeastern Massachusetts
therefore evidently also came into the Pleistocene drift from Carboniferous con-
glomerate. The Devonian and Cambrian pebbles in the supposed Jameco
gravel under Highland Light on Cape Cod and any that may be found in the
higher drift beds of the region can therefore hardly be used as a basis of definite
conclusions as to the direction of motion of the Pleistocene ice sheets. These
pebbles appear to have been shifted northward in Pennsylvanian or Permian
time into the gravel beds at a time of local mountain glaciation,! and to have
been carried southward during the Pleistocene epoch. Upper Cambrian pebbles
could not have been brought to southeastern Newfoundland during Pleistocene
time because an ice sheet coming from that small gathering ground to Nantucket
and Cape Cod would have to maintain its position and course directly along the
front of a great regional glacier that was pushing down over New Brunswick,
Maine, and eastern New Hampshire, on the edge of the continental platform,
in a position that seems physically impossible. The fact that no ice mass radiated
out far to the southwest and west is shown by the absence of glacial deposits
from the Magdalen islands, in the St. Lawrence Gulf, except some deeply weath-
ered early Pleistocene till discovered by Goldthwaite? in 1913. The position of
Upper Cambrian fossiliferous sandstone containing Obolus on the Avalon penin-
sula, in southeastern Newfoundland, is quite consonant with the probable
extension of a band of these rocks southwestward off Nova Scotia and the -
present southern coast of New England in late Paleozoic time. *

GARDINERS (?) CLAY

Beds of dark clay may be seen along the shore of Cape Cod above sea level

at several places, as at Sandwich and thence eastward to West Barnstable;

1 Robert W. Sayles, The Squantum tillite, Bull. Mus. Comp. Zoél. Harvard College, 56, 1914, pp.
141-175; 12 pls., including map of country south of Boston showing localities.

2 James Walter Goldthwaite, The occurrence of glacial drift on the Magdalen Islands, Museum Bull.
Canada Geol. Survey, No. 14, geol. ser. No. 25, May 12, 1915, p. 11, with maps and illustrations.

3 See C. D. Waleott’s chart showing the distribution of Cambrian formations in the twelfth Annual
Report of the Director, U. 8. Geol. Survey, for 1890-91, pt. I, pl. XLII, p. 532.

256 CAPE COD GEOLOGY

about Chatham and Pleasant Bay; on the Bay side of Truro; and in the so-called
‘‘clay-pounds” at Highland Light. The base of these beds is nowhere exposed
to view except at Highland Light. Shaler called them the ‘‘Barnstable series,”’
a term that was apparently intended to include also certain gravelly clay.
Whether the beds of clay on Cape Cod are all of the same age is still uncertain.
The only well exposed section that strongly resembles the typical Gardiners |
section is that at Highland Light, where the dark clay occurs in the form of a ?
large lens that crops out on the coast above the gravel that Fuller called Jameco
and below beds of sand that represent either the Jacob sand or a younger
deposit. (See Plate 33). |

HIGHLAND
LIGHTHOUSE

WIRELESS

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f
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° ° 6 6 a oo = ° I
° © Le < a 8 oO? = co Sie “ 00 © Seow)
oe (OO O98 35 =. 6 6 o OS - ° ° 6 o O r)
Be es we SE 8.8/9, SAMECO "GRAVEL *. See te
° io 0 a oe. 6 oo 3 5 0-50 o oo 8g i
ne

BEA CH

Fig. 20.— Section at Highland Light, in North Truro, showing the “clay pound” or supposed Gardiners clay resting on jee
identified by Fuller as Jameco gravel and overlain by sands that resemble the Jacob sand. : \
The bed of clay that crops out at Highland Light lies in a shallow syncline,

the axis of which appears to trend south of west and to pitch in that direction,

so that the clay is brought out beneath the North Truro plain to the bluff on

the bay side between North Truro station and Truro, on the Pamet River.

But the clay on the bay side is prevailingly sandier than the typical Gardiners

clay, and it passes laterally into sand and gravel. At a point a mile south by

east from Truro station there was exposed in the bluff, in 1916, the typical
Gardiners succession, namely, gravel below a brownish clay less than 20 feet [
thick, and above that a fine yellow sand resembling the Jacob sand. The clay

bed thickened toward the north, but the sand became gravelly. There is a down-

fold in the series and beds of clay extend along the bluff nearly to North Truro,

but whether at the same or at a higher horizon cannot be ascertained because

of the slumping of the cliff. The clay south of the sharp downfold may lie at the

CAPE COD GEOLOGY 257

horizon of the beds of clay, gravel, and sand which on the ocean side rise up
south of the ‘‘clay pounds” and show a clayey section beneath the large bed of
clay at the lighthouse.

A lens of clay was seen in a fresh cut of the bluff about a third of a mile
south of the Pamet River Coast Guard station in April, 1916. It presented a
rounded termination on its northern border, suggesting that overthrusting had
foreshortened the lenticular cross section, unless the whole appearance were
due to the dislocation of a once more continuous layer of gray clay. This lens
was 25 feet long.

These lenses of clay in gravel and sand lie below the horizon of the Gardiners
clay, if that formation is represented by the clay at Highland Light.

Fully a dozen beds of blue clay are exposed about Chatham, and along the
coast as far north as the north side of Pleasant Bay. The outcrops mapped on
the bluff near Chatham Light, at the northeast end of Oyster Pond, and on the
sides of a lakelet about a mile northwest of that pond fall into a line extending
northwestward and marking either the outcrop of an eroded inclined bed of
clay or the axis of a fold. The clay on the south side of the lake mentioned dips
rather steeply westward under light-colored sand (Jacob?). In a railroad cut
west of the south end of High Hill a sharp fold of clay and overlying sand dips
eastward at an angle of 23°. This outcrop lies east of those on the banks of the
lake and seems to show that an anticlinal arch brings up the clay along the
line described. North of this outcrop, on the west side of Rider’s Cove, there
is another, and north by east of this is an exposure on the northern part of
Nickerson’s Neck. North of this outcrop there are exposures on the north shore
of Pleasant Bay, on both sides of a small cove. There is also an outcrop of clay
on the North Chatham shore about half a mile north of Allen’s Point. The
alignment of the necks and topographic features, including Great Hill, near
Chatham, is due partly to erosion, but this erosion appears to follow the folding

of older Pleistocene beds, including what appear to be the Gardiners clay, the

Jacob sand, and the Herod gravel. Great Hill is possibly a syncline of Montauk
till.

About half a mile west of Harwich railroad station, there is an exposure of
reddish clay, which possibly lies at the horizon of the beds of clay here described.
Mr. Gilbert Hart, my assistant, noted outcrops of clay under sand along the
railway east of South Chatham at two points. This clay appears to be widely
distributed under the southeastern part of Cape Cod in low folds, which here
and there reach the present surface or lie a few feet below it.

258 CAPE COD GEOLOGY

On the north side of the Falmouth moraine, at an elevation of about 150
feet, on the northwest slope of Bourne Hill, in Sandwich, in the roadside there
was exposed in 1916 some 6 feet of clay beneath glacial gravel and the surface
till. This clay bed is well up in the morainal ridge and is probably a part of
the outwash in front of the Wisconsin ice sheet.

At Yarmouth railroad station, in the low cut west of the branch track
running to Hyannis, there was exposed in 1916 beds of clay in which boulders

are either visible or are reported to occur. The section exposed follows:

Deposits at Yarmouth ;

Feet
Sandy ullwitthsome boulders. == (itis tt 4
Sharp yellowist glacialcand === 6
Brownish boulder clay; larger boulders, 3 feet long.......... 4

The surface at this point has been traversed by the Wisconsin ice and the
top layer beneath the soil corresponds to the general sheet of Wisconsin drift
in the Falmouth moraine of the district.

The bed of till noted above crops out north of the morainal ridge and cannot
be far above or below the horizon of the beds of clay that crop out along the
coast of the Bay or within half a mile of the coast where the overlying Falmouth
moraine is relatively thin or absent.

Blue clay crops out along the south shore of Cape Cod Bay and is well ex-
posed from West Barnstable railway station eastward to the brick-clay pits in
a small valley about a mile east of the station. The beds of clay in the pits lie
close to the level of high tide. The surface at the railway station stands nearly
50 feet above sea level. The beds of clay have evidently been eroded by glaciers
since they were deposited. According to statements made to me in 1899 the beds
of clay at the brick pits are underlain at one place at a depth of 18 feet by quick-
sand and at another place by gravel. The clay contains angular stones, the
largest a foot in diameter, and is said to carry large boulders about 4 feet below
the surface. In this respect the clay resembles the Montauk till rather than the
Gardiners clay. Farther south the clay disappears beneath sand and sandy
clay and is well stratified.

Probably the same bed of clay continues westward along the shore of the
Bay and crops out opposite Sandwich, near the old glass works, where formerly
bricks also were made. Rolls of clay were struck by workmen digging the eastern
part of the Cape Cod Canal and the boulders found below the sand in the district
were probably in this clay. These boulders appear to have been dropped from
masses of floating ice, if not from glaciers. Such boulders occur in the brick

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CAPE COD GEOLOGY 259

clays at North Cambridge at a horizon that is presumably equivalent to the
Gardiners clay. No boulders have been found in the clay at Highland Light
and in the third cliff at Scituate in sections that are similar to those of the
Gardiners formation on the islands, so that the clay at Barnstable and in the
valleys of the Charles and Mystic rivers may lie either at the horizon of the
Montauk boulder clay or at a lower horizon than the Gardiners clay. They
may be the equivalent of one of the stony blue clays near the base of the Pleis-
tocene section.
JACOB (?) SAND

The assumption that the clay at Highland Light represents the Gardiners
clay involves the correlation of the overlying beds of yellowish fine sand with
the Jacob sand on the islands to the southwest. Sandy beds also overlie the beds
of clay about Pleasant Bay and in the brick-pits at West Barnstable. If, how-
ever, the boulder-bearing clays along the shore of the Bay represented the
Montauk till these beds of sand should be regarded as Hempstead beds. Large
tracts of sand and gravel overlie the clay along the south coast of Cape Cod
Bay. These tracts lie beneath the veneer of frontal moraine which covers the
district. Some reasons for regarding both the sand and the gravel as newer than
the Jacob sand are set forth below.

MANHASSET FORMATION (?)
Herop GraveL Member (?)

On the islands the Herod gravel underlies the Montauk till or boulder
clay, occurring very much as the Jameco gravel occurs beneath the Gardiners
clay. The Herod normally overlies the Jacob sand, which may in places be
gravelly. If the boulder clay in Barnstable is the Gardiners clay the overly-
ing beds of gravel in the tabular hills along the coast of the Bay at the foot
of the moraine represent the Herod member; but if the beds of clay are re-
garded as the equivalent of the Montauk till, the Herod would be found below
sea level, and the gravel lying above the clay must be the equivalent of the
Hempstead gravel. South of the frontal moraine, which consists mainly of sand,
there is a broad expanse of sand and gravel that is evidently older than the
outwash from the Falmouth moraine.

Montauk Trut Mremper (?)

Along the south shore of the Bay from Barnstable westward to the Cape
Cod Canal there are beds of clay that are said to contain large boulders, such as

260 CAPE COD GEOLOGY

are characteristic of the Montauk till rather than the Gardiners clay as known
on Marthas Vineyard, No Mans Land, Block Island, and Long Island. The
clays about Pleasant Bay may not lie at the same horizon as those seen about
Barnstable, but are probably part of the same deposit that underlies the south-
ern part of Cape Cod at about sea level.

In the bluff on the south side of the entrance to Nauset Harbor there is
an outcrop of till or clay containing striated stones and underlain by gravel
and sand. This outcrop lies within the boulder-strewn area of the Falmouth
moraine, but the bed of till appears to be in the older Pleistocene below the
surface moraine. There is also a small exposure of stony clay in the low bluff
at the Nauset Beach coast guard station. This bed is only 3 or 4 feet thick and
overlies about 6 feet of brown clay. The entire section at this point appears to
be a part of the Eastham plain, and is possibly newer than the section at the
entrance of Nauset Harbor. Deposits of sand, gravel, clay, and pebbly till were
probably laid down at all the glacial stages along the ice front, which probably
advanced at times over its washed deposits and then retreated so as to produce
alternations of stratified and unstratified deposits. The two sections described

‘show that there are several beds of true stony clay till on the Cape and that
their positions in the older Pleistocene succession can be determined only where
the beds of clay or till are very thick and extensive.

HempstTeaD GRAVEL MumBeEr (?)
Beds of gravel overlie the blue clay in the southern part of Cape Cod in
a position comparable with that of the Hempstead gravel, which lies upon the
Montauk till in the islands. If the clay in the southern part of the Cape is the
Gardiners clay the gravel and sand beneath the morainal outwash correspond
in position to the Herod gravel, which lies beneath the Montauk tills.

SUMMARY

The beds of gravel and sand that lie above the clay are evidently older than the
Wisconsin outwash gravel in the southern part of the Cape and represent the
Manhasset formation, which is composed of the Herod gravel member below, the
Montauk till in the middle, and the Hempstead gravel member above. All three
of these members are found on Cape Cod. In the plain on the south side of the
Cape these beds of gravel and sand, where they are not covered with the out-
wash from the Falmouth moraine, show traces of erosion channels made by
streams prior to the Wisconsin stage.

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CAPE COD GEOLOGY 261

THE VINEYARD INTERGLACIAL STAGE
EROSION PHENOMENA

Before the Wisconsin ice advanced to Nantucket and Marthas Vineyard the
outer line of islands and, presumably, the region north of them, were long sub-
jected to normal fluvial erosion. On Cape Cod there are traces of a pre-Wis-
consin topography on the plain in its south-eastern part and in the plains of
Wellfleet and Truro. These plains lay in or near the interlobate axis of the
ice sheet, where, as there was no erosion by ice and the glacial deposits were
small, the older features have been but slightly masked by the Wisconsin
deposits. The dissection of the beds of gravel and sand in the area about
Chatham, in Harwich, and in Orleans evidently preceded the advance of the
Wisconsin ice to Nantucket, because the ice-block holes occupied by the lakelets
there differ from those farther west, about Falmouth, for they lie in channels
cut in the folded beds of clay and sand of the pre-Wisconsin drift here referred
to as probably the Montauk till of the Manhasset formation. The peculiar
winding courses of these depressions are not like those excavated by moving ice,
and they were evidently not the channels of subglacial streams, because they
were occupied by stagnant ice left over from the Nantucket stage of the Wiscon-
sin glaciation. Thus the unevenness of the plains of the Chatham district (except
the outwash terrace, which was formed during the last advance of the ice of the
Cape Cod bay lobe) dates back to an interval of erosion between the deposition
of the Manhasset formation and the Wisconsin ice advance. Similar features may
be seen in the highland plains of Wellfleet, where the deep channels or ‘‘hollows”’
are flanked by moraines and kettle holes, which show that these channels were
in existence when the last ice lay over that region. Moreover, large boulders here
and there on the surface, such as those seen near Highland Light, show that an
ice sheet lay here after the topography had been outlined. These plains or
terraces thus fall into two groups — the high-level Wellfleet plain and the
low-level Chatham plain.

THE WELLFLEET PLAIN
The Wellfleet plain, which forms the highlands of the forearm of the Cape,
is much dissected and is in places masked by moraines and kettle holes. Its
highest points reach elevations of 140 to 150 feet north and south of the val-
ley of Pamet River. Toward the west it’ declines to elevations of about 100
feet. It overlooks from Truro northward the lower plain of North Truro, which
has an elevation of 60 to 80 feet and a surface partly masked and partly carved

262 CAPE COD GEOLOGY

by glacial and stream action during the Wisconsin stage. Most of the deposits
on it, however, are older than those of the Wisconsin stage. North of the clay
pounds at Highland Light the lower, oldest beds in that.region can be traced
continuously northward into the bluffs of the lower plain — the Truro. The
Wellfleet plain appears to have been deeply dissected by westward flowing
streams before it was occupied by the Wisconsin ice. Some of the vales in this
plain headed in land that stood east of the present cliffs of the Cape, but
that is now washed away. The spaced erosion and the general parallelism of the
channels do not resemble the creases on the margins of the outwash plains
that were formed in front of the Wisconsin ice sheet on Nantucket and Marthas
Vineyard. At a place in the Eastham plain where Fresh Brook enters the salt
creek that occupies the greater part of a small valley there is a pamet! that is
unmodified by glacial action.

Although it may be assumed that the stream erosion on the Wellfleet plain
was the work of water that flowed out of the ice sheet during its advance in
Wisconsin time, this assumption appears to be unwarranted, for the ice did
not entirely melt during the interval between the Nantucket and the Falmouth
substages, and the pamets were in existence when the ice sheets finally dis-
appeared. The bottoms of these channels, like those of the channels about
Chatham, lie below sea level and should be referred to the third stage of erosion
— that is, to the Vineyard interglacial stage.

Great Hill, which stands northwest of Chatham village and rises to an
altitude of 132 feet, may be an outlier of the Wellfleet plain. Some of the areas
in the necks east of Orleans approach the 100-foot level and may be regarded
as tracts that were not worn down to the level of the Chatham plain.

THE CHATHAM PLAIN
Most of the eroded and thinly mantled surface of the Chatham plain stands
less than 80 feet above sea level. It lies within the Falmouth moraine, east of
Orleans. The surface about Chatham village declines to levels below 60 feet and
shows no trace of a break or cliff between a higher and a lower level.
A large tract in which the topography is similar lies in Harwich, south of
Long Pond. Remnants of the Nantucket ice covered this tract so completely

1 A pamet is a long depression in a thick deposit of stratified gravel and sand. In its course and slopes
it resembles a small valley formed by running water, but its sides and bottom have the forms of mounds
and hollows produced by irregularities in the deposition of glacial drift, either ice-laid or water-laid.. Most
of these in Massachusetts occur in nearly parallel groups and occupy interlobate morainal tracts in the
Wisconsin drift. In the Plymouth woods such depressions merge into lines of inosculating kettle holes,
which are occupied by glacial lakelets,

set diese ee nn

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CAPE COD GEOLOGY 263

as to prevent the deposition of the sand and gravel that was washed out from
the moraine in the Falmouth stage of the Wisconsin glaciation. The streams
in this tract flowed in long, straight channels that ran between west of south
and southwest. Here kame-like elevations 50 to 70 feet high are common, and
some that stand farther north reach a height of 80 feet or more. Much of the
glacial material here must be assigned to the Nantucket substage, when it was
laid down around ice blocks that were afterward replaced by lakelets. Such de-
posits, however, are at many places thin or nearly absent, as shown by the older
clays in cuts about Harwich.

Other features of the Vineyard erosion interval on the Cape are the channels
and embayments cut in the Chatham plain, which were graded to a base level
of erosion that lay below the present sea level. The relative position of this base
level when the channels were cut cannot even be inferred from the depth of
the channels that remain, for they occupy positions that must have lain well
back from the mouths of the eroding streams. Shaler! recognized the pre-
Wisconsin topography of parts of Cape Cod and drew a hypothetical map
showing the old lines of drainage. The base-level to which this drainage system

is related lies indefinitely below the present level of the sea.

NORTH TRURO PLAIN
(See Plate 25, fig. 2).

The well-defined plain in the northwest part of Truro, including Pilgrim
Heights, at the north end of the glacial part of Cape Cod, stands less than
80 feet. above sea level along the western edge of the higher Wellfleet plain
from Highland Light southward nearly to Pamet River. The escarpment. be-
tween the two plains is a distinct topographic feature despite considerable dis-
section. The surface of this plain is creased by shallow channels of late Wisconsin
streams, as noted by Grabau, but the material found above sea level consists of
gravel, sand, and clay, which may be traced into the lower part of the beds that
form the mass of the higher Wellfleet plain. The North Truro plain is therefore
a bench or terrace cut back into the Wellfleet plain from the west prior to the
last action of the Wisconsin ice or of the streams. There are practically no
boulders on the surface, and except for the coastal sections one would infer
from the surface features that the plain is wholly of late Wisconsin age. It seems
necessary to correlate this terrace plain with the terraces that stand at heights
of 60 and 80 feet in the southern part of the Cape.

tN. S. Shaler, Report on the geology of Cape Cod, p. 516, fig. 86.

264 CAPE COD GEOLOGY

WISCONSIN GLACIAL DEPOSITS

The deposits of the Wisconsin stage of glaciation on Cape Cod consist of
certain beds of sand and gravel, and probably also some of till, which were laid
down along the south side of the Cape during the first advance of the ice to
Nantucket and during times when stagnant masses of that sheet of ice were
melting, as late as the second advance, which reached only the position of the
morainal ridge that skirts the southern arm of the Cape. Practically all the
boulders, gravel, sand, and clay in the high plains and morainal mounds from
Woods Hole northward past Buzzards Bay and thence eastward to Orleans
pertain to the second and last ice invasion. These two distinct groups of Wis-

consin deposits are described below.

NANTUCKET SUBSTAGE

The terminal moraine of the Nantucket substage lay some 30 miles south
of the Falmouth moraine. The deposits and the topographic features on Cape
Cod pertaining to the Nantucket substage are widely spread south of the Fal-
mouth moraine.

Practically all the kettle holes and glacial lakes of that region, even those
that lie within the Falmouth moraine, represent the sites of blocks of ice formed
while the stagnant ice of the Nantucket substage was melting. The block of
ice that occupied the site of Great Pond, in the town of Barnstable, must at
first have risen high enough above the surrounding surface to supply by its
melting not only a considerable stream, which flowed from its southern border,
but fans of gravel and sand that were built out from its side!

One has only to fill these depressions in imagination with large berg-like
masses of ice, which were more or less charged with stones and sand and which
rose above the level of the plains of that part of the Cape, to gain a vivid picture
of the landscape at the time the ice sheet of the second or Falmouth substage
yet lay against the northern slope of its terminal moraine.

These ice masses lay in chains and groups that had rather well-defined
directions. A remarkable chain extended across the plains in Barnstable from
Pondsville southward to Great Bay, east of Cotuit, a region in which the back
bays of the coast are ice-block holes. The northernmost depressions in this
chain, known as the Cotuit ponds, are separated by transverse ridges supple-
mented by bars thrown up by the waves on the lakelets. Here a large mass was

1 Woodworth, J. B., Some glacial wash plains of southern New England, Bull. Essex Inst., 29, 1897
(issued in 1899), pp. 71-119. (See pp. 93-95, and fig. 4.)

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CAPE COD GEOLOGY 265

divided into three smaller ones and drift filled the channels between them.
On the southeast side of the southern pond an ice-contact terrace and outwash
plain shows that a sand plain was formed in a space left by the melting of the ice.

Another group of ice-block holes in the town of Sandwich, near Farmers-
ville, including Spectacle, Triangle, Lawrence, and Hog ponds, further illustrates
the mode by which the remnants of the Nantucket ice sheet were broken up by
the opening of channels that were filled with gravel and sand, here perhaps
largely by outwash from the Falmouth ice front, for the frontal plain of that
substage encloses these holes.

A lakelet in the bottom of one of these depressions may occupy a lower story,
so to speak, in a group of depressions. On one or more sides of such a lakelet

OUTWASH PLAIN

scaLe 2 = S 4 ? MILES

Fig. 21. — Section of Falmouth moraine and outwash plain, showing old ice blocks in sites of glacial lakelets.

there is a terrace whose surface lies at the foot of a higher bank, or ice-contact
slope, showing that the space around a large mass that had melted had been
filled by gravel and sand to a certain height before the ice block disappeared.
Such a terraced kettle or ice-block hole may be seen in Wakeby Pond, in
Sandwich.

The close alignment of the ice blocks and their somewhat regular spacing
suggests that broad waterways existed between remnants of the ice sheet in
the first clearly defined stage of its final disappearance and that cross channels
were afterward formed by melting, so that the long ridges were broken up into
huge blocks, roughly half a mile to a mile and a half across. The long axes of the
holes, as shown by the shapes of the lakelets, trend southward through Falmouth,
Sandwich, and Barnstable, though departures from this general trend are shown
by ponds that extend southwestward. Farther east, in Yarmouth and Harwich,
the southwestern orientation of the long axes becomes a pronounced feature,
not only in individual ponds but in groups of ponds. In its northern half Bass
river, a connected series of ice-block holes and channels, trends southeastward,
but it turns abruptly at South Dennis. This orientation of topographic features

was due to the structural control resident in the moving glacier or in the ground
on which it lay. Along the lobes of many existing glaciers there are crevasses

266 CAPE COD GEOLOGY

that stand nearly perpendicular to the front of the lobe, but in none of the
stagnant glaciers in Alaska do such crevasses widen to form broad channels in
which deposits of drift have accumulated. In the channels on the south side of
Cape Cod such deposits were formed 25 to 30 miles back of the ice front while
the ice was at its maximum extent, when it covered the northern half of the site
of Nantucket. Certain ponds, such as those at the west base of Great Hill, in
Chatham, occupy ice-block holes whose sides are in part formed of much older
drift, showing that remnants of the ice there held open ancient channels in
what is here called the Chatham plain. Chains of ponds and waterways on the
south side of the Cape within these plains appear also to be old channels that
were in part filled with more recent drift that gathered around masses of ice,
which eventually melted and left depressions. The alignment of the lakelets
and ponds may therefore be a reflection of the topography of the Vineyard
interglacial stage just before the Wisconsin stage of glaciation. Such channels
extend north of the Falmouth moraine in Orleans and are well shown by the
trend of Town Cove. Lakelets did not lie in these old channels, because the ice
was there deepest and thickest and therefore remained longest.

Estimates as to the thickness of the ice which stood in these holes depend
on evidence as to whether the water supplied by the melting ice built up gravel
fans or formed outflowing streams. Many existing depressions are shallow saucer-
shaped pits, the ice in which may have been covered by gravel and sand. Such
pits are found in Alaska.! Great Pond is flanked by fans of drift, which was
probably derived from ice that rose above the level of the plain. The small,
high tables of drift about Long Pond, in Brewster, appear to have had the
same origin. From several ponds water now flows out through channels that are
much too large to have been cut by the streams that flow in them. Mashpee
and Cotuit rivers are examples of such drainageways. These shallow valleys
appear to have been cut by streams that flowed through them when the melting
ice in the ponds added water to the run-off arising from rainfall. Many lakelets
have such excurrent channels, which start out much above the level of ground
water. Ashumet Pond, on the line between Mashpee and Falmouth, is a typical
example of this type of glacial lakelet. Whether the water of a lakelet formed an
excurrent stream depended upon the height of the water table in the gravel and
sand, for the lakelets and ponds may be regarded as great open wells. A depres-
sion that does not descend to the depth at which water stands in the sand remains
essentially dry. Such dry kettles are found in the northern part of the outwash
plain about Falmouth.

1 Tarr, R. 8., and Martin, Lawrence, Alaskan glacier studies, Washington, 1914, Pl. 76.

-nenayresmeanmenomnncnente Ot

Gi al lp ge ga, SPOR gn MMU tee ce

CAPE COD GEOLOGY 267

A chain of ice-block holes that are occupied by lakelets extends from the
plain south of the Falmouth moraine into the higher ground of the moraine.
Long Pond, in Falmouth, is a conspicuous example of this entanglement of
remnant ice blocks of the Nantucket substage with the ice front of the Falmouth
or second Wisconsin substage. The ice blocks in Spectacle and Lawrence ponds,
near Farmersville, appear to have been pushed into by the Falmouth ice, as does
also the block that gave rise to Great Pond, in Barnstable. The Mill Ponds in
Brewster occupy a similar position, and numerous smaller ponds lie along the
southern edge of the moraine, showing that the Falmouth frontal lobe deployed
into a region that was still occupied by scattered masses of the Nantucket
ice sheet.

Upham ! has pointed out that the abundant supply of gravel and sand about
the ice blocks which gave rise to glacial lakelets of this kind must have come
from drift that lay well up in the ice sheet.

Masses of ice stood in the open ice-block holes south of the Falmouth
moraine during the second ice advance of the Wisconsin stage and lasted without
much change until the ice of that stage had disappeared; otherwise the outwash
of sand and gravel from the Falmouth ice would have obliterated the depres-
sions. The duration of the second or Falmouth substage was brief as compared
with the duration of the remnants of the Nantucket ice.

On the south side of the Cape, in addition to the ice block holes of the
Nantucket substage, there are a few hills of drift that rise above the level of
the plain. Falmouth Heights is such a hill. It borders on Vineyard Sound, is
about 40 feet high, and is evidently older than the low sand plain that surrounds
it on the landward side. The bluff, which is now in part revetted by a sea wall,
shows coarse cobbly drift and much glacial sand. Small boulders occur in the
talus and on the beach. The deposit has all the internal characters of a torrential
kame. Its form suggests that it was overrun by the Wisconsin ice sheet when
that sheet advanced to Marthas Vineyard. It is early Wisconsin or older.

Two small till-covered areas lie at the entrance to Lewis Bay, south of
Hyannis. The hill that rises above 60 feet at Hyannis Port appears to have
been strewn with small erratics, more of which are now gathered in stone fences.
The southwestern trend of the hill, parallel to that at Falmouth Heights, agrees
with the trend of the buried channels of the plain and indicates that ice moved
southwestward across this area during the Nantucket substage of glaciation.
Squaw Island, just back of Hyannis Point, is also a low mound of till. Boulders

1 Upham, Warren, Walden, Cochituate, and other lakes enclosed by modified drift, Proc. Boston
Soc. Nat. Hist., 25, 1891, pp. 228-242.

268 CAPE COD GEOLOGY

on both sides of the drainage crease at Craigsville show that till lies either at or
very near the surface. Great Island, whose southern part forms Point Gammon,
is also a till-covered tract. Another small tract makes up ‘‘Fish Hills,” called
Harbor Bluff on the map, at the entrance to Hyannis harbor. All these till-
covered tracts stand out because the sand of the plains on the north does not
cover them.

Large boulders lie at some places along the shore. Those south of Harwich
have been noted by Julien.! There are small patches of till on the beach at the
east entrance of Herring River; at Dennis Port; on the shore of Lewis Bay, east
of Hyannis; at three points on the beach at Succonnesset and farther north,
toward Poponesett Beach; and on Great Neck, in the southern part of Mashpee.
These are tentatively referred to the Nantucket substage, but some or all of
these deposits may be older.

It is not possible to distinguish the series of plains on the south side of the
Cape that were formed or finished by the wash of sand from the remnant of the
Nantucket ice from the series of higher plains farther north, which owe their
origin to outwash from the ice sheet at the Falmouth substage; for the two series
are so intricately interlocked that the attempt to make distinctions based not
on difference in material but on slope, position, or slight differences of level
would be long and laborious. A study either of the topographic map or of the
ground shows that the large tracts in front of the high plains that form the
southern border of the Falmouth moraine in Chatham, Yarmouth, and Barn-
stable were held open by masses of ice outside of the steep-sided ponds. Hun-
dreds of small pits and saucer-shaped depressions too shallow to be expressed
by the 20-foot contour interval of the topographic map dimple the surface, yet
on the map these areas appear to be smooth seaward-dipping plains.

Amid all the variety of relief due to the deposition of gravel and sand
between and around melting masses of the ice sheet in this region of broken
plains there are no traces above the present level of the sea of its former action
on the surface. It may therefore be inferred that neither at the time of the
Nantucket substage of the Wisconsin ice nor since that time has the sea level
here been higher than it now is. The ice blocks would have prevented tides and
currents from sweeping sand into the kettles and holes in the plains, but after
these ice blocks disappeared, tidal action upon these surfaces would have
built deltas backward into ponds having excurrent channels, and waves would

1 Julien, A. A., On the pebbles at Harw _ ae Cod), Mass., and on rude arrowheads found among
them, — = ser., 26, pp. 831-832,

S asnaeaanadimmanie * Pema

Te eC a MM oe Nag ee ee

CAPE COD GEOLOGY 269

have thrown the sand into beaches at scores of places that were identical in
exposure to those under which the beaches of the coast are found.

FALMOUTH SUBSTAGE
FatmoutaH Moraine

The Falmouth moraine forms the boulder-strewn belt of high ground
(Plate 34, fig. 1) that extends from Nauset Head, in Orleans, westward through
the northern part of the main arm of the Cape to Manomet Creek, where it
turns southwestward to Woods Hole and is continued in the Elizabeth Islands.
In Orleans this frontal moraine is scarcely distinguishable except by its boulders
and a slight thickening of the till over the older gravel and sand of the pre-
Wisconsin glacial deposits on which it rests. The small glacial erratics on the
surface about Chatham village and farther north, together with the deeply in-
dented coast line, suggest that the ice front turned sharply southward at Orleans
and that the edge of a lobate moraine covered the necks of land as far south as
Chatham and thence ran out to sea. This part of the frontal moraine contains
little drift in the angle between the off-shore lobe just mentioned and the lobate
moraine that runs westward to Buzzards Bay. Just west of Orleans, however,
the moraine becomes higher and thicker. The thickness of its beds of till or
boulder clay increases, as well as the thickness and breadth of the outwash sand
and gravel. From this point westward the outwash plain increases in size
through the towns of Brewster and Dennis. They are highest and broadest
just where the Cape peninsula is widest. In Yarmouth and eastern Barnstable
the moraine diminishes in breadth and continuity and the confronting plain is
correspondingly low and narrow, the change occurring nearly in the middle of
the are formed by the ice front that lay between the interlobate axis traversing
the eastern arm of the Cape and that traceable from Plymouth to the angle
near the Cape Cod Canal. West of Barnstable village the morainal belt grad-
ually rises in height from 100 feet to more than 200 feet and reaches a height
of 207 feet in Bourne’s Hill, south of Sandwich, the highest point in the Falmouth
moraine.

The highest points on Marthas Vineyard, Prospect Hill (808 feet) and Peaked
Hill (311 feet), in the Nantucket moraine, owe their height almost entirely to
older formations, whose topography was determined chiefly during the Vineyard
interglacial stage. Manomet Hill, the highest point on the west coast of Cape

Cod Bay in the Plymouth interlobate moraine, has an elevation of 394 feet.
The hill is covered with till, but underneath the till there are beds of stratified

270 CAPE COD GEOLOGY

gravel and sand that reach a height of about 250 feet above sea level where the
State road crosses the northern spur of the hill. The approach of the summits
of the pre-Wisconsin deposits to a height of 300 feet suggests a former base level
at that height.

Road cuts on the northern slope of Bourne’s Hill expose stratified beds of
gravel, sand, and clay under a thin veneer of till, generally less than 4 feet thick.
The mass of the hill is probably made up of outwash from the ice front.

From Bourne’s Hill westward and southwestward through the town of
Bourne the moraine forms the iceward border of a great outwash plain that is
backed by a high ice-contact slope having a morainal topography and a surficial
cover of thousands of granitic boulders, many of them gathered in huddles.
The Manomet Creek depression, which is followed by the Cape Cod Canal,
skirts this ice-contact border as a deep fosse separating the Falmouth moraine
at the interlobate angle from the huge mass of drift on the north, in the Plymouth
interlobate moraine. From Pine Hill, in Bourne (altitude about 260 feet) the
morainal mounds slope southwestward and the plain on the east slopes south-
ward, toward the Sound, at a steeper grade.

In this higher part of the Falmouth moraine the deeper cuts show that
stratified sand is the chief constituent of its mass. The till varies greatly in
thickness from place to place. Its greatest thickness is exposed in borrow pits
20 or 30 feet deep, but the till and coarse waterworn cobbly drift must form a
very small part of the total mass deposited by outpouring streams at the front
of the ice. Here as in areas farther east, in Brewster and Barnstable, masses of
the Nantucket ice sheet remained while the great fan of outwash sand was
deposited. Some of this sand was laid down in front of the ice, particularly in
Falmouth, where Long Pond, now the town reservoir, extends from the plain
halfway through the frontal moraine.

Many small sections exposed along the ice-contact face of this moraine in-
dicate that the ice kept pushing on the sand deposited immediately at its front,
advancing upon it one to three miles, as is well shown at the interlobate angle
southeast of the village of Bourne. The morainal ridge at Woods Hole, as indi-
cated by the mode of development of the moraine farther northeast, must also
be only superficially composed of bouldery till. Like other parts of the Falmouth
moraine it was doubtless laid down from ice masses at the Nantucket substage.
At many places these ice masses appear to have served as barriers behind which

outwash streams built up high-lying masses of sand and gravel. (Fig. 21).

CAPE COD GEOLOGY Zi1

Tur Outwasi PLaIn

The impressive feature of the Falmouth substage is the great fan of out-
wash sand in the towns of Sandwich and Falmouth. This fan spreads out from
the boulder-strewn ice-contact surface on the north, which stands at an eleva-
tion of 200 feet or more above the sea. Between the 200 and the 160 foot levels
this fan slopes southward and southeastward for a short distance at the rate of
about 100 feet to the mile. It stands behind the sites of the outlying ice blocks
that gave rise to Snake Pond, at Forest Dale, and the chain of waterless kettle
holes that lie at the east base of Pine Hill. This fan appears to have been the
last part of the sloping plain to have been deposited at the ice front. From
Snake Pond southward the slope is gentler but somewhat difficult to generalize
upon because tracts of lower ground appear to have been held open by remnants
of the Nantucket ice. South of the belt of ponds in the latitude of Hatchville,
in Falmouth, the surface is channeled by stream creases, which are found along
the southern border of the fan between Falmouth and the vicinity of Waquoit
Bay. The bottoms of the widened-out lower courses of these creases lie below sea
level and form a series of beach-barred lagoons whose longer axes are perpendic-
ular to the coast line, like those bordering the outwash plains of Marthas Vine-
yard and Nantucket.

North of the Falmouth moraine, along the shore of Cape Cod Bay, there
are a few till-covered morainal tracts, such as Town Neck and Scorton Neck,
in Sandwich, and Nobscusset Point and Quivet Neck, which rise nearly to a
height of 80 feet, in Dennis. Sections in cliffs or artificial cuts show that these
moraines are composed of beds of stratified gravel and sand. Precisely similar
low-lying areas lie inside of the moraine skirting Buzzards Bay and forming
so-called ‘‘necks,” or even islands, at North Pocasset, near Cataumet, and
between North Falmouth and West Falmouth. Near North Falmouth there
are no boulders on the surface, which has the form of a terrace of stratified
sand that stands 60 feet above sea level. The associated boulder-strewn tracts,
some of which are higher, are obviously older than the moraine, yet this terrace
shows a good ice contact at Cedar Pond and just north of it, along the inner
part of Cataumet harbor, and is probably a late outwash of sand from the
retreating ice front. This terrace was made above sea level.

THE INTERLOBATE MORAINAL AREA

Tur HASTHAM PLAIN

North of the town of Orleans there are deposits of drift which have been
regarded by some as more recent than the Falmouth moraine. Chief among

272 CAPE COD GEOLOGY

these deposits is the plain at Eastham, which filled in what may have been a
depression between the moraine at Orleans and the ‘‘table-lands of Eastham,”
in Wellfleet, before the ice began its retreat.

This plain is separated from the Falmouth moraine on the south by a narrow
belt of kames that extend across the Cape. The knobs and basins of this plain
are well shown about the hamlet of Eastham Centre and along the coast just
north of Nauset Beach lighthouse.! The kames in this plain were deposited
in the presence of ice and were originally probably an extension of the creased
plain on the north. Grabau first and Wilson later presented the view that
the Eastham plain was built from an ice mass lying east of the present coast of
Cape Cod by streams flowing westward, just after most of the ice had melted
away from the site of the moraine at Orleans.

The Eastham plain (also called the ‘‘table land of Nauset’’) presents a
relatively even crest to the Atlantic waves at its cliffed edge. From an elevation
of about 70 feet at its eastern margin the plain slopes westward and merges on
the south and southwest into a field of kames and ends rather abruptly on the
bay side in deeply indented knobs of sand and gravel. Its surface is traversed
by creases made by running water. The plain lies north of the bouldery moraine
about Orleans and south of the broken higher plain in Wellfleet, so that its
position and its slope toward the continent and away from the sea excludes the
supposition that it was modeled by the action of the sea.

The gravel and sand in the eastern bluff have been stratified by the action
of water except at the south end of the bluff, near the Coast Guard station,
where there is a bed of what appears to be till containing small pebbles and
subangular stones.

Grabau and, later, Wilson appear to have assumed that this deposit of sand
and gravel was laid down later than that found on the high plain farther north.
Although the section along the cliffs was not entirely free from talus at the
critical place at the time of my visit, it seemed that the beds on the seaward side
of the Eastham plain may extend northward in continuity with the beds of the
high plain in Wellfleet. If the beds of the Eastham plain were laid down later
an unconformable contact should occur at the junction, of the two plains where
the surface of the ground changes its level. The somewhat similar plain that
forms Pilgrim Head, at the north end of the Cape, is obviously a plane of erosion,

1 The two lighthouses shown on the topographic map of 1887 are'gone. On October 23, 1910, the north
light stood 16 feet back from the summit of the cliff and on August 7, 1916, the lighthouse tower, whose
base was about 15 feet in diameter, had fallen into the sea and the cliff was about 10 feet farther back
than the site of the tower. A new light stands somewhat back from the present cliff.

,
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CAPE COD GEOLOGY 213

and the gravel under the Eastham plain may have been laid down in the same
manner at nearly the same time. The creases here are of the type formed by
streams carrying little or no sediment and not heavily loaded distributary wan-
dering streams, such as are found on deltas and alluvial tracts that are being
actively aggraded.

Wilson! supposed that the Wellfleet high plain was formed by glacial streams
just before the Eastham plain was formed. He held that, at his Wellfleet stage
of Lake Shaler, the site of the Eastham plain was occupied by a tongue of ice
that extended eastward from an off shore lobe of the ice sheet. This explanation
of the kame field between the till-covered ground in Orleans and the creased
plain north of it overlooks the probability that ice from the Falmouth substage
remained there in stagnant patches. Abundant evidence of the existence of such
remnants of ice is found in the lakelets in the moraine, such as Cliff Pond and
the neighboring ponds in Brewster. The ice certainly stood on the sites of these
ponds until the end of the Falmouth glacial substage. The remnants of ice
about Eastham Centre were probably parts of the interlobate ice at the Falmouth
substage. Most of the ice on the site of the unbroken plain had no doubt then
melted except that in the creases about Eastham. The clear evidence that the
water which formerly discharged across the plain in the creases, the necessity
of admitting the existence at this time of ice on the east side of Cape Cod and
in the depressions and ice-block holes in Chatham, Orleans, Brewster, and else-
where in the low places of the moraine as far west as Sandwich appears to permit
no escape from the theory of Wilson that the water which gathered in the space
vacated by the ice back of the moraine found exit from the ice-barred growing
crescent in the southern part of the site of Cape Cod Bay to a lower level through
the Manomet channel or fosse.

To the water thus confined between the moraine and the receding ice front
in Cape Cod Bay Wilson gave the name ‘‘Lake Shaler.’ The water level of this
glacial-dammed lake, whatever may have been its extent, was controlled by the
sill of sand in the Manomet fosse at Sagamore, which stood nearly 32 feet above
mean low water in Buzzards Bay and more than 34 feet above mean low water
in Barnstable, or Cape Cod Bay, or a little more than 25 feet above mean sea
level This col is 27 to 28 miles south by west of the western limits of the East-
ham plain. The bottom of the Manomet valley is composed of stratified drift

1 Wilson, J. Howard, The glacial history of Nantucket and Cape Cod, pls. 36-37. New York, 1906.

2 Report of the Joint Committee of 1860 upon the proposed canal to unite Barnstable and Buzzards
Bays, Public Document No. 41, pp. 26, 31. Boston, State Printers, 1864. This report includes a profile
along the line of the proposed canal and a small-scale hachured chart.

274 CAPE COD GEOLOGY

showing signs of erosion by running water subsequent to the melting of the ice
sheet in the fosse. Manomet River, which drained the glacial lakelets in the
interlobate moraine, enters the fosse at North Sandwich and has cut a channel
below the old glacial level of the stratified drift, forming a low terrace. At the
west end of the fosse, on the shore of Buzzards Bay, the mouth of the river
is bordered by sand flats that appear to have been formed in glacial time. We
may therefore suppose that water once discharged from the basin behind the
Falmouth moraine across the divide in the fosse to lower ground in the depression
occupied by Buzzards Bay.

The height of the water level up to which the Eastham plain was constructed,
in Grabau’s view of its origin, is not readily determined. The eastern cut edge
of the plain at the grass line on the cliff obviously does not indicate the water
level on either the old view that such plains were formed entirely under standing
water or on the modern view that outwash plains of this kind are formed above
the level of standing water. According to the old view, as the plain originally
extended farther east and rose in elevation in that direction, the water level
would have to be put at an indefinite height. The summit of the cliff stands
somewhat below 80 feet. The North Eastham railroad station, which stands
about midway across the southern part of the plain, in the upper part of the
stream creases, stands at an elevation of 69 feet. In the areas west and north-
west of this station the western edge of the plain proper accords roughly with
a water level between 20 and 40 feet, but at some places, as west of the Methodist
Camp Ground and on the coast near Fresh Brook, where the plain is now narrow-
est, its western edge bears knobs of drift that have steep ice-contact faces on the
west, showing that they were formed in the presence of masses of ice. The
plain may have been built up by streams that discharged water into the site
of the Bay at a height about 30 feet above the present sea level, but the stream
creases descend to and below the present sea level in the area around Fresh Brook.
These stream creases were formed when the load of sediment had fallen off and
the water discharged from the ice was cutting down the plain to a lower base
level than that at which it was constructed. The streams at this stage could
not have discharged through the Manomet fosse into the Buzzards Bay region
but must have found some point of escape out of the bay at a lower divide in
the morainal barrier on the south, for the deep channel of Pamet River and the
now open bay on the north were then probably closed by the ice sheet. The
only passage sufficiently low to conform in height to these creases is that from

Boat Meadow Creek through Jeremiah’s Ditch into Town Cove, in Orleans, in

CAPE COD GEOLOGY. 275

the interlobate axis, where water may have found its way out. It would be diffi-
cult, however, to sustain this view by pointing out any effects produced by water
discharged along this course when the creases were being sunk into the surface
of the Eastham plain. Lake Shaler is not marked by shore lines and must have
been rather small and of brief duration at the stage of crease-cutting on the
Eastham plain.

Norra Truro PLain

Intimately connected with the Eastham plain by reason of its similar
elevation and the nature of the creases that dissect its surface is the North
Truro plain, which terminated the glacial deposits of Cape Cod at Pilgrim
Heights. This plain or terrace was made by the erosion of the beds that form
the west edge of the Wellfleet high plain from Highland Light southward. A
dissected escarpment separates the two plains along a southward-trending line
from Highland Light nearly to Pamet River. This escarpment is not, as Wilson
supposed, an ice-contact slope; it is an old erosion cliff that was greatly modified |
by stream action and glaciation. It is one of the most puzzling features in the
topography and glacial history of Cape Cod, and it has no counterpart in the
entire region except, perhaps, in the Plymouth region about Manomet Hill. The
surface of the North Truro plain is creased, as Grabau and Wilson have noted,
by very late Wisconsin streams, which discharged from the ice that lay around
the eastern, northern and probably the northwestern border of this plain.
When and by what agency was the North Truro plain cut down nearly to its
present level, which lies below that of the higher plains on the east and south?
At what stage of the ice retreat were the creases on the surface of the plain
produced, and in what direction did the water escape to the sea?

The plain was formed by the erosion of a once higher mass, the beds of
which are seen in the cliff at Highland Light. It was formed after the pre-
Wisconsin deposits were laid down in the Wellfleet tract, because the valleys
which intersect those deposits are traceable across the North Truro plain. These
valleys in the region south of Highland Light are well shown by the topographic
map. If the North Truro plain was cut back after the ‘‘hollows” or valleys of
the Pamet River type were formed the ‘‘hollows” should have been filled to
the level of the plain, even if they were afterward partly re-excavated when
surface water ran in the creases on the plain and elsewhere. This plain appears
to have been formed just before the Wisconsin stage of glaciation. It was prob-
ably once much wider and longer. Coarse gravel near Wood End, on the spit

at. Provincetown, indicates that this spit stands on a shoal that may represent

276 CAPE COD GEOLOGY

an island which has been reduced to sea level during the present stand of the
sea, when the cliff on the west side of the North Truro plain was cut. (Plate 265,
fig. 2.) The plain probably did not extend west of the line of beach between
Race Point and Wood End, because the sea floor there suddenly drops to depths
of 24 to 28 fathoms. It is not known whether the original plain was cut back
into the older Pleistocene deposits at Highland Light by glacial streams that
discharged southward across that part of the Cape in advance of the Wisconsin
ice sheet or whether it was formed at sea level by wave action during the latest
part of the Vineyard interglacial stage.

Most of the creases on the North Truro plain drain westward. Fine examples
of these creases may be seen at the North Truro railroad station, where they
come down from the clayey ground at the western base of the hill on which the
Highland light stands. A deep crease springs out from the air, so to speak, at the
crest of the cliff south of the lighthouse and follows closely the line of the escarp-
ment between the upper and the lower plain. Other short creases, which have
curving courses, lead down the northeastern side of the plain, showing that the
streams flowed in that direction, unless we may suppose that these creases were
formed by the run-off from the plain, an unlikely supposition, because of the
freedom with which rainwater soaks into the sand and gravel north of the clayey
tracts west of the lighthouse. The bottoms of these creases, like the bottoms
of those of the Eastham plain, were as low as the present sea level, and the
streams that occupied them probably found their way between the ice and the
gravel banks and joined those of the Chatham drainage system, which appear
to have been contemporaneous. The structure of the beds in the North Truro
plain and the extension of these beds into those at Highland Light, notwith-
standing the community of level of the two plains, does not seem to warrant
the assumption that a glacial lake was held in elsewhere by the glacier.

THe WELLFLEET PLAIN

There is abundant evidence in kettle holes and in downsunk beds of strati-
fied drift in the outer coastal section that at least the superficial parts of the
southern and eastern divisions of the Wellfleet plain were shaped by the Wiscon-
sin ice and that deposits were laid down from that ice either directly or by the
action of water. Kettle-hole topography is typically developed around the lake-
lets south of Pamet River. What appears to have taken place is as follows:

1. Deposition of a foundation of stratified material, including the beds at
Highland Light that suggest the Jameco gravel, the Gardiners clay, the Jacob
sand, and possibly the lower part of the Manhasset formation.

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CAPE COD GEOLOGY 277

2. Deposition or erosion of a then more extensive tract and, after its surface
had been shaped by deposition or erosion, its dissection by streams flowing to
a base level that is now submerged. The heads of most of the stream valleys
then lay on a divide east of the present coast line.

3. The Wisconsin ice sheet then advanced over this tract, filling depressions
with ice in the interlobate axis between the offshore South Channel lobe and the
Cape Cod Bay lobe. In the interlobate axis of two such lobes the motion of
the ice and its erosive power is at a minimum.

As the glacier melted, masses of the ice were left here and there in low places,
and the spaces about them, between the ice and the hillsides, were filled with
gravel and sand and some of the older valleys were more or less blocked, so
that many of the depressions in this glacial field, where pre-Wisconsin glacial
deposits and valleys are partly masked by Wisconsin ice effects, are very complex.

The ‘‘hollows” in this region are named and described in Blunt’s American
Coast Pilot. The first and northernmost of the ‘‘hollows,’’ known as Dyer’s
hollow, opens on the east coast of the Cape at a point 14 miles from the light-
house, at the clay pounds. No. 2, Harding’s hollow, which is 1% miles south
of Dyer’s hollow, is blocked by sand just north of Pamet River. No. 3 is at the
head of Pamet River, and No. 4, known as Brushy hollow, which is three-fourths
of a mile south of the head of Pamet hollow, is a narrow vale that runs into Pamet
hollow. No. 5, 3 miles south of Brush valley, known as Newcomb’s hollow,
lies east of the head of Herring River, in Wellfleet, and is a quarter of a mile
wide. No. 6, which is half a mile south of Newcomb’s hollow, is known as Pearce’s
hollow. No. 7, Cohoon’s hollow, is half a mile south of Pearce’s hollow. No. 8,
Snow’s hollow, is 2 miles south of Cahoon’s hollow. No. 9 is Fresh Brook hollow,
the name Fresh Brook appearing on current maps. No..10, Plumb valley, is
2% miles south of Fresh Brook, at a point just north of the Nauset Beacons on
the present map. These hollows afford opportunities for castaways on the
beach at the back of the Cape to reach places of refuge and the houses of the
inhabitants, so that they need not attempt to climb the steep sand and gravel
bluffs, which for long distances are unscalable.

PLYMOUTH INTERLOBATE MORAINE
As the retreating ice sheet in Cape Cod Bay melted and permitted the
drainage from the lobe lying east of Cape Cod to discharge westward into the
basin just vacated by the ice, so the lobe lying west of the Plymouth interlobate

1 Blunt, Edmund M., The American Coast Pilot, 11th ed., pp. 71-74, 1827; New York, also 13th ed.,
pp. 179-183, 1837. :

BUZZARD'S BAY LOBE

278 CAPE COD GEOLOGY

axis appears to have melted out faster than the lobe lying in Cape Cod Bay,
for there are similar high plains of stratified drift that slope westward and south-
westward from the axis of the lobe into the basin vacated by the ice of the
Buzzards Bay lobe. This earlier melting of the ice on the western sides of the
interlobate axes in these two fields may mean that the ice was thicker and main-
tained longer, more vigorous advance over the Bay of Maine than over southern
New England. This difference may not have arisen so much from inequality in
the snowfall in the eastern and western parts of northern New England and the
adjacent gathering grounds on the north as from the fact that, in Vermont and
New Hampshire, the ice sheet encountered high mountain barriers that restricted
its flow to the southern part of the field after the Labrador ice sheet began to

pt

CAPE COD BAY LOBE

PRESENT.

APE COD HIG
LAINS OF WEL

melt. Farther east, over the site of Maine, broad lowlands stretched between
the White Mountains in New Hampshire and Mount Bigelow, and between
Mount Bigelow and Mount Katahdin. Another result of this freer flow of ice
across Maine and east of Massachusetts is the apparent extension of the ice
front, at least at the Nantucket substage, southeastward from Nantucket over
Nantucket shoals and Georges Bank.

The accompanying theoretical cross section (Fig. 22) in the latitude of
Manomet Hill near Plymouth and the high plain near the Highland Lighthouse
shows the relation of the ice sheet to the glacial formations before the ice sheet
disappeared from the vicinity of Cape Cod Bay. Some such relation between
the lobes of the ice sheet and the deposits made or left in the interlobate axes
out of the path of maximum motion and most effective erosion of the ice
began to give shape to the features of the land in the earlier ice advances.

SEA LEVEL

Fig. 22.— Theoretical cross-section of Cape Cod interlobate axis, Cape Cod Bay, and the Plymouth interlobate axis, with the
Wisconsin ice sheet at the Falmouth substage.

\
( CAPE COD GEOLOGY 279

POST-GLACIAL OR RECENT CHANGES

Cape Cod more than any other part of southeastern New England shows
the changes due to the ravages of the sea since the glacial epoch. As the changes
in the inland part of the area are insignificant compared with those that occurred
along the shore, they will be considered later.

\ CHANGES IN THE SHORE LINE

The east coast of Cape Cod is somewhat protected from the attack of the
| sea by the great shoal known as Georges Bank, which lies southeast and east
of the Cape at distances of 80 to 140 nautical miles. This shoal breaks the force
of seas running from the east and southeast, but the Cape is exposed to the full
force of northeast storms, which have a fetch of more than 250 nautical miles
measured from the southern prong of Nova Scotia, and of a much greater fetch
measured from the Bay of Fundy. Since glacial time considerable land has been
lost on the east coast and the outline of the coast has been reduced to its present
form, in which irregularities have been cut away to form a graceful curve. This
cutting has been accompanied by the building up of great hooks and spits of
: wave-washed sand encumbered by dunes formed by the wind that sweeps the

beaches. The submarine contours off the east coast of the Cape conform to the
curvature of the shore line down to the depth of 24 fathoms. Those that lie at
greater depths, south of Nauset Light, do not show like conformity. The curva-
ture of the coast line increases westward as the exposure of the shore to the
northeast storms increases, until at Highland Light the coast trends about 502
west of north. It turns within two miles to 70° W. on the bar that extends the
Cape toward its northernmost reach, where it recurves to the southwest toward
Race Point. The contour of the sea bottom below a depth of about 30 fathoms
suggests that the original trend of the Cape did not differ much from its present
trend from High Head as far south as Chatham.

As the submerged ridge between the north end of the Cape and Stellwagen
Bank lies at a depth of about 24 fathoms, the land probably did not extend out
beyond that depth, although the shore line may have been shifted inward by
the erosion of the bottom or outward by deposition. At and off the headland
of the Cape an old shore line lies 5 miles from the present shore. The nature of
this headland of interlobate morainal material indicates that along the old
eastern shore line there was an embankment or ice-contact slope along which
| the surface of the Wellfleet and Eastham plains dropped to a lower level, such

i
i
:

ee CAPE COD GEOLOGY

an embankment as the mass of drift that skirts the west coast of Cape Cod
Bay and forms an irregular wall of drift that rises above the present sea level.
An estimate of the height and the extent of this outer bank may be made by a = |
theoretical reconstruction of the Wellfleet and Eastham plains on a hypothesis }
supported by a comparison of such deposits — namely, that the Eastham plain
at its original summit along the ice contact rose as high as the Wellfleet plain.
Assuming that the higher plain stood at an altitude of 120 feet at its iceward
border, as it does just north of the Eastham plain, the eastward rise of the
Eastham plain would reach this altitude at a distance of about 3 miles off the
present coast. This estimate is of the same order of magnitude as that reached \
by Davis. If the assumed rate at which the coast was cut back approximately <
during the present stand of the sea holds good, this work could hardly have
been begun more than about 3,150 years ago. As the minimum estimate of the
time since the ice sheet disappeared is more than twice this number of years
and as the maximum is many times longer, the Cape would now have been nearly
cut away by the sea if some cause had not prolonged its erosion. If the sea
began its work when the land stood about 30 fathoms higher than it now stands
in relation to sea level in the latitude of the middle of the arm of Cape Cod,
the discrepancy may be accounted for by assuming an attack of the sea, brought
about after a period of subsidence, on a prism of land that lay between the
initial plane of marine erosion at the end of the glacial epoch and the present
higher plane.

6

Gulliver ° describes Cape Cod as ‘‘a winged beheadland which projects far |
into the sea, so that the wings do not extend across the bays on either side.”’
Davis * has considered at length the change from the presumable original glacial
outline of the land to its present form under the action of the sea. Within
historical time the headland has receded more than a third of a mile. On the
south, in the zone of the winged bars of Chatham, small islands of glacial drift
have disappeared. Mitchell * gave an account of these changes in a report
concerning Nauset Beach and the peninsula of Monomoy,’ and a brief summary
of them is given by W. C. Smith.® From these and other sources of information
1 Davis, W. M., The outline of Cape Cod, Proc. Am. Acad. Arts and Sciences, 31, pp. 302-332.
* F. P. Gulliver, Shoreline topography, Proc. Am. Acad. Arts and Sciences, 24, 1899, p. 213.
3 Davis, W. M., The outline of Cape Cod, Proc. Am. Acad. Arts and Sciences, 31, 1896, pp. 303-332.
‘ Mitchell, Henry, Nauset Beach and Monomoy peninsula, U. 8. Coast Survey Report for 1871. Ap-
pendix 9, pp. 184-148, Sketch No. 35. |
° For a list of the 39 different ways in which this aboriginal name has been spelled and pronounced, |
see William C. Smith, A History of Chatham, Part I, p. 1, footnote, Hyannis, 1909. Monomoit and .
Monomoy are variants of the same name. Monomoy is now restricted to the beach south of Chatham. [
°Smith, W. C., A history of Chatham, Part I, pp. 6-11, 1909, with plate reproducing part of Cham-
plain’s map of Fort Famine showing the beach at Chatham in 1606.

CAPE COD GEOLOGY 281

\ it appears that at the time of the American Revolution Nauset Bar lay farther
| out than it now does and that there was an open lagoon between it and Nauset
| Head. Until the great storm of November, 1730, there was an opening in this
/ bar into Pleasant Bay at a point east of Strong Island. South of this opening
a bar extended southward toward Chatham. Inside of this bar, near Allen’s
Point, lay Ram Island, which appears to have been enclosed on the north by
the hook of the bar of Champlain’s chart which joined the land at North Chatham.
Ram Island, Cotchpinicuit or Scotchpenacot, as it was known to the aborigines,
is shown on Des Barres’ chart as lying east by south of Allen’s Point. Mitchell ’
\ describes the island as shown on the first topographical map by Gluck in 1847
as then having an area of 13 acres, an elevation at some places of 20 feet, and
some kind of building on it. A breach in the beach lay directly before the island,
so that it was exposed to storm waves, but it continued to be used as a pasture
down to 1851, when the Minot’s gale washed it away, though traces of it could
| be seen for a few years later; but in the topographic survey of 1868 it could not
be found.

Whiting * states that the Minot’s lighthouse gale, which occurred in the
| middle of April, 1851, breached the outside bar at Nauset for 500 feet. The
channel thus produced, which was 11 feet deep, remained up to 1867.

Numerous changes have taken place in the position and extent of the bar
and the openings at Chatham since reliable charts of the locality were made.
In Des Barres’ time the inlet had the general form shown on the chart of 1887,
except that the Monomoy Beach bar broke off from the beach flat south of the
inlet and joined the land in front of the village, about as it did in 1915-16. In
an easterly gale on November 15, 1871, the bar opposite Chatham lights was
broken through (Plate 34, fig. 2.) This breach appears to have rapidly shifted
southward by the wearing away of the north end of Monomoy Beach and the
southwestward building of the Nauset Beach, which according to a survey

1 Mitchell, Henry, Additional report on the changes in the neighborhood of Chatham and Monomoy,
U.S. Coast Survey Rept. for 1873, Appendix 9., pp. 103-107. Mitchell’s first report was also printed
in the Seventh Annual Report of the (Massachusetts) Board of Harbor Commissioners, House No. 65,
Jan. 1873, Boston, pp. 94-108, 1873. Townsend, C. H., Notes on an early chart of Long Island Sound
and its pain, U.S. Coast and Geod. Sane bot for 1890, Appendix No. 20, pp. 775-777; illus-
tration No. 71 reproduces Captain Southack’s (?) chart of Cape Cod. Mitchell, Henry, Monomoy
and its shoals, Ann. Rept. of the (Massachusetts) Harbor and Land Commissioners for 1886, Public
Document No. 11, Appendix A., pp. 37-46; with map showing changes in Nantucket Sound from 1784
| to 1885, Boston, Macs. 1887. Des Barres, Joseph F. W., The Atlantic Neptune, London, 1774-1781,
| .8, charts of the coasts and harbors of New England, fron surveys taken by Saml. Holland .. . Survr.
general . . . and Geo. Sproule, Chas. Blascowitz, Jams. Grant and Thos. Wheeler . . . for the use of the
, royal navy of Great Britain.
f . fo concerning Nauset Beach and the Peninsula of Monomoy.
3U. 8. Coast Survey Rept. for 1867, p. 157. For an account of the “Lighthouse” storm of 1851 see
Sidney Perley, Historic storms of New England, Salem, 1891, Chap. 70, pp. 302-310

282 CAPE COD GEOLOGY

made in January, 1873, had joined the mainland near Chatham lights. For
some time after the gale of November 15, 1871, the bluff near Chatham lights
was exposed to the sea. Later the bar was re-formed in the manner shown on
the chart of 1887. Since that time the hook on the north side of the inlet has
grown southward about a mile. In 1916 the inlet was correspondingly south of
its former position, and the Monomoy Beach joined the land at Chatham.

The swampy tract between Chatham and Morris Island is represented on
Champlain’s chart as an open passage which, according to Mitchell, became
closed between 1752 and 1772. In 1916 the tide was flowing across the swamp
and bar on the north side of the island.

Monomoy bar, on Monomoy Island, undergoes frequent changes. Again
resort must be had to the reports of Henry Mitchell! for an account of it, from
1784 to 1885.

_ From this account it appears that the south end of Monomoy has shifted
» eastward as if it had fallen back with the retreat of the headlands on the north,
and the southern tip has advanced southward much more rapidly. During the
first period of accurate surveys of the position of the south point, between
1840 and 1853, the point gained in southing only about 140 feet. During
the next three years, between 1853 and 1856, the point gained 509 feet to the
southwest at a rate of 170 feet a year. At the time of the next determination of
its position, in 1868, the point was about 2,123 feet farther southwest, an advance
made in 12 years at the rate of about 175 feet a year. In June, 1886, the point
has grown southward, but at a slower rate, 223 feet a year. Mr. Mitchell con-
cluded that the longshore drift from points north of Chatham became lodged
somewhere north of Monomoy. It also became evident that the growth of the
flying beach was subject to periods of maxima and minima of change.

Between Monomoy and Great Point, the corresponding flying beach at
the entrance to Nantucket Sound, there are numerous shoals of shifting sand.
These form a sort of broad belt, which curves eastward. Fear has arisen that
the flying beaches of Monomoy and Great Point might be built up by the sea
on the crest of these shoals in such manner as to close the entrance to Nantucket
Sound. This change, which would be fraught with embarrassment to the coast-
wise navigation, seems now, so long as land and sea remain stable, not likely
to take place, because the shoals lie well eastward and seaward of the flying
beaches, which are not only inclined inward, toward the axis of the sound, but
are ee in that direction. This inward movement of the flying beach is

n. Rept. ee Harbor and Land Commissioners for the year 1886, pp. 37-46; with
map. ae 1887

?
|
\
}
t
|
|
'
\

CAPE COD GEOLOGY 283

clearly shown by the changes at Monomoy, but is less obvious from the charts
and surveys of Great Point, on Nantucket. Nevertheless, as the headland
on the east side of Nantucket recedes with the attack of the sea, so must the
flying beach attached to it recede with the recession of the shore. Handkerchief
Shoal, off the southwest end of Monomoy, actually extends the flying beach about
one-third of the space between the southern point of Monomoy bar and Great
Point. This shoal has grown southward since accurate surveys of it were first
made. On the other hand, Great Point, the end of the flying beach from Nan-
tucket, has been nearly stationary, and its underwater extension turns abruptly
northeastward. In fact, the end of the bar has receded several hundred feet
during the last century, whereas Monomoy has been built out as much as two
miles. Thus, while the space between the points is becoming narrower the
Monomoy beach is working southwestward and forcing the current southward
against Great Point, and this process will apparently continue for a long time,
because more sand is available for transportation from the shore of Cape Cod
than from Nantucket. Furthermore, the coast of Cape Cod, unlike that of
Nantucket, is not defended by off-shore banks and shoals.

WEBB’S ISLAND

Local histories repeat an account of the disappearance of ‘‘Webb’s Island,”
which once lay southeast of Chatham or of Stage Harbor, and hence outside
of the existing Chatham or Monomoy bar, in such manner as to have been ex-
posed to the attack of the sea. The earliest account of the disappearance of this
island is given by a writer! in the Massachusetts Magazine for December, 1790,
who says:

When the English first settled upon the Cape, there was an island off Chatham, three
leagues distant, called Webb’s Island, containing twenty acres, covered with red cedar or
savin. The inhabitants of Nantucket used to carry wood from it. This island has been wholly
washed away for almost a century. A large rock that was upon the island and which settled
as the earth washed away, now marks the place; it rises as much above the bottom of the
sea as it used to rise above the surface of the ground. The water is six feet deep on this spot.

The article quoted fails to give the direction in which the island lay from
Chatham. As the island seems to have disappeared about 1700 it ought to
appear on charts published before that year and to be missing from those pub-
lished later. Henri de Champlain shows no such island on his chart of the
coast drawn in 1606, nor does Captain John Smith or later navigators, though

1 Quoted by William C. Smith in A history of Chatham Hyannis, 1909, Part I, p. 11, footnote 25.
Smith supplies the direction “southeast from Stage Harbor” in his account, stating that the existence
of the island is established by unanimous local tradition.

284 CAPE COD GEOLOGY

most if not all of them had troublesome experiences with the shoals off Monomoy
beach. There is thus no seaman’s record of a lost island lying southeast of
Chatham from 1606 onward.

In his cautious remarks upon the ‘‘lost island” Mitchell notes that a map
of Nantucket Sound and Nantucket Shoals in The English Coast Pilot of 1707
shows a ‘‘Webb’s Island” as a part of the sand flat in Monomoy Beach, south-
west of Chatham Harbor. The Southack (?) chart, which bears an inscription
noting the crossing of the Cape at Orleans by a whale boat in 1717 and which is
probably the same chart as that of 1707, also shows Webb’s Island. This name
was well established in Chatham for a part of the Monomoy bar as it existed
in 1738, half a century before the legend started in the Massachusetts Magazine,
as shown by a record reproduced by Smith ! from the files of the Superior Court
of Judicature describing lands on Monomoy Great Beach, in which it appears
that there is a reference to the ‘‘marsh which lies to the northward of a place
called Webb’s Island.”’ It would appear that Webb’s Island was an integral
part of the shifting winged beach of Monomoy. There seems no good reason to
believe that ‘‘Webb Island” lay outside of the beach.

Mitchell notes that on the Atlantic Coast Pilot chart of 1707, and the
Southack (?) chart in use in 1717, there is inscribed off the south end of Webb’s
Island the words, ‘‘the Seal Island sunken channel way,” presumably a refer-
ence to land that disappeared before 1707.

THE PROVINCELANDS HOOK

At the north end of Cape Cod peninsula there is a historic sand hook
known as the Provincelands, the title to which is held by the Commonwealth.’
Several detailed maps of Provincetown harbor and the surrounding dunes and
bars or barrier beaches have been made from time to time, because the harbor
is a port of refuge and a fishing station. The most elaborate study of the origin
and mode of development of the hook is that made by W. M. Davis * in 1896.
It constitutes the northern complement of Monomoy flying beach, the wing-
bar of Gulliver’s winged beheadland of Cape Cod. Davis called attention to the
fact that before this wing-bar or sandy hook was formed, the sea played freely

1 Smith, W. C., A history of Chatham, Mass., Part II, p. 208, footnote 27, Hyannis, 1913.

_ ? For the history of the control of these lands by the State and the attempts to regulate the work of
the winds in blowing the sand, see Second Ann. Rept. of the Trustees of Public Reservations, for 1892,
Appendix III, House No. 339, pp. 65 et seq., Boston, 1893. The original State document contains a
map of the dunes drawn with a 5-foot contour interval.

5 Davis, W. M., The outline of Cape Cod, Proc. Am. Sci., 31, pp. 303-332, 1896. Also reprinted in
Geog. Essays, edited by D. W. Johnson, Chap. 25, pp. 690-724, Boston, 1909.

CAPE COD GEOLOGY 285

around the end of the glacial part of the Cape, forming the headland known as
Pilgrim Heights, or High Head, in North Truro.

High Head, or Pilgrim Heights, is cliffed in three directions, none of which
coincides with the present trends of long-shore marine action. On the north side
of the head there is an old, somewhat dissected cliff which is about 2 miles long
and is separated by the ‘‘Salt Meadow” from the dune-crested beach that joins
the Provincelands on the ocean side to the end of the Cape near Highland
Light Coast Guard Station. This cliff is regarded by Davis as a remnant of
an early, outer coast line of the headland of Cape Cod, a line that existed
about 1,200 years ago. As the coast of the ocean or ‘‘back” side of the Cape
retreated under the action of the sea and straightened out, the flying beach
would spring off from the head of the Cape near B and the sandy hook beyond
the point of contact with the coast would grow outward. Thus the oldest
part of the hook at Provincetown is on the inside next the harbor and the
newer part on the north. :

The cliff on the west side of High Head is older and is apparently contem-
poraneous with that on the north, behind the Salt Meadow, cut before the
flying beach and hook at Provincetown began to form, and a newer one farther
south which, as it lies farther east, has sent off a flying beach from the head
enclosing Pilgrim Lake, or East Harbor, as the lagoon was called before this
beach united with the main beach.

In 1916 Vaughan observed on the outer beach, near Woods End, at low
tide, a small area of angular gravel of glacial origin that seems to be abnormal
for the hooked spit there, which appears to rest upon an older deposit. This
gravel must have formed a shoal before the Woods End spit was built out to
its present outline. As the cliffs at Pilgrim Heights indicate an open sea when
they were cut, the time of the removal by wave action of glacial deposits there
that lay above sea level was probably the time the shoal was formed. The shoal
and any island or land that lay in that position would have given direction
and support to the sand-spit that now forms the outer barrier of the harbor.
The gravel recalls the Jameco (?) material underlying the Gardiners (?) clay
at Highland light, and this material extended over the site of Provincetown
harbor before the land was cut away to form the cliffs at Pilgrim Heights.

The Provincetown wing-bar has undergone little change since it was first
mapped. In 1857 Whiting found by comparing late maps with those made
by the survey of 1849, that the changes were most pronounced near Race Point
and East Harbor. Lance’s Harbor had been closed, and the enclosing beach

286 CAPE COD GEOLOGY

for 23 to 3 miles between Race Point and Long Point, forming the western
finger of the Cape, had been driven in from 100 to 300 feet. In 1849 the beach
between East Harbor and the ocean was about 300 feet wide where narrowest
and about 40 feet high.! In 1857 Mitchell found the beach at this place about
100 feet wide and 12 to 15 feet high. He records a report that the sea had
broken over this place in the preceding winter.

Certain small-scale maps that form illustrations in books published at the
end of the eighteenth century? show a passage through the outer beach at
the west end of East Harbor (Pilgrim Lake on recent charts), seeming to indicate
that for a time after the survey by Des Barres the sea broke through the bar
at this place; but no authentic record of such an occurrence has been found. Any
such irruption, however disastrous it might have been to Provincetown Harbor,
would have soon been closed by the long-shore transportation of sand from
the cliffs of Truro and Wellfleet.

In 1868-69 a dike was built at the ‘‘wading place” at High Head (or Pilgrim
Heights) by the United States, and another dike was built to close the connection
between East Harbor and the bay, thus converting the East Harbor into Pilgrim
Lake. In 1870 a dike was built at the head of Lancy’s Harbor, at the foot of
Abel Hill, to prevent the flow of the tide from Lancy’s Harbor into Provincetown
Harbor. More recently a dike has been built from Steven’s Point across the
House Point Island flats to Long Point. Formerly there was a small islet on
these flats, known as House Point Island, which has gradually disappeared.
In 1890 Marindin found Lancy’s Harbor a ‘‘dry sand and gravel slough.”’

In the Coast Survey Report of 1867, Whiting * states that, between Graham’s
survey in 1835 and his re-survey in 1867, Long Point had become extended
above high water as much as 2,460 feet. The flats between Long Point and the
western part of the village advanced in the same period (32 years) an average
distance of 275 feet upon the harbor. Beach Point, which was built out from
the west side of High Head, advanced in the same period 1,000 feet on the south
side of East Harbor, but the main shore of the inlet opposite the point had re-

‘In addition to the general charts of Cape Cod already listed, there is a chart of Cape Cod Harbor
by J. D. Graham, U. 8S. Topographical Engineer, 1836, accompanying Document 121, 25th Congress,
2nd session, surveyed 1833-35, scale 1/10,560. The harbor was surveyed by the U. 8S. Coast Survey
in 1849, and re-surveyed by H. L. Whiting in 1857, see U. S. Coast Survey Report for 1857, pp. 148-
149, plate No. 9, map of Provincetown Harbor. Whiting made another survey of the harbor in 1867.
Again the harbor was surveyed by Henry L. Marindin in ne see U.S. Coast and Geodetic Survey for
1891, Part 2, Appendix No. 8, pp. 288-288, plates Nos. 11, 12

z The State of Massachusetts from the best information, 1799, Engraved for New Encyclopedia.
Published by I. Low, New York, Scale, 20 miles to one inch. A map of Massachusetts, from the best
authorities, by J. Denison, published by Thomas & Andrews, Boston. No date. Scale 1/564,960.

°U. 8S. Coast Survey Report for 1867, pp. 151-156.

CAPE COD GEOLOGY 287

ceded 200 feet. At the same time the bar had moved inward about 200 feet.
On the ocean side of the harbor Whiting found the bar still more reduced in
width and height than it was in Mitchell’s survey, and he recommended that the
East Harbor be closed.

In 1890 Marindin found that the outer beach back of East Harbor had come
in still farther since the survey of 1867, so that the width of the barrier there
had been reduced; also that although the harbor opposite the town showed
scouring and deepening, the mud flats between Stevens Point and Long Point
had advanced somewhat into the harbor.

The surveys of Monomoy and Provincetown harbor showed that much

_ more material is being transported southward along the Cape to the sand bars

of Chatham and Monomoy than northward to Provincetown because of the
greater force of the northeast storms. Moreover, Cape Cod is fended on the
southeast by great shoals from the full force of the waves. During a northeaster
the Provincetown spit is driven in from the ocean side, hence the bar that ends
in Long Point. Only a small part of the sand and gravel taken from the high
cliffs of Truro and Wellfleet appear to lodge above sea level on the Provincetown
bar, and Nauset Beach and Monomoy probably draw supplies from the shore
north of the middle of the coastline, between the ends of these bars. The low
plain of Eastham becomes thinner toward the west, as does to some extent the
high plain of Wellfleet, which also decreases in thickness westward owing to the
widening and deepening of the hollows in that direction, and the consequence
is a reduction in the quantity of gravel and sand that is fed to the longshore
current on the ocean side. Marindin shows that the rate of retreat of the coast
is most rapid along the Truro plain — about 8 feet a year as compared with
5 feet a year along the Eastham plain — so that a large part of the material
handled by the waves and currents comes from the erosion of the high cliffs
of Wellfleet and Truro. This more rapid retreat on the north turns the curving
coast farther to the west of north and diminishes the southward component of
longshore shift of material during northeast gales. The drift of sand toward
the Provincetown bar being thus increased, if it should counterbalance the loss
from the decrease in thickness of the deposits above sea level as the coast recedes,
would tend to establish stability and to preserve Provincetown harbor, at least

in outline.

On the inside of the arm of the Cape there are a number of islands and
offshore bars that end on the south in Billingsgate Island. On Des Barres’
chart (1780) no barrier beach is shown between the land at South Truro and

288 CAPE COD GEOLOGY

Bound Brook Island nor between Griffin Island and Great Island and Great
Island and Great Beach Hill Island, such as is shown on the chart of 1887.
It is said that the barrier beach once continued southward to Billingsgate Island
and beyond it to the little remnant hook island farther south, on which Billings-
gate lighthouse stood in the 70’s, when a remnant of this barrier beach formed
a small island between Beach Hill Island and Billingsgate Island. In recent
years much of the northern part of Billingsgate Island has been washed away.

BARNSTABLE BEACH

Barnstable Harbor, on the south shore of Cape Cod Bay, is guarded on
the north by a long barrier beach that is built eastward along the curving shore
where the sea beats against drift hills back of the frontal moraine, such as Scor-
ton Neck, to which the beach is an appendage.

A detailed chart of Barnstable harbor, on a scale of 1 to 20,000 was prepared
in 1861 by Henry Mitchell and published in the U. 8. Coast Survey Report for
that year. (See page 34, chart No. 5.) The beach known as ‘‘Sandy Neck’’
has undergone few changes since this survey was made. It is said that since the
breakwater at the entrance to the Cape Cod Canal was built the beach along
this shore has begun to wash away. If this statement is true the change has
probably occurred because the longshore drift from the high cliffs on the west
side of the Bay no longer reaches the barrier beaches east of the canal and must
therefore be deposited near the breakwaters of the canal.

THE SOUTH SHORE OF THE CAPE

The south shore of the Cape is lined by barrier beaches that face the rela-
tively quiet water of Nantucket and Vineyard sounds. Some of these barrier
beaches form small winged beheadlands, such as that on the Neck near Oster-
ville, and on Powers Neck. A curved bar and beach forms the shore of New
Harbor near Centreville. Beach cusps may be seen at Cotuit Highlands, at the
entrance to Osterville Harbor, at Hyannis Point, in the beach barrier to Great
Pond, in Falmouth and Waquoit Bay.

LAND-TIED ISLANDS

Certain small peninsulas appear to be land-tied islands, particularly those
on the Buzzards Bay shore, such as Wenaumet Neck, Scraggy Neck, Bennet’s
Neck, Chappaquoit Point, Long Neck, Great Island (Point Gammon) off
Yarmouth, Morris Island (near Chatham), Indian Neck (near Wellfleet), and
the so-called islands between South Truro and Great Beach Hill Island.

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Mf A

na Somalis

sccsuisiuaiesnaampses pees le

CAPE COD GEOLOGY 289

Not every body of land that is formed of glacial drift and is tied to a larger
land mass has been an island since the glaciers disappeared. When the land
stood higher in relation to the sea, the depressions between the elevations that
now form most of the islands in the Cape Cod district were simply low places
in the land. As the sea rose it would reach the level of one of the depressions
and flood it with sea water, making an island out of the detached fragment of
land. If, however, the beach action were sufficiently strong a barrier beach might
be thrown across the depression as fast as it became lowered below the level
of the sea, and thus the beach-tied island may have existed as an island except
for some temporary irruption of the sea over the beach barrier.

The arm of Cape Cod from Town Cove northward consists at present of
two islands tied together by a bar at the head of Pamet River. The southern
or Eastham member of this insular group is separated from the mainland by the
old boat channel from Boat Meadow River through Jeremiah’s ditch to Town
Cove. A dike that has a gateway just west of the railroad track about a mile
north of the Orleans railway station prevents the sea from flowing through this
ancient channel, most of which is filled with marsh vegetation.

The old glacial drift at the head of Pamet River has been cut away and the
sea has been brought into contact with a depression, just as it has at Blackfish
Creek, in South Wellfleet, where the coast is now about three-fourths of a mile
from the head of a depression. Without any change in the level of land and
sea, the coast will after a time have receded so far as to admit the ocean to the
east end of the creek unless a bar is thrown across the entrance. Blackfish Creek
probably represents an early stage of the Pamet River depression before the sea
had cut back the coast so far as to tap the valley.

If we plot the direction of the longshore drift against the chief tangent
bars and winged beaches of the Cape and Bay inside it (see fig. 23) it will become
obvious that wash from the shores of the Bay become pocketed except where
tidal scour carries them out upon the bottom, and that the headland of the
Cape is being driven inward by a general southward movement of the coastal
waste.

WoRK OF THE WIND oN CAPE Cop

The geological action of the wind on Cape Cod consists of the deflation of
the glacial gravel of the upland, the erosion of the cliffs, and the formation of
dunes along the beaches.

290 CAPE COD GEOLOGY

N. TO NE.

ge

“st

Fig. 23. — Outline map of Cape Cod and Cape Cod Bay showing longshore drift, as indicated by the chief beaches and sandbars.

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CAPE COD GEOLOGY . 291

THE DEFLATION OF THE GLACIAL GRAVEL

At many places on the Cape, particularly near the brows of the cliffs, the
wind has swept away the soil and is moving the glacial sand across tracts of
lag gravel. The pebbles and the angular rock fragments in such tracts thus
become highly polished and carved. The ‘‘blowholes”’ or lag-gravel tracts and
the windswept face of the cliff at Highland Light afford an excellent field for
observing the action of wind on glacial material. Some of the effects of this
action have been described by Davis,! who found that sand-blasted pebbles or
glyptoliths are widely distributed on the Cape in places where the stratified
glacial gravel is exposed to the action of the wind. He also described numerous
glyptoliths that were buried, with the carved side up, in the superficial part
of the glacial gravel. He writes: *

The highest cliff of stratified sands and gravels on the southern shore is at Succonnesset
Point, between Falmouth and Cotuit. The bluff here rises twenty or thirty feet above sea-
level. The occasional pebbles scattered through the greater part of this section were not
facetted, but in the upper eight or ten feet, where pebbles were common, many carved
pebbles were found, and, as before, they lay with the facetted side uppermost. The greatest
depth at which a pebble with distinct facets was found was about nine feet beneath the
surface. Many carved pebbles were found along the base of the cliff, sometimes, apparently,
in place, but then held in large masses of gravel which had slipped down from the top of
the cliff.

If it be postulated that these buried facetted pebbles have been carved by wind-blown
sand, as they certainly seem to be, then it must be concluded that at least those beds of
stratified sands and gravels which contain facetted pebbles were deposited by subaerial pro-
cesses, and not by marine processes below sea level.

In addition to the more or less symmetrical carved pebbles bearing facets
whose intersection produces edges there are pebbles in which grooves and pits
have been worn by the sand blast. These sand-blasted pebbles are found in

- situations which indicate that they were shaped at many times since the glacial

period, or at all times, for they are obviously now being shaped.

The following data concerning the direction of the wind at Provincetown,
obtained by Dr. T. W. Vaughan from the United States Weather Bureau, may
be serviceable in an investigation of the dunes and sand-blasted pebbles at the
upper end of Cape Cod.

1 Davis, W. M., Facetted pebbles on Cape Cod, Mass., Proc., Boston Soc. Nat. Hist. 26, pp. 166-

175, pls. 2, 1894.
2 Op. cit., pp. 168-169.

292 CAPE COD GEOLOGY (

Number of times the wind was observed blowing from different points of the compass at
Provincetown in 1882, 1883 and 1884. Computed from three datly observations made at 7 am.,
3 p.m, and 11 p. m.

1882
Jan. Feb. Mar. Apr. May June July Aug. Sept. Oct. Nov. Dee.
N......... Tt 5 11 2 S 4 3 17 21 8
NE. 12 12 19 5) 6 12 30 12 15 5
oo 3 3 3 3 1 1 3 13 I 3
oh 09 6 8 —% 7 8-16 11 0 5 \
So 13 10 9 15 1S. 25 12 a 7 3
SW........ 9 18 27 31 36 29 9 16 6 14
ee 7 3 3 12 11 9 6 6 12 25
N Woe 29 24 12 18 1 5 11 10 24 25
1883
oe Ss 8 & fF | & 6H he CU \
NE |. 10 3 4 18 6 3 8 13 17 15 4 1 |
Bees 8 1 3 9 10 L 4 12 10 10 4 4 |
Sho. 9 11 4 7 15 9 4 4 7 8 2 5
Se 5 6 9 13 i 25 25 3 9 9 13 11
SW 8. 13 17 13 15 OF 20 22 ae 15 8 25 12 |
Wo... 15 26 13 6 5 13 12 13 11 6 12 14. }
N.W....... 22 14 33 14 10 4 11 9 a 9 19 23 |
|
1884
Nt 15 4 8
NE... 5 12 10
He 5 7 3
S.E........ 7 16 9 |
S.. 7 7 10
SW... 17 15 12
Woo... 1 7 12 |
NeW. 17 17 20

Average velocity, in miles per hour, of wind blowing from specified directions at Province-

town, Mass. |

1882

Jan. Feb. Mar. Apr. May June July Aug. Sept. Oct. Nov. Dec. \

Ne. 13 14 13 4 6 9 19 11 12 12 |
Nok... 15 15 13 13 7 4 12 8 13 6
Bo. 9 4 10 4 a 2 6 5 10 11
Sk... 14 11 8 8 9 6 12 10 10 16
So. 15 13 10 10 8 9 10 7 12 10
SW... .... 8 9 10 9 8 8 6 8 7 il
Wi 9 10 8 6 6 4 fe 6 10 0
N. W....... 14 11 9 10 7 8 10 12 12 13

a 9 I

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CAPE COD GEOLOGY 293

1883
Jan. Feb. Mar. Apr. May Jane July Aug. Sept. Oct. Nov. Dec.
Na. 2 14 12 14 10 10 8 9 6 8 14 13 14
N Eo it 8 10 10 8 7 7 10 6 9 9 10
De. 0 1 12 8 9 6 S 7 5 6 12 il
5 fo... 12 12 14 7. 9 10 4 8 6 10 23 16
Se 18 8 15 12 14 10 8 8 9 it 9 10
S Wo. 12 9 12 9 10 9 11 8 8 9 10 11
W.... 13 11 ll 5 6 6 4 6 6 9 9 ll
NOW....... 12 15 16 10 10 6 9 9 13 10 14 15
1884
No. 11 10 10
No Bee 10 11 11
Hoe 11 6 8
S. E.......- 20 12 15
So. 12 1 9
SW... 13 12 9
Wo, 11 12 10
NEW 12 15 13

The prevailing wind blows from the southwest, and as it is fairly dry it
probably does most of the cutting. The winds from the north, northeast, east,
southeast, and south are usually damp, and the moisture they form causes the
grains of sand to resist them so that only a strong wind from these quarters
can move the sand.

The sand and dust blown from the lag-gravel tracts of the glacial drift form
conspicuous deposits only near the edges of cliffs, where the work of the wind
is reénforced by the vortical movements there set up. High dunes are formed
in such positions, and nowhere more abundantly in this region than in the
stretch on the outside of Cape Cod between Highland Light and Nauset Light,
just where the cliffs are highest and steepest. A belt of such dunes and associated
tracts of lag-gravel border the top of the cliff in Wellfleet and Truro for a con-
siderable distance north and south of the Pamet River coast guard station at
elevations as high as 100 feet above sea level where the older glacial gravel
attains this level.

EROSION OF CLIFFS BY WINDS
The wind loosens and tears down the incoherent gravel and sand in the
coastal bluffs. On fair days when dry winds are blowing in a favorable direc-
tion, pebbles loosened by the blowing out of the sand at their bases roll down
to a sandy talus. Many of these pebbles take somewhat curved courses, rico-

294 CAPE COD GEOLOGY

chetting so as to leave a series of pits on the beach sand leading to the resting
place of the spent pebble. Hundreds of small streams of dry sand run out from
incoherent layers to add their contribution to the growing fan of talus that
rises between the beach and the top of the wasting cliff. When very high
winds are blowing inland, sand and dust are carried up the slope and on to the
surface back of the cliff. These zolian deposits at the tops of cliffs form mainly
in the prism of slack air motion that lies just back of the edge of the cliff, where
vortical movement is at times favorable to deposition. With the secular falling
away of the top of the cliff, the horizontally stratified dune sand loses its fore
part in the same process and becomes a distinct deposit, a few feet thick, at the
top of the cliff. Such a deposit is generally separated from the old glacial
surface by a layer of lag-gravel with or without sand-carved pebbles, by a layer
of soil, or, more rarely, by a thin bed of shell made by the aboriginal inhabitants.

DUNES FORMED FROM BEACHES

The dunes on the beaches differ from the deposits of wind-blown sand
because their component sand is sorted by waves. Fine dust, such as is
deposited by the wind that blows over the unmodified glacial deposits, is not
found in the beach dunes because the finer particles of the dunes have been
swept into the sea by the undertow. Furthermore, most of the small particles
of the softer minerals in the wind-laid deposits derived directly from the
glacial drift are ground down between the pebbles in the mill of the surf
and carried seaward with the clay. Along the beach, as in the bared tracts in
the interior, there are two contrasted land surfaces — the beach whence the sand
is blown (Plate 35, fig. 1) and the dune tract to which the sand is carried by
the wind. The beach is in a certain sense a lag-gravel tract in places where
scattered pebbles occur near headlands or in front of cliffs from which pebbles
are supplied to the beach, but owing to the regular return of the tide and the
greater power of the waves to shape and distribute pebbles and sand on the
beach, the work of the wind on the beach is limited to shifting the sand and,
under favorable circumstances, to producing a paradoxical movement of peb-
bles in a direction opposite to that of the wind. The sand-blasted glyptoliths
found in the glacial upland lag-gravel tracts are not found on the beach, where
the frequent inversion of pebbles and the change in the setting of the surface

give no time for sand blasting.
The principal dunes of the Cape Cod peninsula are formed by the inshore
wind on the great flying beaches at the north and south ends of the headland —

CAPE COD GEOLOGY 295

that is, at Provincetown and Monomoy, and along the Barnstable beach. Many
other small dunes are found on the shore of the open sea, along the sound on the
south, and along the shore of the bay, where the beaches furnish the sand. The
dunes of Provincetown are the best known in this part of the coast.

DUNES OF THE PROVINCELANDS

The dunes of the Provincelands are the highest along the southeastern coast
of New England. They form three distinct belts or tracts, each showing some
peculiarity of form and arrangement. The outermost belt skirts the beach from
Race Point to the place where the Provincetown sand hook is attached to the
glacial headland between High Head and the Highland Lighthouse. This
region is of recent origin. Here the beach and the dunes are partly separated
from the main tract by the slough known as Race Run, a slight depression
that runs nearly continuously through the district. The Peaked Hills, which
stand between 2 and 23 miles from Race Point Lighthouse, were the chief ac-
cumulations of wind-blown sand in this belt in 1835 (Plate 35, fig. 2). On
Graham’s chart, which is based on surveys made in 1833-35, the highest points in
these dunes are given as 44 and 46 feet. Farther east individual dunes reached
elevations of 49, 52.5 and 54 feet, the last one lying just east of the boundary
line between Provincetown and Truro. East of High Head, near the junction
of the sand hook with the mainland of the Cape, there is a group of old wooded
dunes, one of which is known as ‘‘the island.”” These dunes are probably a part
of an older deposit than that at Peaked Hills, having been formed when the
beach joined the mainland at a point east of its present position. These outer
dunes are now considerably reduced.

On the south side of the Race Run slough there is a second belt of more
stately dunes, which form a nearly continuous ridge that extends from the
northwest side of East Harbor, or Pilgrim Lake, to a point within about a mile
of the west coast. On Graham’s chart the highest dune indicated in Provincetown
had an elevation of 64 feet, and one in Truro, near the west end of Pilgrim
Lake had an elevation of 85 feet. Much of the surface of this dune, as shown
on the chart, was covered and anchored by transplanted beach grass. (Plate 36,
fig. 1). The survey of 1887 shows that this ridge of dunes had increased in
elevation near its east and west ends, two points near the west end and three
near the east end, rising above 80 feet.

According to a survey made by McClintock in 1892 the great ridge had risen

above the height shown by Graham’s survey, at one point attaining an elevation

296 CAPE COD GEOLOGY

of 100 feet, which appears to be the greatest height reached by any dune in
the district. By comparing the present position of the dune ridge with its
position as shown on Graham’s chart McClintock! concluded that the ridge
had steadily moved inward from the ocean toward the harbor at a rate of about
10 feet a year. ‘“The north wind,” he writes, ‘‘as a motive power annually
carries more than one million tons of sand a distance of half a mile from the
northern front to the rear of the ridge.” In the same report Mr. Heman S. Cook,
a native resident, testified that sand is blown in by the north wind but by no
other. The result of this general southerly movement of the dune is to bare
the surface that was once covered by the sand on the north side, revealing one
or two sets of buried soils containing stumps of trees, and to bury the living
forest on the south side. On its east side the ridge has thus partly merged into
the outlying dunes known as Mounts Ararat and Gilboa on Graham’s chart,
though these dunes still retain their general forms and altitudes. Intermediate
points, however, have been much altered by the blowing away of the sand,
which is driven southeastward by strong northwest dry winds. —

South of the main line of dunes north of Great Pond stands Negro Head,
the northeast arm of a horseshoe-shaped dune that is open to the northwest,
as shown on Graham’s map of 1835. At that time Negro Head had an elevation
of 88 feet. This dune has been much altered in form and somewhat reduced in
altitude. Farther east, a ridge of dunes that skirts the northern margin of ponds
or sloughs stretches toward Pilgrim Lake. This ridge includes Mounts Gilboa
and Ararat of Graham’s chart, which had elevations of 106 and 100 feet,
respectively, in 1835, whereas, according to the survey of 1887, Town Hill, the
site of the Pilgrim Monument, was the only dune on the hook having an elevation
of 100 feet.

The dunes between the ponds and Race Run form three well defined belts,
which taper out westward. One of these belts borders Race Run, and the Snake
Hills of Graham’s chart form the oldest one of three. The depressions between
these ridges are of the same origin as Race Run, the unfilled space behind succes-
sively offset bars growing westward parallel to the shore.

Between these outer dune ridges and the shore of the harbor the wind, in
forming and reforming dunes, has produced a topography that masks the
original alignment of the dunes along the earliest bars and beaches.

There are three of these groups of dunes, which present rather steep fronts
to the harbor. One group rises back of Clapp’s Pond and extends eastward

* McClintock, John N., Report of the Trustees of Public Reservations on the subject of the Province
Lands, Feb., 1893, Mass. House... No. 339, pp. 16-17, with accompanying map of the Province Lands.

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CAPE COD GEOLOGY 305

inbuilt deltas, bars, and shore phenomena at an old sea level in these basins lends
no support to the supposition that they have come up from the sea since the
present surface was formed. Careful scrutiny of the surface of Cape Cod and
the country south of Boston by several competent geologists has failed to dis-
close beaches that lie beyond the reach of storm waters, or other evidence of
marine action that indicates changes in the level of the sea since the end of
the glacial period, or during or after the retreat of the last ice sheet.!

Before the stratified glacial deposits of this district were properly interpreted
they were called ‘‘modified drift,’ a term which implied that they had been
modified by some agency other than that which produced them. The modification
was by some supposed to be due to the action of the sea. Many geologists, in-
cluding Shaler, held that the outwash plains of gravel and sand on Cape Cod
and the neighboring islands had been laid down beneath tidal waters.

1 Woodworth, J. B., Some glacial wash plains of southern New England, Bull. Essex. Inst., Salem,
Mass., 29, 1897 (actually issued 1899), pp. 71-119. At p. 105 some evidence against deposition of sand
plains at sea level is presented. The accompanying bibliography includes the titles of several papers
on changes in sea level in Massachusetts and Rhode Island.

308 CAPE COD GEOLOGY

age and to have been formed by erosion and somewhat modified later by the
action of ice. Deposition of morainal drift, however, is more evident than glacial
scouring, though here and there the effects of the action of running water may be
seen in winding creases that lead away from old ice fronts marked by morainal
ridges.

The chain of islands has a strong morainal cast and conforms in trend with
the lobate margin of a protrusion of the ice sheet in the Buzzards Bay depression
and in the main owes its origin to the crowding up of the underlying coastal plain
deposits and older Pleistocene gravel, sand, and clay, yet the stage of Pleistocene
glaciation at which the deformation was accomplished is not clearly indicated.
Here, probably, as on Marthas Vineyard, several successive ice thrusts were
effective in the shaping of the islands.

A small exposure of Cretaceous and Tertiary beds lies at the east end of
the group. These beds are tilted and show a strong deformation. Such beds
have not been recognized as the southwest end of the group, where a well boring
goes over 200 feet below sea level.

The absence of outwash plains of gravel and sand on the south side of the
islands is evidently not to be explained by supposing their erosion and removal
by the sea. It may mean that the stream flow was not sufficiently strong to carry
sand and gravel to a great distance from the ice front. Soundings in Vineyard
Sound and in the adjacent waters between Gay Head and Block Island do not

show the presence of such deposits.

NAUSHON
SALIENT FEATURES

Naushon, the largest island of the Elizabeth group, is 82 miles long and
between 1 mile and 14 miles wide. It extends southwestward and is separated
from Pasque Island, on the southwest, by Robinsons Hole, a narrow tidal pas-
sage having a minimum depth of 13 feet at mean low tide, and from several
small islets — Uncatena, Nonamesset, Rams Head Island, East Buck Island,
Monohansett Island, and three islets unnamed on the Coast Survey chart — by
shallow tidal ways due to depressions in the moraine. Woods Hole, a tidal
passage navigable for small steamers, separates Naushon and its dependent isles
from the heel of Cape Cod at the port of Woods Hole.

The topography of Naushon and the adjacent islands is morainal. The higher
hills in the interior of the Naushon rise to elevations ranging from 100 to 168

a SER ace

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CAPE COD GEOLOGY 309

feet. A broad depression just west of the middle of the island gives rise to coves
on the opposite shore of the island. Tarpaulin Cove, on the southeast side, is
a well known anchorage in northeast gales for sailing vessels passing through
Vineyard Sound. Naushon remains largely covered by a native forest, which
corresponds closely with that growing on these islands when they were first
explored by white men. The soil is prevailingly sandy and the surface is encum-
bered with glacial boulders, some of them large and assembled in picturesque
groups.

Hollick! has given a sketch of the glacial deposits of Naushon. He found
on the south shore of Nonamesset Island, near its east end, a bed of Cretaceous
lignitic and noduliferous parti-colored clay, and he gives a hypothetical cross
section of Naushon showing overthrust Cretaceous beds surmounted by bouldery
moraine.

The forest comes down to the wind-swept shores in a bushy cover that
dwindles to a low serub growth of plants and that protects the trees from the
harsh winds that strike the island. Plate 37, fig. 2, gives a view of the open
forest, free from undergrowth, as seen from a point on the south shore east
of Tarpaulin Cove. In this primeval forest deer keep down the undergrowth.
The flora appears to have come from the mainland and not from the islands
on the south, for Vineyard Sound has doubtless been an effective barrier to
the migration of plants between Marthas Vineyard and the Elizabeth Islands.

CRETACEOUS DEPOSITS

The geology of Naushon was briefly described by Shaler,” who recog-
nized, beneath the surface moraine, a thick mass of fine sand, to which he had
already given the name ‘‘Naushon series,’ comparing it with the beds now
referred to the older Pleistocene on Marthas Vineyard.

Cretaceous beds are exposed on the south side of Nonamesset Island at the
base of a small hillock that forms the eastern headland of Lakey’s Bay. The
surface here carries large boulders, one of gneiss having a length of 18 feet.
Farther east, along the bluff facing Vineyard Sound, gravel that appears to lie
in beds that dip gently northwest is seen under a gray till having a compact
clayey matrix. A bed near by contains light, fine-grained sand. A section farther
east, about 20 feet high, reveals, beneath a top of gravelly, clayey till, a bed

1 Hollick, Arthur, A reconnaissance of the Elizabeth Islands, Annals N. Y. Acad. Sci., 18, pp. 387-
418, pls. viii-xv, 1901.

2 Shaler, N. S., Geology of the Cape Cod district, U. 5. Geological Survey Highteenth Ann. Rept.,
1896-97, Part II, p. 543, 1898.

310 CAPE COD GEOLOGY

of gravel underlain by a fine yellow sand. A few feet farther east a lignitic
Cretaceous bed rises about 6 feet above the limit of marine action. This bed
discloses the following section, the layers being named from above downward:

Cretaceous beds on Nonamesset

Black lignitic clay containing some lignite.

Pinkish gray clay containing a sandy iron-stained layer that furnishes the ferruginous
concretions seen on the beach.

Quartz gravel.

Light yellow sand.

Lignite underlain by clay imperfectly exposed.

MiocENE GREENSAND
About two rods east of this bed is a Pleistocene section, which is underlain
by a layer of yellowish greensand, a mixture of quartz grains fairly well rounded,
and a few black, rounded nodules such as are found in the Miocene greensand
bed on Gay Head, probably the altered casts of foraminifers. Still farther east
the nodule-bearing Cretaceous clays reappear at the edge of the beach.

PLEISTOCENE SECTIONS
Between the points just mentioned the Pleistocene section exhibits various

features in different thin deposits.

Pleistocene section on Nonamesset Island Foor
Bouldety suriace dmiit, 1-3
UWneomformity. -.2......4......4..25.... 22... 0
Hine lightsond. 3. 4
Zone of angular blocks of granite, etc,................-.. 1-4
Till @) A gravelly unstratified clay...................... 4

Gray, streaked sand, which grades downward into ferruginous

These glacial deposits resemble in character and succession the older Pleis-
tocene beds just above the Cretaceous and Tertiary beds in the Gay Head cliffs.
They include deposits formed at stages as late as the second ice advance here
recognized. The beds are tilted, and the surficial bouldery drift of the Wis-
consin stage is only a veneer over a mass of older Pleistocene deposits.

Most of the boulders on Nonamesset are of granite-gneiss, some of which

contain traces of banded schist.
Several years ago boulders were struck at a depth of 80 feet in wells bored

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CAPE COD GEOLOGY dll

at the east end of Naushon, near the dwellings of the late Commodore Forbes.
These boulders may represent the Montauk till, or one of the lower boulder
beds encountered on Marthas Vineyard. The entire assemblage of gravel and
coarse and fine sand that appear above sea level in small exposures in the central
and western parts of the island closely resembles the Manhasset formation and
the underlying Jacob sand. On the east side of Ram’s Head, the west chop of
Kettle Cove, a bed of fine sand that dips westward is exposed. Similar beds of
sand may be seen in broad, wind-bared exposures in the interior of the island,
in the ‘‘sheep pasture” northeast of Tarpaulin Cove, and in the depression

between Tarpaulin and Kettle coves, on the northwest side of the island.

LATE WISCONSIN OR FALMOUTH MORAINE
FRONTAL MORAINE

The frontal moraine on the Elizabeth Islands is an extension of the Fal-
mouth moraine in the frontal outcurved lobate margin of the ice lobe that
deployed over Buzzards Bay. As seen in the few exposures along the shore and
at places in the interior of Naushon the material of this moraine is very thin.
In these exposures beds of till 8 or 4 feet thick overlie beds of fine sand. At
many places in the interior of the island the later Wisconsin drift appears as
isolated boulders resting in the sand or as morainal belts of boulders that
dominate the surface.

The large ridges in the relief of Naushon, which run nearly parallel to its
long axis, have a decidedly morainal aspect, but the topography as a whole
suggests that they originated as much by the deformation of the older Pleistocene
beds as by direct erosion or by being mantled by new deposits during the last
ice invasion. Here and there downward slopes that form vales which widen
toward the sea suggest the action of running water, such as is evident on Marthas
Vineyard and other islands of the outer group, during the interglacial stage
preceding the Wisconsin glacial advance. The most conclusive evidence that
an ice front extended along the axis of Naushon is seen in the numerous small
ridges of boulders and bouldery drift at places on the island where the removal
of the forest has exposed the surface to view. In the ‘‘sheep pasture’’ on the
hills about a mile or more northeast of Tarpaulin Cove, where the Wisconsin
drift forms a relatively thin veneer over Pleistocene yellowish sand. the moraine
rises into low, somewhat inosculating bouldery ridges containing scattered large
boulders. (See Plate 38, fig. 1.)

The island appears to be a broad, low ridge, which rises rather steeply

312 CAPE COD GEOLOGY

from the sea, especially on its southeast side, and then more gently toward its
middle rolling hills. The axial ridges become lower toward the southwest in the
direction of their length, and are discontinuous, but their massiveness is dis-
proportionate to the details, such as the bouldery ridges, and the kettle holes
which here and there interrupt the surface, and which were formed by the

action of ice.
KETTLE HOLES

The kettle holes on Naushon are typical morainal features and they were
probably produced by the melting of buried blocks of ice or of outlying parts
of the ice front that were encumbered by drift. They have been mapped in
detail by Mr. B. F. Koons.

Most of the kettle holes are in the morainal upland and show no relation
to the ice front and no alignment of their longer axes to the direction of the
motion of the ice. In the middle of Naushon there is a crowded group on the
northeast side of the large (‘‘Grinnell”) swamp, which is an extension of the
depression forming Tarpaulin Cove. Many of the kettle holes are occupied
by small pools or swamps. Mary’s Lake, at the east end of the island, is a deep-
sided kettle hole, from which an ice block has melted out. The depth of some
of these ice-block holes would seem to indicate the deposition around their
sides of the sand and gravel that underlie the till. In a frontal moraine that is
subject to the pressure of ice, blocks of ice may behave very much as large
boulders and may become so much involved in movements of the ice sheet and
the underlying terrane as to assume forced relations with older displaceable
material. Ice blocks evidently lay out in old channels or shallow valleys on the
south side of Cape Cod and were surrounded and probably covered by deposits.
The glacial trough on Naushon that extends from French Watering Place inland
to the west side of Tarpaulin Cove is the site of a remnant of ice, signs of which
are shown in the swamp and central lakelet near its east end. On Cape Cod
the blocks of ice that gave rise to kettle holes in the outwash plain and in the
moraine, as at Brewster, were remnants of the sheet that advanced to the
outer line of islands. The same conditions doubtless prevailed on Naushon and
the Gosnold islands generally, so that the ice blocks were worked over by the
front of the ice when it lay along the crests of these islands.

‘ Koons, B. F., Upon the kettle holes near Woods Hole, Mass., Am. Jour. Sei., 3d ser., 27, pp. 26-
264, 1884. Also additional notes on the kettle holes of the Woods Hole region, Mass., Am. Jour. Sci.,
3d series, 29, pp. 480-486, 1885.

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CAPE COD GEOLOGY 313

GLACIAL ERRATICS ON NAUSHON

Some of the numerous glacial boulders on Naushon are grouped in huddles
or lines. In places along the shore where the finer drift has been washed away
boulders have been heaped up in irregular piles by the waves, as for example,
about a mile northeast of Tarpaulin Cove (Plate 38, fig. 2). Large flattish
boulders that are piled up along the coast have a dip seaward that shows the
action of storm waves. Boulders 6 feet long have been thus thrown up by the
storm waves of Vineyard Sound. Boulders of conglomerate derived from Car-
boniferous rocks around Middleboro are rare on the island. Most of the
boulders appear to have been brought from the pre-Carboniferous gneiss, schist,
and diorite about New Bedford and beneath the waters of Buzzards Bay.

Among the rocks seen were a coarse-grained schistose diorite; an aplite dike
rock in contact with blackish schistose hornblende granitite; a black actinolite
rock; a gray granite-gneiss carrying large inclusions of a subrounded fine-grained
dark rock, possibly diorite; a large boulder of coarse-grained pepper-and-salt
diorite containing veins of epidote and coarse dioritic segregations; a fine-grained
diorite containing intrusions of granitic rock; a diorite breccia enclosed in
granite like that at Little Nahant; a mass of fine-grained aplite (?) enclosing
angular blocks of a coarse, gray hornblendic granitite; a brownish, massive
semi-schistose rock containing aggregates of hornblende in drawn-out bunches,
and a gneiss containing well defined crystals of feldspar that weather out and
leave pits 13 inches across. One hornblende-granitite block exhibited a dike of
fine-grained basic rock, which showed a gneissic structure formed by shearing
along a fault zone. One cobble of diabase was seen.

A comparison of these rocks with those found north of Boston, near
Worcester, and around the head of Narragansett Bay indicates that the area
around New Bedford and probably the islands are underlain by a group of
chiefly igneous rocks that were intruded in probably the following order:

. Dioritic schist (possibly a metamorphosed phase of No. 3).

phe

Granite-gneiss carrying shreds and blocks of No. 1.
Diorite of second (?) intrusion.
Hornblendic granitite with aplitic and pegmatitic dikelets, some enclosing

7 sf

brecciated facies of the mother rock.
5. Aplite dikes of No. 4, contemporaneous or later.
The schistose rocks in the area around New Bedford, which were separated
from the Carboniferous rocks and the granites by Edward Hitchcock in 1841

314 CAPE COD GEOLOGY

and by me in 1899! have not been identified lithologically in the field, and
their lithological character is not shown on the geological map of the State.
The complex of rocks described above corresponds apparently with the sup-
posed Devonian igneous rocks of Emerson.” The hornblendic granitite is probably
the same as his Dedham granodiorite and Milford granite. The granite-gneiss
would thus become the correlative of the Northbridge granite-gneiss of Emerson,
which is referred to the Archean and lies below an Algonkian (?) quartzite.
The aplite becomes the associate of the Milford granite, and the fine-grained
dioritic rock, although it is subject to further examination under the microscope,
would appear to be the equivalent to the Ironstone quartz diorite of Emerson.
The area about New Bedford is shown on Emerson’s map as an extension of
the Dedham granodiorite, whose various phases, which grade toward aplite on
one hand and diorite on the other, include local sheared strips of the rock form-
ing ‘‘gneiss.”’

Many large boulders may be seen in the interior of Naushon. Koons
measured two erratics, each 27 feet long. A large, roundish boulder about 30
feet long, surrounded by small boulders, lies on the crest of the island, in the
middle one of three strong ridges, northeast of Tarpaulin Cove.

Many boulders lie along the shore of Kettle Cove. A large boulder of
gneiss on the beach on the east side of Ram’s Head, at the west point of the
Cove, bears on its western sloping surface glacial grooves running N. 20° W. by
the compass, or N. 33° W. by true bearing. This boulder may therefore bear
the marks of the ice that ran over it during the last stages of the ice on the
island. On Ram’s Head also there is a large boulder that has split along a
joint plane, so that its upper half has slid down to form a small rock shelter,
which is invaded by the sea at high tide.

About half a mile west of French Watering Place and a third of a mile inland
from the shore there are two large boulders about 30 feet long, one of which
is broken into three blocks.

A large boulder on the beach at the base of the 80-foot hill about a quarter
of a mile northeast of the east chop of Tarpaulin Cove stands out several yards
from the present bluff. It is inclined landward as if it had slid down the bluff
from the surface when the coast stood farther out. This boulder is rather too
large to have been thrown back by sea waves.

Somewhat east of the central point of Nonamesset there is a boulder 24 feet

1U. 8. Geological Survey, Monograph XX XIII.
* Emerson, B. K., Geology of Massachusetts and Rhode Island, U.S. Geol. Survey, Bull, 597, pp.
164-185, 1917.

}

CAPE COD GEOLOGY 315

long, which stands at least 9 feet above the surface of the bouldery drift. Koons
noted another larger boulder near by. These large boulders appear to be a
part of the Wisconsin drift.
AGATE PEBBLES

On the south coast of Naushon, west of Tarpaulin Cove, pebbles of
brown and white banded agate are rather common on the beach. These
pebbles have evidently been washed out of the morainal cliffs along the
coast. Similar pebbles are found on the beach on Marthas Vineyard, but
Tarpaulin Cove is probably about the eastern limit of their distribution in the
Elizabeth Islands. An occasional pebble of agate on Naushon encloses fragments
of a reddish shaly wall rock resembling certain phases of the Carboniferous
Wamsutta formation seen about Attleboro, but these agate pebbles appear
to have been derived from some locality south or east of Attleboro. Boulders
of the peculiar ilmenitic iron-ore of Cumberland Hill, in Rhode Island, some
5 miles northwest of North Attleboro, have been carried to Gay Head by glacial
action in at least one of the older Pleistocene stages of glacial invasion. The
general direction followed by these pebbles is 8. 40° E., and Tarpaulin Cove,
on Naushon lies in the same direction from Diamond Hill, northwest of North
Attleboro. This hill includes a large mass of quartz that appears to contain
veins of similar agate. Other smaller veins are found near by in the red Carbon-
iferous rocks. Along with the agate pebbles on Naushon there are numerous
pebbles of white quartz that,contain small cavities beset with minute quartz
crystals. Possibly the source of the quartz and agate may prove to lie near
Diamond Hill. Similar agates have been found on the beaches on No Mans
Land and Block Island.

PASQUE ISLAND

Pasque Island lies west of Naushon and is separated from it by a narrow
passage, Robinson’s Hole, which at its narrowest point is little more than 500
feet wide. The island is about a mile wide from north to south and about 13
miles long from east to west. This measurement does not include the barrier
beaches and a small swamp and land-tied islands at the southeast end of the
island. Several drift-covered knolls in the eastern part of the island rise to a
height of about 100 feet and a middle ridge of the same height extends westward
toward a point exceeding a height of 120. feet, from which it is separated on the
north by a steep-sided glacial depression. Between the medial ridge and a lower
one on the north coast there is a small kettle hole containing a lakelet. Similar

316 CAPE COD GEOLOGY

lakelets are seen at the east and west ends of the island, either in the glacial
drift or behind barrier beaches thrown up by the waves.

The island is covered with bouldery drift of the Wisconsin stage, in which
there are numerous kettle holes, 30 to 50 feet in diameter, which contain lakelets
or swamps. The north coast is covered with drift. On the steeper and more
exposed south coast, Mr. Gilbert Hart, my assistant, observed a cut in the
bank showing 4 to 8 feet of till covered by a bed of sand 4 feet thick, under
which 3 feet of clay was exposed down to the base of the bluff.

At the east end of the island, between the two small ponds shown on the
map, clay has been dug. The till at this point is little more than a coating of
scattered boulders embedded in a sandy soil or subsoil one or two feet thick.
Well defined waterlaid sand, 3 to 4 feet thick, underlies this till and is underlain
by the clay. This clay is probably underlain by pre-Wisconsin drift, as is shown
more clearly on Nashawena.

A small islet of glacial drift off the southeast end of the island supports
bars that tie it to the main island and enclose a small marsh. A barrier beach
thrown up on the north coast encloses another small marsh. The beaches are

largely bouldery.

NASHAWENA ISLAND

The island of Nashawena, the second largest in the group, is about 22 miles
long and from three-fourths of a mile to 14 miles wide. Its glacial features —
its ridges of older Pleistocene sand, its long hollows, and its kettle holes — are
essentially the same as those of Naushon. Most of the broader ridges are in the
southwestern part of the island, where at three places they rise to heights
exceeding 120 feet. A deep depression lies in the western part of the island. Here
the steep slopes on the east, south and west sides of a small glacial lakelet show
that it was formed by an ice block or a tongue of the ice sheet. Two depressions
on the south side, which extend southeastward down to sea level appear to
mark the path of a glacial stream.

The north coast of the island is covered with till or, where the sea has formed
cliffs, with a talus of bouldery drift. At several places on the south coast, where
steep bluffs show that the sea has cut back the land, beds of clay that rise
several feet above sea level may be seen. Most of the clay on the weathered
surface is whitish, but that within the bed is blue or brown where it is oxidized,
resembling the clay exposed on Cuttyhunk. The bed appears to be a phase of
the Gardiners clay, which is much better exposed on Marthas Vineyard, Block

CAPE COD GEOLOGY 317

Island, and Long Island. Most of the beds are horizontal, and those along
the south coast are covered by Wisconsin till, which at some places is 6 feet thick.

After a heavy rain in September, 1916, which exposed a section in a gully
near the east end of the bluff of the 100-foot hill at the west side of the channel
that extends southeastward from the ice-block hole already described, my

assistant, Mr. Gilbert Hart, measured the following section:

Section on the south coast of Nashawena near the middle of the island
Feet Inches

Gane ond Clay = 2 6
Glacial sand containing a layer of pebbles........... 1

Coarse sand and gravel............... ss.
Ferruginous blue clay containing angular pebbles. .... 3

- Blue clay containing iron concretions............-.. 5:
Einesand,. ee. 4

me feet
SloowomHrounwoand

21

The upper clay bed, which carries angular pebbles, appears to be till laid
down in the presence of ice, possibly floating ice, and is like a similar bed of
pebbly clay in a section of the older Pleistocene deposits on Gay Head. The
ferruginuous bands and concretions in the clay are like those in the clay that
lies below the Gardiners clay. Exposures of the similar beds of clay were seen
at a few places on the northeast coast of the island.

At the east end of the island, which faces Quick’s Hole, there are two , onds
of brackish water, which are partly enclosed by bars that have tied a small
islet of drift to the main island.

On the north side of the island a small ridge of bouldery drift projects
westward into the sea, forming a small harbor. Two small islets of drift off the
point at the west side of the ice-block hole already described appear to be a
continuation of this ridge. Between these islets and the peninsula the entrance
to the small harbor is obstructed by large boulders, and other boulders stand
conspicuously around the northwestern point of the island and about the north-
east point, at the entrance to Quick’s Hole.

A small marsh surrounds the ponds at the east end of the island, and the

lakelet in the ice-block hole near the middle has been encroached upon by a

318 CAPE COD GEOLOGY

swamp. Other small swamps lie in the bottoms of kettle holes or in hollows
behind the barrier beaches.

A small sand spit has been formed by the currents at the west end of the
island, where Canapitsett channel separates the island from the appendages
of Cuttyhunk. The shore seems to be retreating very slowly as compared
with that of the islands which face the open sea. Talus conceals most of the
cliffs, and the sea probably does not accomplish much erosion except during
unusually heavy winter storms.

CUTTYHUNK ISLAND

Cuttyhunk is the outermost of the Elizabeth Islands. John Brereton
described it in a paper published in 1602. He writes, ‘‘it containeth many pieces
of necks of land, which differ nothing from several islands, saving that certain
banks of small breadth do like bridges join them to this island.’’ Brereton’s
statement that the island was then sixteen miles in circumference could be
true only if Nashawena were included in his measurement. Canapitsit channel
may then have been closed by a bar. On Southack’s chart drawn somewhat
more than a century later, Cuttyhunk and Nashawena are represented by a
single island, but this chart is not reliable evidence concerning such details

as the opening and closing of bars across inlets. Brereton described the lake

é Pi

at the west end of the island as ‘‘almost three miles in compass,’”’ a measure-
ment that is too large for the present body of water called West End Pond,
but the lake may have extended considerably farther north in 1602, the barrier
beach on that side having since been driven in by erosion.

A small island in West End Pond, named Gosnold’s Island on the charts,
was the site of Captain Gosnold’s house, erected in 1602. Gosnold arrived from
England in the Concord about the middle of May, 1602, and abandoned his
attempt to found a colony after staying a month on Cuttyhunk, which he
called Elizabeth Island, and sailed for England on June 1711

The island, which is now deforested, was in Gosnold’s time covered, ap-
parently in its central part, with an open growth of trees, which, according to
Brereton, included oak, cedar, beach, elm, holly, and walnut in abundance, and
some sassafras. The low outer parts of the island appear to have been grass

*See Winsor, Justin, Narrative and critical history of America, 3, pp. 172-178, 187, 1884. John Brere-
ton’s letter to Sir Walter Raleigh giving an account of his voyage under Gosnold, entitled “(A Briefe
and true Relation of the Discoverie of the North Part of Virginia,” etc. (London, 1602), was reprinted
in the Massachusetts Historical Collections, 3d series, 3, pp. 85-93; and again (with some omissions)
by Thomas Wentworth Higginson in his ‘Young Folks book of American explorers,” Book X, pp. 201-
213, New York, 1894.

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a

CAPE COD GEOLOGY | 319

land, as they are now. Here, as on Block Island, where the original forest was
cut away by white men for fuel or for timber, trees cannot survive except in
the lee of some protective barrier of lower, hardier bushes, or of hills.

Cuttyhunk now consists of a central round hill of glacial drift, which rises
136 feet above the sea in its highest morainic knobs and ridges. These are
flanked on the southwest by a lower mass of glacial drift, which has a different
contour and has been much cut away by the sea on the south and west. An
extension of this drift forms a barrier beach enclosing West End Pond, near
the western shore of which lies the small islet on which Captain Gosnold at-
tempted to form a settlement. Another low glacial deposit that lies northeast
of the central mass of the island would form a separate island were it not for
the bar that ties it to the main mass. Hooked spits that stretch out from the
shore partly enclose a salt lagoon known as Cuttyhunk Pond. The bar or
barrier beach on the south side of this pond extends from Cuttyhunk toward
Nashawena and ends in a small mass of drift that borders Canapitsit channel.

The central round morainal hill of the island bears ridges that trend in
the general direction of the group of islands and that consequently lie nearly
parallel to the old ice fronts along which they were formed, either by pressure
and displacement of the underlying beds or by the formation of frontal deposits.
Many of the depressions here culminate in kettle holes, most of which contain
small swamps.

The morainal ridges in the lower drift surface, which lies south and west
of the main mass of the island and extends to its west end, rise to a height of
60 feet. These ridges front the south coast and show by their general rise in
that direction that the land once extended a quarter of a mile seaward from
the present cliffs. The detached deposit of drift in the northeastern part of
the island rises to a height of about 50 feet and shows gently swelling glacial
contours. In Gosnold’s time this land appears to have been connected with
the western part of the island by a bar, as it now is, and to have been the place
referred to by Brereton as the bivouac of the savages described by him as
“every night retiring themselves to the furthermost part of our island, two or

three miles from our fort.”

GEOLOGICAL STRUCTURE
The geological structure of Cuttyhunk is like that of the islands immedi-
ately northeast of it. Beneath the surficial morainal deposits of Wisconsin drift,
which in places reach a thickness of 15 feet, and which bear scattered blocks of

320 CAPE COD GEOLOGY

granite and gneiss, there is exposed above sea level along the cliffs a thin bed
of sand overlying a blue clay. The clay at the surface is in places whitish, but
that within the bed is ferruginous red. This clay is probably the equivalent of
the Gardiners clay.

A well that was driven to a depth of 230 feet on the island passed through
sand and blue clay. The water in this well rises to a height of 190 feet above
the bottom of the boring.

Freshwater swamps occupy several small tracts on the island, the water
being held up by the underlying clay. Saltwater marshes have been formed in
the lee of the barrier beaches and around the shores of the salt ponds. The
Coast Survey chart of 1853 shows West End Pond extending into confluence
with a small pond that was cut off from it by a marsh as shown by the survey
of 1889.

The southwest coast of Cuttyhunk is exposed to heavier attacks by the
sea than any other part of the coast of the Elizabeth Islands and has therefore
retreated rather rapidly since the first survey was made. A comparison of the
chart of 1853 with that of 1889 appears to show that the south coast has re-
treated more than 130 feet, or at a rate of more than 3 feet a year. A few centuries
ago the land must have extended farther south and west.

SOW AND PIGS REEF

A boulder-covered reef extends westward from the westernmost part of
Cuttyhunk to a group of large boulders known as the Sow and Pigs, a map of
which was made by Lieut. M. Woodhull, U. 8. N., in 1853, which accompanies
his report on the Sow and Pigs rocks.

Lieutenant Woodhull states the Sow and Pigs rest on ‘‘a bed of rocks and
stones from the size of those generally used for paving, to boulders two or three

feet in diameter.’”’? He says that the cluster which makes up the ‘‘

pigs” forms
almost a circle, about 50 feet in diameter, within which there is one to two feet
of water at low tide. No. 1, or Saddle Rock, measured 14 feet in length, 7 in
width, and 9 in height. Sow rock stands on the south slope of the reef in about

two fathoms of water at low tide. The base of this rock, according to Lieutenant

Woodhull, measured 15 by 20 feet, but the apex was visible only at low water.
The Sow and Pigs reef is no doubt the site of a former islet, and the Middle

1 Woodhull, M., Upon the survey of the “Sow and Pigs” rocks, off Cuttyhunk, Massachusetts, with
reference to the location of a lighthouse, Rept. Supt. Coast Survey for 1853, p. 172, Plate No. 5, Sketch
A, No. 5. :

CAPE COD GEOLOGY 321

Ledge and Whale Rock, which lie just off the west end of Cuttyhunk, are similar
remnants of lost land that extended westward along the line of the Falmouth
moraine. The name ‘‘Sow and Pigs” is on Southack’s chart of the coast, and
is undoubtedly a seventeenth century expression, like ‘‘Bishop and Clarks,”
‘‘Rose and Crown,” shoals that lie farther east, designating a large boulder
and its surrounding smaller associates.

PENIKESE AND WOEPECKET ISLES

Three small islands, Penikese and Gull Island, which lie about two miles
north of Cuttyhunk Island, and Woepecket Island, which lies about three-quarters
of a mile north of the eastern part of Naushon Island, form an inner line of
morainal heaps on the south side of Buzzards Bay.

PENIKESE ISLAND

Penikese Island consists of a large and small islet of glacial till which are
connected by a barrier beach. The larger island is about three-fourths of a mile
long and somewhat over a quarter of a mile wide. Two drift hills in its central
part rise to heights exceeding 80 feet. The eastern isle is not more than a quarter
of a mile long from northeast to southwest and rises to an elevation of more
than 60 feet. Its wave-washed shores are strewn with glacial boulders derived
from till. The underlying deposits are presumed to be sand and clay similar
to those under Cuttyhunk Island. According to Mr. Gilbert Hart, my assistant,

who visited the island in September, 1916, there were then seven bored or driven
wells on the island, one of which is 120 feet deep.
On the northeastern coast of the main island Mr. Hart observed a bed of

till 7 feet thick, which lay upon sand. Boulders are abundant on the surface
of the island. Most of them are granitic, but there are some boulders of dark
basic rock, probably a dike rock, as well as some of conglomerate derived from
the Carboniferous basin about Middleborough.

GuLL ISLAND

Gull Island, which lies about three quarters of a mile east of the south point
of Penikese Island, is a wave-washed shoal from which lines of boulders stretch
toward Penikese. Mr. Hart noted a boulder on Gull Island 20 feet long which
rose 6 feet above mean tide level. About a quarter of a mile west by south of
Gull Island is a small shoal, which is dry at low water. Penikese and the adjacent

322 CAPE COD GEOLOGY

isles probably once formed the summits of till-covered land having a morainal
topography and representing frontal deposits laid down by the Wisconsin ice
sheet on its retreat from the Falmouth moraine.

THe WOoEPECKET ISLES

The Woepecket Isles! form a line of small islets and shoals that lie off the
‘northeast side of the island of Naushon. The largest islet is at the southwest
end of the group. Woepecket (also spelt Weepecket) island, as well as the two
much smaller islets north of it, are rapidly being cut away by the waves, and their
low, flattish drift tops, which are surrounded by low cliffs at the back of boulder-
strewn beaches, give to the islands the appearance of great hats floating in the

sea.

WoEPECKET Rock

Woepecket Rock is on a shoal at the east end of the group. The coast charts
show a bank, with 26 and 30 feet of water, separated from the shoal on the
west by depths of 47 feet at mean low water. What may be traces of a line of
retreatal moraine, now shoals, dot the borders of the Bay off Quamquisset
Harbor, off Gunning Point, at Gifford’s Ledge, and thence northward to South-
west Ledge, off Scraggy Neck, near Cataumet. Soundings fail to reveal evidence
of a submarine ridge west of the Woepecket Isles toward Penikese, but opposite
the north entrance to Quicks Hole three small shoals, the largest of which is
marked by ‘‘Lone Rock,” may indicate the extension of the moraine.

West of Penikese Island a line of shoals on which the water ranges in depth
from 23 to 29 feet extends southeastward over a bottom whose soundings run
from 32 to 135 feet. This line of shoals would join the northwest corner of
Nashawena if it were extended so far. It lies about two miles south of Penikese
in the meridian of that island, and it is therefore probably earlier than any re-
treatal moraine on that island. Numerous retreatal morainal ridges no doubt

occur in this area.

RIBBON REEF
Ribbon Reef and another small shoal that lies west by north of the north-
west corner of Cuttyhunk suggest other morainal lines, which cannot, however,

be traced over the sea floor.

1See Chart No. 249, Buzzards Bay, U. S. Coast and Geodetic Survey, May, 1913.

ns = a =— <n SS = a

EXPLANATION OF THE PLATES

PLATE 1

PLATE 1

Geologic map of Cap Cod, western half

Base from United States Geological Survey topographic maps of Plymouth, Barnstable, and
Falmouth quadrangles. Geology by J. B. Woodworth, United States Geological Survey, Gilbert Hart,
field assistant, 1916. Drafting and editing supervised by the United States Geological Survey.

&
70°45' MEM. MUS. COMP, ZOOL. ; | GEOLOGY CAPE COD. PLATE 1
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Base che Ao ge niniton Soggpesd topographic Geology by J. B. Woodworth,
maps of Plymouth, Barnstable, an : U. S. Geologica! S ;
Eideheailc crcacieaidi. ribprirhad frees anita GEOLOGIC MAP OF CAPE COD PENINSULA, MASS. (WEST HALF) Gilbert HarkeMcld assistant, 1916
editions without revision : . 3200 ,
Se
| ‘4 a ° 1 — 2 3 4 Miles
\ 1 & 3 ° 2 2 3 & 5 Kilometers

Contour interval 20 feet.
Dice#z, rs ea la Z

A

Wisconsin stage

%

(Sandy, probably clay and sand and gravel

EXPLANATION

See 7 \

a oe ae

Swamps (fresh)
(Probably contain peat)

Marshes (salt)
(Probably contain peat)

Beach and dune sand and gravel

7: oF

Ground moraine of Buzzards Bay lobe

QUATERNARY

Drumlin
(Elliptical hill of glacial drift)

Falmouth moraine
(Thin bouldery glacial drift overlying outwash
sand and eueat od: older "Vaciniocsne
deposits)

Glacial till, boulders, sand and gravel of
Nan

tucket substage

Pre-Wisconsin Pleistocene blue clay, prob-

ably Montauk till member * 4 an-
asset formation(?)or Gardiners clay(?)
and Miocene greensand

{Only outcrop known)

TERTIARY AND

QUATERNARY

PLATE 2

PLATE 2

Geologic map of Cape Cod, eastern half
Base fro

om U.S. Geological Survey topographic maps of Provincetown, Wellfleet, Yarmouth and
Chatham quadrangles. Geology by J. B. Woodworth, United States Geological Susvey, 1916. Drafting
and editing supervised by the United States Geological Survey.

70°

42°05

42°00"

4°35’

MEM. MUS. COMP, ZOOL.

15°

eer: , ai is os ee a or Sedocat a,

ay Se eee ey Pe ar ET

a

. os ry -

a se a
—=— er * ss aE

GEOLOGY CAPE COD. PLATE 2

5’ 70° 00 69° 55

\\\
Ass
\\ Wi

XX

SS

Pleistocene

Recent

4

Wisconsin stage

a

Pre- Wisconsin

Sand and gravel of Chatham plain, partly

EXPLANATION

Swamps (fresh)
(Probably contain peat)

’

Marshes (salt)
(Probably contain peat)

Beach and dune sand and gravel
(Manly as mapped in 1887)

Sand and gravel, thin, of the North Truro
plain, overlying eroded surface of older
leistocene sand, gravel, and Gardiners

(?) clay

Sand and gravel and scattered boulders
of the Wellfleet plain, overlying eroded
surface of older Pleistocene sand, gravel,
and Gardiners (?) clay

and gravel of the Eastham
plain, with kame belt on the south
(Deposited by streams flowing westward from
an ice front on the east)

eee
Outwash sand

; Falmouth moraine

(Thin bouldery glacial drift overlying outwash
sand and gravel po i older Pastels
deposits)

Sand and gravel outwash from Falmouth
moraine overlying older Pleistocene
deposits

of Nantucket substage of Wisconsin but
chiefly pre-Wisconsin deposits

(These and similar beds beneath intervening
swamps and ponds prevented the remnants
of ice of Nantucket substage from bein
covered by outwash from the Polmeuth

"0:

QUATERNARY

Ms,

Gardisers (?) clay

42 00°

a
Hl] Hl Wi t
N >
\\\ =
yy
RB oR \
\ \\ \ \ // Hy Wi Yj \ \\\
x | | } |] / HLT Whi \\ \\\ \W\\\ — ;
Hy} \\\\\\\\
\
G ;

Vig

ae
\\

<<
Sig tae Na
eee os
as

Soe

anes

YY
YY
Mf Hf |

/
//
ti
/ |

///
fit
LLL

//

i //

}/ |

SSS

==

—

eae a

a, toe
ie ee
Pies

ea
oe Seno. es =
eee ae eee
ese
oe

/
iy
bel

yy |
Yyyyy
Yj) 7/
Yy Uff
/

41°35’
LLL I
fiT] Hf} | oe
WN
/ ELT LLY PY /
rae Hi} iif / /
/ WAY f/ /
TL} Lf i
Wi,
Yj ent SHIP”
/ aire
Wiis
eee
es
ee
Sigh
je jl , 4 70° 00 WILLIAMS & HEINTZ CO,WASH,D C. 69° 55.

Base from U. S. ———— Survey topographic
maps of Provincetown, Wellfleet, Yarmouth,

and

atham

quadrangles, reprinted from

earlier editions without revision

: Geology by J. B. Woodworth,
GEOLOGIC MAP OF CAPE COD PENINSULA, MASS. (EAST HALF) ci gk a ipa
Seale 32800

a a ° t 2 38 4 Miles

1 + ° 2 2 3 a 5 Kilometers

Contour interval 20 feet.
Dank. y p 7.

PLATE 3

PLATE 3

Outline map of Elizabeth Islands.

Shorelines from U. 8. Coast and Geodetic Survey Sheet No. 1210, with soundings and other features
omitted. Drawing and cut prepared under the supervision of the United States Geological Survey.

GEOLOGY CAPE COD. PLATE 3

MEM. MUS. GOMP. ZOOL.

Z
Ov,02 Sp |SS00L
uoggiy ede
a 2
Oe we wa Nn

14
lol 7

jolt?

‘lL 3SAMINSd

‘| LASSAWYNON 8

Tos

4d uineysi-w

Ov OL

“Yd II!H PYNOY
Lnowiv4 ie
4q Buiuung
“4d UWE

UOBZO}9!14
a “Fd NDIIUOIS ae ‘J &
bit. z f Baa a Liv

IN 1SamM } \ ea
a ee
is 0S JS0OL e

PLATE 4

PLATE 4

Map of coastal plain formations of southeastern Massachusetts, Rhode Island, and eastern Connecticut.

Base from United States Geological Survey. Geology by J. B. Woodworth, United States ee
Survey, 1915-1916. Drafting and editing supervised by the United States Geological Survey

-

U.S. Geological Survey, 1915-1916

GEOLOGY CAPE COD. PLATE 4
Geology by J. B. Woodworth,

\
_

°
fo)

e Vaas
et SN ~
ee

WAS

pt
“
> Ay 4
x N
rr ;
. . > cs
er hy
. ‘4 ®)
IN ¥
NX
‘

\
2)

NX: EERE <
a ls ‘ : SN ay oO
\ WSs AE nv; : e : . SS Was SY \ Sad
e +S = aoe 5 ES A \E ty
XX \ WS ie : Se |
QZ ey NS
3 S TN N
G BW
0 : ae a

EXPLANATION

f

y
‘oximate zone o
ocene deposits

re

“th

Pleistocene deposits.

x
500,000

Scale

30 Miles

20

|
5.2
35
ie)
RS
o>,
33
=e
Bap
£5
a
oS
he
ad

Miocene greensand
(only known outcrops shown).

| MAP OF COASTAL PLAIN FORMATIONS OF SOUTHEASTERN MASSACHUSETTS, RHODE ISLAND, AND EASTERN CONNECTICUT

WILLIAMS & HEINTZ CO,WASH.,D.C

N ZA Up Uy Lip y Los 5 Yy Wes

°
i

Base from U. S. Geological Survey

MEM. MUS. COMP, ZOOL.
1:500,000 scale map

ae ST So, BE oe iS

PLATE 5

PLATE 5

Fossil mollusks from the Miocene greensand.

Fig. 1. Panopea sp. Daniel Webster estate, Marshfield, Mass.
Fig. 2. Venus sp. Marshfield, Mass.
Fig. 3. Macoma lyalli Dall. Gay Head, Mass.

PLATE 5

GEOLOGY CAPE COD.

MEM. MUS. COMP. ZOOL.

ck cas a

HELIOTYPE CO. BOSTON

PLATE 6

PLATE 6

Map of eastern Massachusetts and Rhode Island, showing extent, directions of movement, terminal
moraines, and boulder fans of ice sheet of Wisconsin stage of glaciation.

Drafting and editing supervised by the United States Geological Survey.

ct ee ae
MEM. MUS. COMP. ZOOL.

GEOLOGY CAPE COD. PLATE 6
72° 70°
te)
$
v |
0
: =
s
| (ape Ann
° a
°
8
\ \ | | =
\
a
oe
\ 6 |
0
e

ree SAR wa 2 :

\ | | —
\ \ Re ‘ |
Ca a

we
No

ae

eg ee
ry
— e
CONNECTICUT_ __#
[ISLAND 2

ob ==

ee
P29Q000g6

s

\ 1A
SRG AL MOUTH
\

No
ala)
\SZAUNTON ©

cS
ay
me le

ve\ [ox

ODE

Re
.)
——
>e
a
@
Bs)
‘y
8)
.
a

So
: | if : os
v. | , H
pot j | i Bit ‘ fe

Se a i fe
anne : a e | a Ly id Crnt d Ser ie
Va \ \, Beste a ee eels
en |

\
\
\
L
LO
\
\
2
fe
=
N

“
oe

a oo as
12 van 70°

MAP OF EASTERN MASSACHUSETTS AND RHODE ISLAND SHOWING EXTENT, DIRECTIONS OF MOVEMENT

TERMINAL MORAINES AND BOULDER FANS OF ICE SHEET OF WISCONSIN STAGE OF GLACIATION
By J. B. Woodworth
oe 10 > 30 30 Miles
10 es, 10 20 30 40 Kalometers

a
_
nw
‘ oe
Terminal! moraine.

Direction of ice movement.
(Generalized).

ener hg of chiastolite- Peridotite boulder fan
bea: me al pebbles and Pawel ~~ Mine ae
Rouen m Georges Hill ay and Blo
to Blo ah ‘ne ad. Island.

Distribution of ice-borne Probable trail of ice-borne
agate pebbles probably porphyritic dike rock
cS a near Diamond
Hill.

fragments ag re » drift
at Plymouth,

PLATE 7

PLATE 7

Map of Cape Cod, Mass., showing an old cross-channel south of Hastham.

Reproduced from a copy of part of “A portion of a Map of New oS in jhe Public Record
Office, London, England. Copied for Charles Hervey Townshend, Esq. of ‘Raynham,’ New Haven,
Conn., U.S. A., by L. M. Byrne, April, 1887,” as eee ee in U.S. Coast and Geodetic Survey Report
for 1800, Plate 71,

‘Captain Townshend is of opinion from evidence afforded by the chart itself, and by the copious
notes it contains relative to the coasts, shoals, and passages embraced within its limits, that it was con-
structed by a hydrographical survey party, composed of British naval officers, between the years 1715
and 1720. There are, however, some indications that parts of it had an origin from 20 to 30 years earlier.”

The officer referred to in the note, opposite the old passage way through Cape Cod, “‘ was probably
Captain Cyprian Southack, a Boston pilot, who commanded a ship in the expedition against Quebec,
1690.”

Drafting and editing supervised by the United States Geological Survey.

MEM. MUS. COMP. ZOOL.

GEOLCGY CAPE COD. PLATE 7

oe
2S a2 yo fo 50 Late C
vo So
5 20 ie ~
i Kt
bes ground i =
wy “y pastlap? Cod
. 60
Yoh landef Ga
AO
a i ae
Js ae
: 60
es 2
; e ee eae :
10 ce
a Griffins Ie, sod -
Fe Boy 13 not of dangeroud by Grech Ws ‘30 og
Be, as : * Crab. $i
Lh of agent J, ee : 2 ;
ye. 2 “g° 2
(et Ddpth. of U. Mhatol seesceat™ Zi of zo 46 Ji
Vests at high SfWaer woe i . Stony oo :
is 9: Wt £ 2
wees Auown from om fathoms 2 pe . SableLand 2 2: 1 i x
ae i the, rae be PF placed by therm, 7 : : siery \ : 30 2 :
Barnftable 7 > Bay <a r a op ee -
Garde Bron Sand, - se “Uh HL.
Y Gove ae a
y¥ THe ae Lod Bek
¥ castaway ¥ 26 7a ae wih vcard
4 Ore Hundred ke
—
ee =
ae
Tie wo
a2 Gose Brown Sand,
it 2
oe oo
- 3 ue
a = 70 foot ‘
Ss . a i
Coarse Sand Jo: : v -
1k 10 re = S :
fo
A Seale of Leagues
i Z ZA. Z ZA Z Zi Z ZA wZ ZA,
1 2 3 4 3 6 7 8 9 10

PLATE 8

Te RA ERE em cee anerene erm

PLATE 8

Geologic map of Nantucket, Mass.

Base from the United States Geological Survey topographic maps of Muskeget and Nantucket
quadrangles. Geology by J. B. Woodworth, United States Geological Survey, 1915-1916. Drafting
and editing supervised by the United States Geological Survey.

\
>

oe

~ oo Op eR ITN. Je

pA Mn

MEM. MUS. COMP, ZOOL. : ; . GEOLOGY CAPE COD. PLATE 8
70°20 f é : 5 ee BF PT og

EXPLANATION

= ae i a
Swamps (fresh)

(Probably contain peat)

Recent

—————
Marshes (salt)
(Probably contain peat)

%

Beach and dune sand and gravel
Se 08,

Sand and gravel of outwash plain corre-
lated with Nantucket moraine

Ice contact slopes at head
of outwash plain

Sandy drift in fosse

Pleistocene
Wisconsin stage

| | / / \ \ Hyd
| , LITT MI“ ) Kit i |} y Lf. \ 20’
| 20 hg ; ] x =\ SZ iF y ] rT 7 Z 7, y : TTT NN : 5 ES PERE oe
f/f Y y Hitt |S ZY Zi, / é ify / $$$ ¢ /, Y) Y= TF) | \ \ ‘ Z > e
| } J Yy Z Zy Yj yy Yy Jt y lw. WY \ Drift, thin, overlying older deposits
\ a \ \ Y

ates 24

Nantucket moraine
(Corrugated moraine, marginal, mainly
fo pre-Wisconsin beds overlain by thin
Wisconsin drift)

SE
ee
— =

SSS

= =
——
—————

— io

41°13’
57’

4nis' 70°20’ 15’ 7 10’ a WILLIAMS & HEINTZ CO,WASH, D.C. 70°00! 69
Geology by J. B. Woodworth,
U. S. Geological Survey, 1915-1916

Base from U. S. Geological Survey topographic :
maps of Muskeget and Nantucket quadrangles.
reprinted from earlier editions without revision. GEOLOGIC MAP OF NANTUCKET, MASS.

Scale 6300 ' ‘ ; 2

ay 3 2 7 4 Miles

oO
i! <a ° a es 3 4 5 Kilometers

Contour interval 20 feet.
ee lowed

QUATERNARY

PLATE 9

PLATE 9
Map showing changes at Smiths Point, Nantucket Island, from 1846-1887.
Reproduced from a report by Henry L. Marindin, United States Coast and Geodetic Survey, Report

for 1892, Pt. 2; App. No. 6, Plate 27, op. cit., p. 248, 1893. Drawing and cut prepared under the super-
vision of the United States Geological Survey.

Seen secenetrtem,.
i

MEM. MUS. COMP. ZOOL.

GEOLOGY CAPE COD. PLATE 9

CHANGES
AT

SMITHS POINT

From 1846 to 1887

S Seale

STATUTE MILES

Ad j thus YoJtlbJ€bCr~;
Retreat shown thus ZZ.

dares ocreemminnmisntne ercenmeenteeer emeremi <Megaili ‘Ses iaceiiidsinsren sen J . peste ene te > ee ee “Wiican oa

Le oe

| PLATE 10

PLATE 10
Views of the eastern coast of Nantucket in 1916

Fig. 1. Gullied cliff near Siasconset, — north.
Fig. 2. Pebbly clays at Wauwinet. (See p. 169). f

RII aI gE NG TI

ca eect ee

MEM. MUS. COMP, ZOOL,

HELIOTYPE CO. BOSTON

GEOLOGY CAPE COD. PLATE

10

| PLATE 11

PLATE 11

Views of the surface of Nantucket

Fig. 1. Southern side. Sea cliff, Tom Never’s Head. Ice-contact slope marking the front of the
ice sheet on the right of the cliff.
Fig. 2. West of town of Nantucket looking south. Corrugated moraine enclosing swamp.

Fm 6 pe <A A sm

>

\
{
\
%
|
,

gag et: I e.g

ee ee
a i >

At

a) ca

GEOLOGY CAPE COD. PLATE 11

MEM. MUS. COMP. ZOOL,

er | em: A mat

Se

(Rn <n eet

ge I ae erg,

ae Nie eee een

I I

Sa A epee. eS eR

HELIOTYPE CO. BOSTON

PLATE 12

PLATE 12

Pebbles and stones carved by sand blast.

Fig. 1. Sand-blasted glacial pebble (glyptolith), from the surface of a wind-blown tract.
Fig. 2. Sand-blasted glacial erratic (glypolith) of the three-edged type, from cliffs, north side

of Nantucket. The under side shows glacial striation unaffected by subsequent wear.

=
ae)
12)
N
o
=
ie)
O
1)
2)
=
=
ial
2

GEOLOGY CAPE COD. PLATE 12

HELIOTYPE CO, BOSTON

PLATE 13

PLATE 13
Geologic map of Marthas Vineyard and of part of Elizabeth Islands and No Mans Land, Mass.

Base from the United States Geological Survey topographic maps of Gay Head and Marthas ae
ard quadrangles. Geology by J. B. Woodworth, United States Geological Survey, assisted by
Wigalesworth and Gilbert Hart, 1915-1916. Drafting and editing under the supervision of the a
States Geological Survey.

MEM. MUS. COMP, ZOOL.
70°57’ beta)

a er ee

SS pe Aer

n

41°15
10S © 5
rvey topographic
maps of Gay Head and Marthas Vineyard
quadrangles, reprinted from earlier

BE:
—————
a

Be

GEOLOGY CAPE COD. PLATE 13
Viewrse
THAI? 30°

i] j
YH
Yj /

Yy Yj Wy
ft

WILLIAMS & HEINTZ CO,WASH,D.C.

Recent

(Thin
Pleistocene deposits, mostly sand and gravel)

tage

A.

SCONSIUN S

t

Pleistocene
W

4
30 1G8er

45’

Base from U. S. Geological Su
M

editions without revision

a 3 ° s

GEOLOGIC MAP OF MARTHAS VINEYARD AND
OF PART OF ELIZABETH ISLANDS AND NO MANS LAND, MASS.

Scale 32800

L = eo” 2 2

Contour interval 20 feet.

Geology by J. B. Woodworth,
U. S. Geological Survey, assisted by
E. Wigglesworth and Gilbert Hart, 1915-1916

EXPLANATION

ot
ia
P Sai,

Suretign (fveah)

2 = SS
Marshes (salt)

Beach and dune sand and gravel

Falmouth moraine
bouldery glacial drift overlying older

QUATERNARY

& eae ee]
Nantucket moraine
Wisconsin cla
till overlain
drift)

Outwash sand and gravel correlated with
Nantucket moraine

Pre-Wisconsin Pleistocene deposits, includ-
ing folded and faulted gor tills, boul-
ders, sand, gravel, and Gardiners clay

marine)

Older Pleistocene, Miocene, and Upper
retaceous deposits

(Uncludes folded and faulted glacial till, boul-
ders, sand, and gravel overlying Aquinnah
conglomerate (earliest Pleistocene); Miocene
greensand; Upper Cretaceous white clay
and gravel (partly marine?) and variegated
clays and lignite)

CRETACEOUS, TERTIARY,

AND QUATERNARY

NOLSO8 “OD 4dA LOUGH

PLATE 14

PLATE 14

Gay Head Cliffs, south of Devils Den, Marthas Vineyard. Photograph, April, 1894, by Philip P.
Sharples.

MEM. MUS. COMP. ZOOL. GEOLOGY CAPE COD. PLATE 14

HELIOTYPE CO. BOSTON

PLATE 15

PLATE 15

Views of the glacial deposits of Marthas Vineyard

Fig. 1. Morainal topography in West Tisbury near the Chilmark line.
Fig. 2. The outwash plain with the western moraine in the distance.
Photographs by Edward Wigglesworth.

PLATE 15

GEOLOGY CAPE COD.

MEM. MUS. COMP. ZOOL.

HELIOTYPE CO. BOSTON

PLATE 16

PLATE 16

Views of Marthas Vineyard upland

Fig. 1. Morainal topography of the western uplands, with pre-Wisconsin valley in foreground,
slightly changed by ice action
Fig, 2. _ of Me sees beds in ioradial ee showing almost no Wisconsin drift
ring. In Peaked Hill district of Chilma
Photogrighe | = Edward Wigglesworth.

MEM. MUS. COMP. ZOOL, GEOLOGY CAPE COD. PLATE 16

¢ . bye ‘ ]

ers ee
>:

HELIOTYPE CO. BOSTON

PLATE 17

PLATE 17
Views of glacial details on Marthas Vineyard

ig 1. Subdued morainal topography west of Sengekontacket Pond; Cape Cod Bay glacial lobe.
_ 2. Morainal knob and boulders, Chilmark; Buzzards Bay lobe of the Wisconsin glacier.
fees by Edward Wigglesworth.

MEM. MUS. COMP. ZOOL. GEOLOGY CAPE COD. PLATE 17

HELIOTYPE CO. BOSTON

PLATE 18

PLATE 18

Views of glacial details on Marthas Vineyard

Fig. 1. Lower portion of Lagoon Pond, with Vineyard Haven in the distance. A submerged pre-
Wisconsin valley.
_2. Ice contact slope and fosse north of West Tisbury.
a by Edward Wigglesworth.

18

|
1

PLATE

i
i
|
|

GEOLOGY CAPE COD.

2
HELIOTYPE CO. BOSTON

MEM. MUS. COMP. ZOOL,

i a aid

2 Se ee NT OT Te eR MES eT NTT ae RE ee eS eRe

alan

iii aici ee ae eer

PLATE 19

PLATE 19
Marthas Vineyard
Fig. 1. ae of Oyster Pond channel, looking south. A typical drainage crease crossing the out-

e2: Nout end of Gay Head cliffs, the largest exposure of Cretaceous beds on the island.
Poe fe by Edward Wigglesworth.

MEM. MUS. COMP. ZOOL, GEOLOGY CAPE COD. PLATE 19

a ti ll

HELIOTYPE CO, BOSTON

PLATE 20

PLATE 20

Marthas Vineyard

Fig. 1. Nashaquitsa cliffs in 1915, looking we
2. The same cliffs, broken by landslips in ae Gardiners clay.
Photographs by Edward Wigglesworth.

MEM. MUS. COMP. ZOOL GEOLOGY CAPE COD. PLATE 20

HELIOTYPE CO. BOSTON

i
|

| PLATE 21

PLATE 21

Fossils from Upper Cretaceous beds in Gay Head Cliffs

Fig. 1. Leaf nodule from the plant-bearing beds. Original in the Harvard Geological Museum.
Fig. 2. Concretion from the clays folded under the lignite bed. Original in the Harvard Geological
Museum.

MEM. MUS, COMP. ZOOL. GEOLOGY CAPE COD. PLATE 21

a a as

HELIOTYPE CO. BOSTON

— spas

PLATE 22

PLATE 22

Pleistocene fossils from the Aquinnah conglomerate at Gay Head.

Fig. 1. Astragalus of horse (Equus? ee Leidy).
Fig. 2. Metacarpal of camel (Protocamelus? sp.).
Fig. 3. a. Tooth of a whale (Squalodon sp. -

b. End view of the vertebra of a Dolphin.

MEM. MUS. COMP. ZOOL. GEOLOGY CAPE COD. PLATE 22

HELIOTYPE CO. BOSTON

PLATE 23

PLATE 23

Marthas Vineyard

Fig. 1. Nashaquitsa cliffs. East end of section showing lowest Pleistocene gravels at right, Gar-
diners clay and sand at left, vertical boulder bed upturned (Moshup till) in center, as
exposed on Sept. 4, 1916.

Fig. 2. Gita clay, sanded jing Manhasset formation southwest of Cape Higgon, on Vine-
MA

a :
Photographs by Edward Wigglesworth.

i
|
|
|
|
|

GEOLOGY CAPE COD. PLATE 23

MEM. MUS. COMP. ZOOL,

HELIOTYPE CO. BOSTON

nn nner iain in ectenenpeeen on rtaleapenepe tla ; = anc See nicer oiacincrtmrnttali oe se

PLATE 24

seas ama aammaaia iil aaa

PLATE 24

Marthas Vineyard

Fig. 1. Montauk till in road cut, town of Gay

ead.
2. Montauk till overlying Herod gravel. ee Beach cliffs near west end.

Fig
eee by Edward Wigglesworth.

MEM. MUS. COMP. ZOOL,

HELIOTYPE CO, BOSTON

GEOLOGY CAPE COD. PLATE 24

iin —iniimttnnneanatrece “Te ne agen

PLATE 25

PLATE 25

Views of Marthas Vineyard and Cape Cod

Marthas Vineyard. Montauk till showing characteristic erosion forms.

Fig. 1. Squibnocket cliffs,
s, as seen from railroad track in the

Fig. 2. Cape Cod. Old sea cliff on west side of Pilgrim Height
marshes. The North Truro plain is above this cliff.

|

MEM. MUS. COMP. ZOOL, GEOLOGY CAPE COD. PLATE 25

HELIOTYPE CO. BOSTON

PLATE 26

Topographic map of No Mans Land, part of Marthas Vineyard, Mass., and adjacent shoals.

(Contour interval 20 feet. Shore lines and topography on land from United States Geological Survey
topographic map of Gay Head quadrangle. Soundings in feet at mean low water from United States
Coast and Geodetic Survey Sheet No. 1210.) Drafting and editing supervised by the United States
Geological Survey.

| MEM. MUS. COMP. ZOOL. GEOLOGY CAPE COD. PLATE 26

70°50" 70°45

fe) | z 3 MILES
{Rees ee es ae ea ee 1 }

PLATE 27

PLATE 27

Glacial beds in the cliffs of No Mans Land

Fig. 1. Folded sand and Gardiners clay overlying Moshup till. One-half mile north of southeast
oint of the island, June 14, 191

Fig. 2. Boulder-bearing Montauk , in small bay near middle of the south side of the island;
looking N. 24° W., June 1 16.

|
|
|
}
|

MEM. MUS. COMP. ZOOL, GEOLOGY CAPE COD. PLATE 27

HELIOTYPE CO. BOSTON

PLATE 28

PLATE 28

Views of No Mans Land

Fig. 1. View of the cliffs one-third mile east of southwest point of No Mans Land, on south shore
June 14, 1916.

Fig. 2. Surface of No Mans Land at cliff edge, about half a mile east of the southwest point on
south shore, June 14, 1916.

MEM. MUS. COMP. ZOOL, GEOLOGY CAPE COD. PLATE 28

HELIOTYPE CO. BOSTON

PLATE 29

PLATE 29

Geologic Map of Block Island

Base from United States Geological Survey topographic map of Block Island quadrangle. Geology
by J. B. Woodworth, United States Geological Survey, 1915-1916. Drafting and editing under the
supervision of the United States Geological Survey.

nk, emma.

GEOLOGY CAPE COD. PLATE 29

Recent

Pleistocene

Cc

——

Ss

=

=

—

=

—
sa
—————

Segemram

oo

ee

es

7 35
GEOLOGIC MAP OF BLO

LN

EXPLANATION

Swamps
(Chiefly above sea level)

Beaches and dunes
(Sand and gravel)

Se

Nantucket moraine

Wisconsin stage

—

Pre- Wisconsin

deposits

(Sand, gravel, boulders. and g
)

posed only in sea cliff

: | ae
8 .
& White clay and dark lignitic clay

(Exposed only in sea cliffs)

Upper

QUATERNARY

(Corrugated moraine, mainly of folded pre-
Wisconsin clay, sand, gravel, and glacial
till overlain by thin bouldery Wisconsin
drift)

Manhasset formation, Jacob sand
Gardiners clay, and older P
it

CRETACEOUS

Na

PLATE 30

PLATE 30

Glacial deposits, Mohegan Bluffs, Block Island

Fig. 1. Southeast point, looking southwest. Gardiners clay on beach in foreground Jacob
sand. Manhasset formation with Montauk till member in background of ¢

Fig. 2. View west of Southeast Point, Block Island, looking eastward at pinnacles = Moot
boulder clay. October 31, 1915.

MEM. MUS. COMP. ZOOL GEOLOGY CAPE COD. FLATE sO

HELIOTYPE CO. BOSTON

PLATE 31

Cae ae eee A ee ae

PLATE 31

Surface features of Block Island

Fig. 1. View showing configuration of the surface of Block Island, south of Beacon Hill.
Fig. 2. Sand dune on Crescent Beach, east coast of Block Island.

MEM. MUS, COMP. ZOOL, GEOLOGY CAPE COD. PLATE 31

re cphrentt
Kreers

HELIOTYPE CO. BOSTON

PLATE 32

PLATE 32

Block Island

Fig. 1. Wind ripples on black magnetic sa nd.
Fig. 2. Remains of device for magnetic separation of black iron sand of the Crescent Beach dunes.

ont iin iy

erin, asi

MEM. MUS. COMP, ZOOL, GEOLOGY CAPE COD. PLATE 32

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HELIOTYPE CQ. BOSTON

a neeneaenics eR "en a "ean —eccerllgamnes- cn mae Tt ee an —gmmemne ee" ~ ean——ge ae

PLATE 33

eee eT it i ep mag emer mee * eggnog net Tam ne

PLATE 33

Exposures of Gardiners (?) clay on Cape Cod.

Fig. 1. The “clay pounds” at Highland Light, near the wireless station. Jameco (?) gravel at
base, Gardiners (?) clay in the middle, and Jacob (?) sand at the top of the section.

Fig. 2. Gardiners (?) clay exposed in anticlinal fold on Nickerson’s Neck, south shore of Pleasant
Bay near Chatham. Looking S. 70° W, July 28, 1916.

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| MEM. MUS. COMP. ZOOL, GEOLOGY CAPE COD FLATE 33

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“a

HELIOTYPE CO. BOSTON

PLATE 34

emer. emer ae e-em

PLATE 34
Views of Cape Cod
Fig. 1. Enos Rock in Eastham. A granite boulder from the South Channel lobe of the Wisconsin

ice sheet. :
Fig. 2. The sea cliff at Chatham in front of the old lighthouse.

MEM. MUS. COMP. ZOOL

ition, sss...

HELIOTYPE CO. BOSTON

GEOLOGY CAPE COD. PLATE 34

PLATE 35

PLATE 36

PLATE 36

Views of Cape Cod

Fig. 1. Panorama of dune ridges about 1} miles northeast of Pilgrim Monument.
Fig. 2. Lee side of old sand dune near Duck Pond north of Provincetown.
Photographs by T. Wayland Vaughan.

MEM. MUS, COMP, ZOOL.

aeibonynneeae

GEOLOGY CAPE COD. PLATE 36

SOP tee wee ee

HELIOTYPE CO. BOSTON

PLATE 37

PLATE 37

Fig. 1. Marsh growth at head of old harbor, Wellfleet, Cape Cod.
Fig. 2. Edge of natural forest on south shore of Naushon Island.

MEM. MUS, COMP. ZOOL. GEOLOGY CAPE COD, PLATE 37 i

HELIOTYPE CO. BOSTON

PLATE 38

PLATE 38

Geology of Elizabeth Islands

Fig. 1. A shoved frontal moraine on crest of Naushon Island.

Fig. 2. Glacial boulder on beach east of Tarpaulin Cove, Naushon.

MEM. MUS. COMP, ZOOL. GEOLOGY CAPE COD. PLATE 38

e HELIOTYPE CO. BOSTON

—

PUBLICATIONS

OF THE
MUSEUM OF COMPARATIVE ZOOLOGY

AT HARVARD COLLEGE.

There have been published of the BuLietin Vols. I to LXV,
Vols. LXVII-LXXV; of the Memorrs, Vols. I to LII.
Vol. LXVI, of the Butnertin, and Vol. LIII of the Memorrs,

are now in course of publication.

A price list of the publications of the Museum will be sent on appli-
cation to the Director of the Museum of Comparative Zoblogy, Cambridge, |
Mass.

ae

sci nance Teooriton

wT