a/I B R.ARY

OF THL

U N I VLRSITY
Of ILLIN01Sf

570.9773

cop. 3

The person charging this material is re-
sponsible for its return to the library from
which it was withdrawn on or before the
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are reasons for disciplinary action and may
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UNIVERSITY OF ILLINOIS LIBRARY AT URBANA-CHAMPAIGN

i iwo DEC 1 4

i5 2000

L161 — O-1096

A NATURALIST IN THE GREAT
LAKES REGION

THE UNIVERSITY OP CHICAGO PRESS
CHICAGO, ILLINOIS

THE BAKER & TAYLOR COMPANY

NEW YORK

THE CAMBRIDGE UNIVERSITY PRESS

LONDON

THE MARUZEN-KABUSHIKI-KAISHA

TOKYO, OSAKA, KYOTO, FUKTJOKA, SENDAI

THE MISSION BOOK COMPANY

SHANGHAI

IHt
OF THE
OF ILLINOIS

A NATURALIST
IN THE GREAT
LAKES REGION

By
ELLIOT ROWLAND DOWNING

The School of Education ( University of Chicago

THE UNIVERSITY OF CHICAGO PRESS
CHICAGO, ILLINOIS

COPYRIGHT 1922 BY
THE UNIVERSITY OF CHICAGO

All Rights Reserved

Published April 1922
Second Impression August 15

Composed and Printed By

The University of Chicago Press

Chicago, Illinois, U.S.A.

,3

GENERAL PREFACE

Never before in this country has there been so insistent a
•'^demand for a more thorough and more comprehensive system
Z-pf instruction in practical science. Forced by recent events to
O compare our education with that of other nations, we have
n suddenly become aware of our negligence in this matter. Now
£ industrial and educational experts and commissions are united
z? in demanding a change.

-£ While on the whole there has been a steady increase in the
amount of time given to science work in the secondary and ele-
mentary schools, the attention paid to it, especially in the
elementary schools, has been somewhat spasmodic, and its
administration has been more or less chaotic. This is not due
to lack of interest on the part of school officials but to their
dissatisfaction with the methods of instruction employed.
^ There is no doubt that superintendents would gladly introduce
~ more science if they felt sure that the educational results would
_j be commensurate with the time expended. This is indicated
-^ by a recent survey of about one hundred and fifty cities in
"" seven states of the Central West. The survey shows that two-
thirds of them have nature-study in the elementary schools and
-, that all are requiring some science for graduation from the high
^ school. The average high school is offering three years of science.
^ Since 1900 there has been a greater increase in the percentage
of students enrolled in science in the high schools than in any
It! other subject with the one exception of English. Moreover,
j greater attention is now being paid to the training of teachers
&: in methods of presentation of science.

jj The chief needs in science instruction today are a more
^ efficient organization of the course of study with a view to its
- socialization and practical application, and a clear-cut realiza-

583295

viii GENERAL PREFACE

tion on the part of the teacher of the aims, the principles of
organization, and the methods of instruction; it is to meet these
needs that this series is being issued. The books attempt to
present such generalizations of science as the average pupil
should carry away from his school experience and to organize
them for the preparation of the teacher and for presentation to
the class. The volumes will therefore be of three kinds:
(i) source books with accompanying field and laboratory guides
for the use of students in normal schools and schools of educa-
tion, and of teachers, (2) pupils' texts and notebooks, and
(3) books on the teaching of the various science subjects. In
the first the material will be organized with special reference
to the training of the teacher and the most effective methods
of presenting the subject to students. In the second the matter
will be simplified, graded, and arranged in such a way that
the books will serve as guides in science work for the pupils
themselves. Moreover, they will furnish texts for the grades
and high school that will simplify the teacher's task of presenta-
tion and will assure well-tried and well-organized experiences,
on the part of the pupil, with natural objects. This series of
texts for elementary and secondary schools will have dependent
continuity and the subject-matter will gradually increase in
difficulty to accord with the increasing capacity of the pupils.
It will furnish a unified course in science. The third type of
book is for the teacher and deals with the history, aims, prin-
ciples of organization, and methods of instruction in the several
sciences.

AUTHOR'S PREFACE

There is no commonplace; the most dully monotonous
environment is full of wonders, if vision can be enlarged to
apprehend them. J. Henri Fabre, that astute French naturalist
whose portrayal of the interesting lives of the humble denizens
of field and forest we are all reading with avidity, saw more of
the marvelous in his own back yard than the average globe-
trotter sees in all his travels. Slabsides was but a poor shack
in an ordinary farm wood lot. The pond at Walden has its
duplicate in the outskirts of a thousand American villages.
But John Burroughs and Henry D. Thoreau had eyes to see,
ears to hear, and hearts to understand.

Fortunately there is an ever-increasing number of persons,
both young and old, who are learning what fascination there is
in the tales Nature spreads before our eyes in hill and dale,
river and forest, bird and beast, flower and blade of grass.
They are learning to read the landscape, to achieve a companion-
ship in the outdoors quite as real and as satisfying as that of a
wise friend or a stimulating book. For such this book is written
as an aid to an understanding of familiar surroundings.

It is hoped the volume may serve as an advanced general
science, particularly for those teachers who believe that science
instruction at its best is an attempt to interpret the significance
of the commonplace. It craves audience, too, of all those
nature-lovers who desire an introduction to the study of the
things about them as one means of culture. The several type
regions are treated in separate chapters so that one may take it
as a companion into the Dunes, the forest, the prairie, the river
valley and learn by means of the brief descriptions and illustra-
tions to identify the plants, animals, and physiographic processes
encountered, and appreciate something of their meaning.

x AUTHOR'S PREFACE

The author is indebted to Miss Helen Snyder for the care
with which many of the drawings have been made. While the
drawings, except as acknowledged in the text, have been made
from the specimens, suggestions as to methods of expressing
essential characters have been taken at times from the books
mentioned in the list at the end of the volume. The author
gratefully acknowledges his indebtedness.

A few of the half-tone illustrations are from negatives in the
collection of the School of Education, for the use of which the
author expresses his indebtedness.

ELLIOT R. DOWNING

UNIVERSITY OF CHICAGO

SCHOOL OF EDUCATION

December 27, 1921

CONTENTS

PAGE

LIST OF ILLUSTRATIONS xiii

CHAPTER

I. THE CHANGING FACE OF NATURE ...... i

II. THE WORLD IN THE MAKING . . . ...--. . . 21

III. THE STORY OF OUR ROCK FOUNDATION 36

IV. THE GLACIAL PERIOD 56

V. LAKE CHICAGO AND ITS OLD SHORE LINES . . . . 78

VI. DISTRIBUTION AND ADJUSTMENT 90

VII. THE DUNES AND THEIR PLANTS 112

VIII. ANIMALS OF THE DUNES 148

IX. INTERDUNAL PONDS AND TAMARACK SWAMPS . . . .167

X. THE CLIMAX FOREST AND ITS PREDECESSOR, THE OAK-
HICKORY TYPE 202

XI. 'LAKE TO FOREST OR PRAIRIE 232

XII. LAKE BLUFF, RAVINE, AND RIVER VALLEY 259

XIII. BROOK, CREEK, AND RIVER 276

XIV. SOME SOURCES OF OUR FAUNA AND FLORA .... 293

AN OUTLINE OF SOME OF THE IMPORTANT PLANT AND ANIMAL

ASSOCIATIONS 305

BOOK LIST 308

INDEX 311

LIST OF ILLUSTRATIONS

Bold Headlands on Lake Superior Frontispiece

CHAPTER I

PAGE

FIG. i. — Eroding Clay Bluffs on the Shore of Lake Michigan with

Vegetation Sliding Down into Lake 2

FIG. 2. — Serried Ranks of Billows, Lake Superior Shore ... 3

FIG. 3.— A Stream Cutting Its Banks 4

FIG. 4. — A Mountain Torrent in Its Narrow Valley . . . . • 5

FIG. 5. — The Beginnings of a Ravine near Glencoe . . . 5
FIG. 6. — A Deep V-Shaped Ravine near Fort Sheridan . . .6

FIG. 7.— The Dalles of the Wisconsin River 7

FIG. 8.— The Valley of the Illinois at Starved Rock .... 8
FIG. 9. — A Narrow Rock Ravine Ending in a Waterfall at Starved

Rock 9

FIG. 10. — The Glacier, a Stream of Ice, Canadian Rockies . . 9
FIG. ii. — Clay Pinnacles, Rainwashed, near Lakeside, Michigan —

Inset, Near View of Pinnacles 10

FIG. 12. — Talus at Foot of Cliff and Outwash from the Hills . . 12

FIG. 1 3 . — A Hill of Sand Moving Inland, South End of Lake Michigan 1 3

FIG. 14. — A Blow-out in the Dunes 14

FIG. 15.— A Filling Pond 15

FIG. 16.— A Flood Plain Where Deposits Occur Annually, Salt Creek

near Brookfield 15

FIG. 17. — Up-Arched Rock Strata, Pennsylvania . . . . 18

FIG. 1 8. — Lava Outflow Forming Great Areas of Rock . . . 19

FIG. 19. — The Terminal Moraine of a Glacier 19

CHAPTER II

FIG. 20. — Canon Diablo 24

FIG. 21. — A Spiral Nebula 24

FIG. 22. — Diagrammatic Section of the Earth 26

CHAPTER III

FIG. 23. — The Quarries of Stony Island Showing Opposite Inclina-
tion of Strata 37

FIG. 24. — Diagram of Rock Strata Found in Deep Boring at Lock-
port, Illinois 38

xiii

xiv LIST OF ILLUSTRATIONS

PAGE

FIG. 25. — A Dyke near Marquette, Michigan 39

FIG. 26. — A Monadnock, Ishpeming, Michigan 40

FIG. 27. — Rocks Folded and Crumpled, Jasper and Hematite,

Ishpeming, Michigan 41

FIG. 28. — Map of Surface Rocks, Illinois, Wisconsin, Michigan . 43
FIG. 29. — A Coral Reef Exposed at Quarry, Thornton, Illinois,

Showing the Concentric Lines of Deposit ... 45
FIG. 30. — Map Showing Land and Sea When Potsdam Sandstone

Was Depositing (Upper Acadian), after Schuchert . 47
FIG. 3 1 . — Map Showing Land and Sea When Magnesian Limestone

Was Depositing (Beekmantown); after Schuchert . . 47
FIG. 32. — Map Showing Land and Sea When Richmond Shales Were

Depositing (Cincinnatian), after Schuchert ... 47
FIG. 33. — Map Showing Land and Sea When a Part of the Niagara

Limestone Was Depositing (Mid-Silurian), after

Schuchert 47

FIG. 34. — Animal Fossils from Niagara Limestone .... 49
FIG. 35. — Map of the Late Paleozoic When the Illinois Coal Beds

Were Depositing (Upper Pennsylvanian) , after Schuchert 5 1
FIG. 36. — Fossils of the Coal Period from Mazon Creek, Illinois . 53
FIG. 37. — The Great Arch of Rocks in Illinois, a Diagram . . 54

CHAPTER IV

FIG. 38. — Glacial Map of North America 57

FIG. 39. — Conjectural Preglacial River System 58

FIG. 40. — Angular and Striated Glacial Bowlder near Glencoe,

Illinois 60

FIG. 41. — Grooves and Scratches on Bed Rock at Stony Island Due

to Glacial Erosion 61

FIG. 42. — Map of Moraines in the Chicago Region .... 62
FIG. 43. — Map of Moraines in Illinois, from Bulletin State Geological

Survey 65

FIG. 44. — View of Typical Glacial Country a Few Miles Southwest

of Chicago .66

FIG. 45. — Flathead, below Joliet, General View and Detail . . 67

FIG. 46. — Figures of Several Crystals 68

FIG. 47. — Cleavage Shown in a Piece of Orthoclase Feldspar . . 69

CHAPTER V

FIG. 48. — The Wisconsin Ice Sheet at Its Maximum Extension . 79
FlG. 49.— An Old Shore Line of Lake Chicago . . . . . 80

LIST OF ILLUSTRATIONS xv

PAGE

FIG. 50. — Lakes Chicago, Saginaw, and Maumee . . . . 81

FIG. 51. — Lake Chicago at a Later Stage and Lake Warren . . 83

FIG. 52. — Lake Algonquin 84

FIG. 53. — Map Showing Successive Shore Lines of Lake Chicago . 85

FIG. 54. — Grooves and Potholes in Bed of Outlet of Lake Chicago . 86

CHAPTER VI

FIG. 55. — Spring Flowers of the Forest Floor . . . . . 91

FIG. 56. — Fresh- Water Crustaceans 93

FIG. 57. — Map Showing Relation of Rainfall to Evaporation in

Eastern United States 95

FIG. 58. — Map of Forest, Prairie, and Plains Regions in Eastern

United States 96

FIG. 59. — Diagram of Rates of Evaporation in Contiguous Regions

(Adams) 97

FIG. 60. — The Cactus of the Dunes, Opuntia Rafinesquii ... 98

FIG. 61. — The Six-lined Lizard, Cnemidophorus sexlineatus . . 99

FIG. 62. — Relative Evaporation Rates in the Strata of the Forest . 100

FIG. 63. — Wild Lettuce, Lactuca scariola 101

FIG. 64. — Dissected Leaves of Bladderwort, Hornwort, and Milfoil;

Utricularia, Ceratophyllum, Myriophyllum . . .103

FIG. 65. — Closed Gentian, Gentiana Andrewsii 107

FIG. 66. — CuponStemotSilphiumperfoliatum . . . . 108

FIG. 67.— Digger Wasp, Bembex spinolae no

CHAPTER VII

FIG. 68. — Newly Formed Sand Bar Offshore in Dunes . . .113
FIG. 69. — Small Dunes Held by Prostrate Juniper, Juniper us

horizontalis .114

FIG. 70. — Panne at Miller 115

FIG. 71.— Double Row of Seedlings. Same Two Years Older . . 116

FIG. 72. — Sea Rocket, Cakile edentula 117

FIG. 73. — Bugseed, Corispermum hyssopifolium 117

FIG. 74. — Beach Pea, Lathyrus maritimus 117

FIG. 75. — Cinquefoil, Potentilla Anserina 117

FIG. 76. — Wormwood, A rtemisia caudata 117

FIG. 77. — Rye Grass, Elymus canadensis 117

FIG. 78. — Winged Pigweed, Cycloloma atriplicifolium . . . .117

FIG. 79. — Green Milkweed, A cerates mridiflora 117

FIG. 80. — Seaside Spurge, Euphorbia polygonifolia . . . .117

FIG. 81. — Cocklebur, Xanthium echinalum 118

xvi LIST OF ILLUSTRATIONS

PAGE

FIG. 82.— Sand Thistle, Cirsium Pitcheri 118

FIG. 83. — Fore-dune Association 119

FIG. 84. — Long-leaved Sand Reed, Calamovilfa longifolia . . .120

FIG. 85. — Marram, Ammophila arenaria 120

FIG. 86. — Sand Cherry, Prunus pumila 121

FIG. 87. — Furry Willow, Salix syrticola 122

FIG. 88. — Cottonwood Zone 122

FIG. 89. — Red-osier Dogwood on Steep Side of Advancing Dune . 123

FIG. 90. — The Pine Association . 124

FIG. 91. — Bearberry, Arclostaphylos Uva-ursi . . . . . 125

FIG. 92. — Arbor vitae, Thuja occidentalis 126

FIG. 93. — Shinleaf, Pyr old elliptica 126

FIG. 94. — Checkerberry, Gaultheria procumbens 126

FIG. 95. — Prince's Pine, Chimaphila umbellata 126

FIG. 96. — Bluebell, Campanula rotundifolia 126

FIG. 97. — Puccoon, Lithospermum canescens 126

FIG. 98. — Horsemint, Monarda punctata 126

FIG. 99. — St. John's- wort, Hypericum Kalmianum . . . .126

FIG. 100. — Bellwort, Uvularia grandiflora 126

FIG. 101. — Star Flower, Trientalis americana, and False Lily-of-the-

Valley, Maianthemum canadense 127

FIG. 102. — Blue-eyed Grass, Sisyrinchium angustifolium . . .128

FIG. 103. — False Solomon's Seal, Smilacina racemosa .... 128

FIG. 104. — Staghorn Sumac, Rhus typhina 131

FIG. 105. — Dwarf Sumac, R. copallina 131

FIG. 106. — Aromatic Sumac, R. canadensis 131

FIG. 107. — Poison Sumac, R. Vernix 131

FIG. 108. — Bittersweet, Celastrus scandens 131

FIG. 109. — The Frost Grape, Vitis cordifolia 131

FIG. no. — The Summer Grape, V. aestivalis 131

FIG. in. — The River-Bank Grape, V. vulpinus 131

FIG. 112. — Sassafras, Sassafras variifolium 131

FIG. 113. — Poison Ivy, Rhus Toxicodendron 132

FIG. 114. — Shadbush, Service Bush, or June Berry, Amelanchier

canadensis 133

FIG. 115. — Pin Cherry, Prunus pennsyhanica 133

FIG. 116. — Chokecherry, P. mrginiana 133

FIG. 117. — Huckleberry, Gaylussacia baccala 133

FIG. 1 1 8. — Bush Honeysuckle, Diervilla Lonicera 133

FIG. 119. — Spiderwort, Tradescantia mrginica 133

FIG. 1 20. — Bastard Toadflax, Comandra umbellata .... 133

LIST OF ILLUSTRATIONS xvii

PAGE

FIG. 121. — Anemone, A nemone cylindrica . . . . . .133

FIG. 122. — Columbine, A quilegia canadensis 133

FIG. 123. — Lupine, Lupinus perennis 134

FIG. 124. — Rock Cress, Arabis lyr ata . . 135

FIG. 125. — Hoary Pea, Tephrosia virginiana 135

FIG. 126. — Bush Clover, Lespedeza capitata 135

FIG. 127. — Wild Geranium, Geranium carolinianum . . . .135

FIG. 128. — Flowering Spurge, Euphorbia corollata 135

FIG. 129. — Bird's-Foot Violet, Viola pedata 135

FIG. 130. — Butterfly Weed, Asdepias tuberosa 135

FIG. 131. — Arrow-leaved Violet, Viola sagittata 135

FIG. 132. — Lousewort, Pedicularis canadensis 135

FIG. 133. — Wild Bergamot, Monardafistulosa 136

FIG. 134. — Blazing Star, Liatris spicata 137

FIG. 135. — Mixed Oak Association 138

FIG. 136. — Oaks of Chicago Area 139

FIG. 137. — Water Beech, Carpinus caroliniana 140

FIG. 138. — Yellow Lady's-Slipper, Cypripedium parviflorum . . 141

FIG. 139. — Hepatica, Hepatica triloba 142

FIG. 140. — May Apple, Podophyllum peltatum 142

FIG. 141. — Wild Geranium, Geranium maculalum 142

FIG. 142. — Canada Violet, Viola canadensis 142

FIG. 143. — Long-Spur Violet, V. rostrala . . . . . .142

FIG. 144. — Rattlesnake Root, Prenanthes alba 142

CHAPTER VIII

FIG. 145. — Species of Tiger Beetles . . 149

FIG. 146. — Termites or White Ants, Termes flavipes . . . .152

FIG. 147. — Sand-colored Spider, Trochosa cinerea 152

FIG. 148. — The Searcher and Fiery Hunter, Calosoma scrutator and

C. calidum 153

FIG. 149. — A Digger Wasp, Microbembex monodonta . . . .153

FIG. 150. — The Bee Fly, Exoprospa 154

FIG. 151. — Willow-Leaf Beetle, Disonycha quinqueviltata . . .154

FIG. 152. — Snout Beetle, Sphenophorus 155

FIG. 153. — Nest Holes of Bank Swallows 155

FIG. 154. — Maritime Locust, Trimerotropis maritima . . . .156
FIG. 155. — Mottled Sand Locust, Sparagemon wyomingianum . . 156
FIG. 156. — Long-horned Locust, Psinidia fenestralis . . . . 157
FIG. 157. — Lesser Migratory Locust, M elanoplus atlanis . . .157
FIG. 158. — Narrow-winged Locust, M. angustipennis . . . .157

xvin LIST OF ILLUSTRATIONS

PAGE

FIG. 159. — Sand Locust, A geneotettix arenosus 157

FIG. 1 60. — Longhorn Beetle, Monohammus scutMatus . . . .158
FIG. 161. — Metallic Wood-boring Beetle, Chalcophora liberta . .158

FIG. 162. — Chipmunk, Tamias striatus griseus 159

FIG. 163. — Ant-Lion and the Hole of the Larva 160

FIG. 164. — A Click Beetle, Lacon rectangulafis , Found beneath Cactus 161
FIG. 165. — A Leaf-eating Beetle, Prasocuris phellandrus , Found

beneath Cactus jgi

FIG. 166. — Blue Racer, Coluber constrictor 161

FIG. 167. — Puff Adder, Heterodon platirhinos 162

FIG. 1 68. — Sprinkled Locust, Chloealtis conspersa 163

FIG. 169. — Coral- winged Locust, Hippiscus tuber culatus . . .163
FIG. 170. — Straight-Lance Grasshopper, Xiphidium strictum . . 163
FIG. 171. — Sword-bearing Grasshopper, Conocephalus ensiger . .163

FIG. 172.— Six Typical Oak Galls !64

FIG. 173. — The Tree Toad, Hyla versicolor ^5

FIG. 174.— The Tree Toad, H. pickeringii T65

CHAPTER IX

FIG. 175. — Interdunal Swale of the First Type .... 168

FIG. 176. — Caddis Worm.,' Goer a jgq

FIG. 177. — Nymph of Damsel Fly, Lestes forcipatus . . . .169

FIG. 178. — Jaws of the Nymph I7o

FIG. 179. — Nymph of Dragon Fly, Celethemis eponina . . .170

FIG. 1 80,— Adult of Dragon Fly I?0

FIG. 181— The Clam, Lamps^lis luteola I7I

FIG. 182. — The Clam, Alasmodonta marginala . . . . I7I

FIG. 183. — The Clam, Anadonta grandis I^I

FIG. 1 84. — The Pike, Esox lucius l - 2

FIG. 185. — The Shiner, Notropis atherinoides J72

FIG. i86.—Chara IJ2

FIG. 187. — The Bluegill, Lepomis pallidus I73

FIG. 1 88. — Pumpkin Seed, Eupomolis gibbosus I73

FIG. 189. — Nymph of the Dragon Fly, Gomphus spicatus . . .174

FIG. 190. — Mud Minnow, Umbra limi I74

FIG. 191. — Golden Shiner, A bramis crysoleucas I7^

FIG. 192. — Chub Sucker, Erimyzon sucetta ^

FIG. 193. — Brown or Spotted Bullhead, Ameiurus nebulosus . . 176

FIG. 194. — Tadpole Cat, Schilbeodes gyrinus I76

FIG. 195. — Nymph of Damsel Fly, Ischnura •verticalis . . . .177
FIG. 196. — Buttonbush, Cephalanthus occidentalis 177

LIST OF ILLUSTRATIONS xix

PAGE

FIG. 197. — Pennsylvania Saxifrage, Saxifraga pennsylminica . .178

FIG. 198. — Sensitive Fern, Onoclea sensibilis 179

FIG. 199. — Sour Gum, Nyssa sylvatica 180

FIG. 200. — Swamp Holly, Ilex verticillata 181

FIG. 201. — Meadowsweet, Spiraea.latifolia 181

FIG. 202. — Steeplebush, S. tomentosa 181

FIG. 203. — Royal Fern, Osmunda regalis . . . . . . .182

FIG. 204. — Clayton's Fern, Osmunda Claytoniana . . . . . 182

FIG. 205. — Cinnamon Fern, Osmunda cinnamomea . . . .182

FIG. 206.— Second Type of Pond 183

FIG. 207. — Shrubby Cinquefoil, Potenlilla frulicosa .... 184

FIG. 208. — A Small Clam, Sphaerium simile 184

FIG. 209. — Nymph of A nax 184

FIG. 210. — Nymph of Leucorhinia inlacla, after Shelf ord . . . 185
FIG. 211. — Adult Libellula pulchetta, from Needham . . . . 185
FIG. 212, A and B — Aquatic Insects and Their Young . . 186, 187
FIG. 213. — Diving Spider, Dolomedes sexpunctalus .... 188

FIG. 214. — The Eft, Diemictylus viridescens 189

FIG. 215. — Garden Spider, Argiope 190

FIG. 216. — Tettix granulatus, Tettigidea later alis 190

FIG. 217. — Short-horned Locust, Tryxalis brevicornis .... 191
FIG. 218. — Short-winged Green Locust, Dichromorpha mridus . . 191
FIG. 219. — Slender-bodied Locust, Leptysma marginicottis . . .191

FIG. 220. — Hoosier Locust, Paroxya hoosieri 191

FIG. 221. — Scudder's Paroxya, P. scudderi . . . . . .191

FIG. 222. — Striped Ground Cricket, Nemobius fasciatus . . .192
FIG. 223. — Leather-colored Locust, Schistocerca alutacea . . .192
FIG. 224. — Nebraska Locust, Phaetalioles nebrascensis . , . .192
FIG. 225. — Marsh Conehead, Conocephalus palustris .... 192

FIG. 226. — A Sphagnum Bog 193

FIG. 227. — The Slender Sedge, Car ex filiformis 193

FIG. 228. — The Shore Sedge, C. riparia 193

FIG. 229. — An Orchis, Arelhusa bulbosa 194

FIG. 230. — The Bearded Orchis, Calapogon pulchellus .... 194

FIG. 231. — The Sundew, Drosera rotundifolia 195

FIG. 232. — Tickseed, Coreopsis grandiflora 195

FIG. 233. — Cottony Grass, Eriophorum gracile 195

FIG. 234. — Swamp Horsetail, Equisetum fliiviatile 195

FIG. 235. — Swamp Fern, Aspidium Thelypteris 195

FIG. 236. — Sphagnum Moss 195

FIG. 237. — Ragged Orchis, Habenaria lacera 196

XX LIST OF ILLUSTRATIONS

PAGE

FIG. 238. — Fragrant Ladies' Tresses, Spiranlhes Romanzqffiana . . 197

FIG. 239. — Leatherleaf, Chamaedaphne calyculata 199

FIG. 240. — Pitcher Plant, Sarracenia pur p urea 199

FIG. 241. — Andromeda, A ndromeda Polifolia 199

FIG. 242. — Chokeberry, Pyrus arbutifolia 199

FIG. 243. — Rush Aster, Aster junceus 199

FIG. 244. — Crested Shield Fern, Aspidium cristatum . . . .199

CHAPTER X

FIG. 245. — Tulip Tree, Leaf and Flower, Lirodendron Tulipifera . 203

FIG. 246. — White Walnut, Juglans cinerea 203

FIG. 247. — Black Walnut, /. nigra 203

FIG. 248. — Black Cherry Trunk, Prunus serolina 204

FIG. 249. — Hackberry Trunk, Celtis occidentalis, and Trunk of Beech,

Fagus grandifolia . • 204

FIG. 250. — American Elm, Ulmus americana 205

FIG. 251. — Sycamore Leaf and Fruit, Platanus occidentalis . . .205

FIG. 252. — Climax Forest Showing Stratification 206

FIG. 253. — Hard Maple Leaf and Fruit, Acer saccharum . . . 206

FIG. 254. — Flowering Dogwood, Leaf and Blossom, Cornus jlorida . 207

FIG. 255. — Twig of Witchhazel, Hamamelis virginiana .... 207

FIG. 256. — Pawpaw, Leaves, Blossom, and Fruit, Asimina triloba . 208

FIG. 257. — Leaf and Fruit of Hop Hornbeam, Ostry a Virginian a . 208

FIG. 258. — Redbud Leaf and Blossom Cluster, Cercis canadensis . 208

FIG. 259. — High Bush Cranberry, Viburnum opulus . . . . 208

FIG. 260. — Nannyberry, V. lenlago 208

FIG. 261. — Wahoo, Ewnymus atropurpureus 208

FIG. 262. — Elderberry, Sambucus canadensis 208

FIG. 263. — Strawberry Bush, Ewnymus americana .... 208

FIG. 264. — Jack-in-the-Pulpit, Arisaema Iriphyllum .... 208

FIG. 265. — Pigeon Berry, Cornus canadensis 209

FIG. 266. — Green Dragon, A risaema dracontium 210

FIG. 267. — Baneberry, Actaea alba 210

FIG. 268. — Waterleaf, Hydrophyllum virginiatium 210

FIG. 269. — Sweet Cicely, Osmorhiza Clayloni . . . . . .210

FIG. 270. — Clearweed, Pilea pumila 210

FIG. 271. — Bedstraw, Galium aparine 210

FIG. 272. — Ginseng, Panax Irifolium 211

FIG. 273. — Touch-me-not, Impatiens pallida . . . . . .212

FIG. 274. — Beech Fern, Phegopteris polypodioides 213

PIG. 275. — Maiden-Hair Fern, A diantum pedatum . . . .213
FIG. 276. — Wood Spleen wort, A splenium acrostichoides . . .213

LIST OF ILLUSTRATIONS xxi

PAGE

FIG. 277. — Pale Wood Fern, Aspidium novaboracense .... 213
FIG. 278. — Christmas Fern, Polystichium acrostichoides . . .213

FIG. 279. — Lady Fern, Asplenium Filix-femina 213

FIG. 280. — Margined Fern, Aspidium marginale 213

FIG. 281. — Florists' Fern, A. spinulosum 213

FIG. 282. — Ostrich Fern, Onoclea struthiopteris 213

FIG. 283. — Bracken Fern, Pteris aquilina 214

FIG. 284. — Species of Polygyra .' 215

FIG. 285. — Land Mollusca 216

FIG. 286. — Common Mole, Scalopus aquaticus 217

FIG. 287. — White-footed Deer Mouse, Peromycus leucopus . . . 217
FIG. 288. — The Common Slug, A griolimax campestris . . . .217
FIG. 289. — The Large Millipede, Spirobolus marginatus . . . 218
FIG. 290. — The Yellow-margined Centipede, Fontaria corrugate . . 218

FIG. 291. — The Red Centipede, Geophilus rubens 218

FIG. 292. — The Eyed Elater, Alaus oculatus 219

FIG. 293. — Blatchley's Locust, Melanoplus Uatchleyi . . . .219
FIG. 294. — The Horned Passalus and Its Larva, Passalus cornutus . 220
FIG. 295. — Several Beetles Common in Fungi, Diaper-is maculata,

Pisenus humeralis, Boletotherus bifurcus . . . .220

FIG. 296. — The Wood Frog, Rana sylvatica 220

FIG. 297. — The Pawpaw Swallowtail, Papilio ajax . . . .221

FIG. 298.— The Spicebush Swallowtail, P. troilm 221

FIG. 299. — Cicada and Larva, Cicada linnei 221

FIG. 300. — Tree Crickets of Several Species 222

FIG. 301. — Twig Pruner of Oak, Elaphidion mllosum . . . .223

FIG. 302. — A Leaf Beetle, Chalepus rubra 223

FIG. 303. — A Nut Borer, genus Balaniniis 223

FIG. 304. — Spider, Epeira gigas 225

FIG. 305. — Spider, Neocosoma arabesca 225

FIG. 306. — The Jumping Spider, Phidippus audax . . . .225
FIG. 307. — Camel Cricket, Ceuthophilus maculatus . . . .225

FIG. 308. — Rustic Borer, Xylotrechus colonus 225

FIG. 309. — Elm Borer, Saperda tridentata 225

FIG. 310. — Graphisurus fasciatus, a Beetle 225

FIG. 311. — Calloides nobilis, a Beetle 225

FIG. 312. — Molorchus bimaculatus, a Beetle 225

FIG. 313. — Flathead Apple-Tree Borer, Chrysobothris femorata . . 226

FIG. 314. — Heartwood Borer, Parandra brunea 227

FIG. 315. — Oak Borer, Eupsalis minuta 228

FIG. 316. — Beetle, Nyctobates pennsyhanica 228

FIG. 317. — Beetle, Tenebrio tenebrioides 228

xxii LIST OF ILLUSTRATIONS

PAGE

FIG. 318. — Jumping Mouse, Zaptis hudsonius 229

FIG. 319. — Gray Gopher, Citellus franklini 229

FIG. 320. — Woodchuck, Marmola monax 230

FIG. 321. — The Painted Lady, Pyrameis cardui . . . . . 230
FIG. 322. — Round-winged Katydid, A mblycorypha rotundifolia . .231
FIG. 323. — Oblong-winged Katydid, A. oblongifolia . . . .231

CHAPTER XI

FIG. 324. — Water Snails 233

FIG. 325. — Blob or Miller's Thumb, Cottus ictalops .... 234
FIG. 326. — One of the Pond Weeds, Potamogeton natans . . .235

FIG. 327. — Stir pus atrovirens 235

FIG. 328. — S. Torreyi 235

FIG. 329. — S. validus 235

FIG. 330. — Juncus balticus 235

FIG. 331. — J. tennis 235

FIG. 332. — J. canadensis 235

FlG. 333-— J- ejjusus ' 235

FlG. 334. — Eleocharis acicularis 235

FIG. 335. — The Bulrush Zone 236

FIG. 336. — Bur Reed, Sparganium eurycarpum 237

FIG. 337. — Arrowhead, Sagitlaria latifolia 237

FIG. 338. — Wild Rice, Zizania aquatica 237

FIG. 339. — The Reed, Phragmites communis 238

FIG. 340. — Sweet Flag, Acorus Calamus 238

FIG. 341. — Painted Turtle, Chrysemys marginata 239

FIG. 342. — Snapping Turtle, Chelydra serpentina 240

FIG. 343. — Bullfrog, Rana catesbeiana 240

FIG. 344. — Pickerel Frog, Rana palustris 241

FIG. 345. — Nest of Marsh Wren . . . • 242

FIG. 346. — American Bittern, Botaurus lentiginosus . . . .243
FIG. 347. — Forked-Tail Katydid, Scudderia furcata . . . .243

FIG. 348. — Texas Katydid, S. texensis ....... 243

FIG. 349. — Carex conjuncta 244

FIG. 350. — C. cristata 244

FIG. 351. — C. lupuliformis 244

FIG. 352. — C. stricta . 244

FIG. 353. — Slough Grass, Spar Una Michauxiana 244

FIG. 354. — Blue- Joint Grass, Calamagrostis canadensis . . . 244

FIG. 355. — Fowl Meadow Grass, Glyceria nervata 244

FIG. 356. — Switch Grass, Panicum irirgatum 244

FIG. 357. — Thin Grass, Agrostis perennans . . . ... .244

LIST OF ILLUSTRATIONS xxiii

PAGE

FIG. 358. — Andropogon furcatus 245

FIG. 359.— Luxuriant Grasses of Wet Prairie . . . . .245

FIG. 360. — Smartweed, Polygonum lapathifolium 246

FIG. 361. — Chickweed, Ceraslium vulgatum 247

FIG. 362. — Three Species of Cardamine: C. Douglassii, C. bulbosa,

C. Pennsylvania 247

FIG. 363. — Mermaid Weed, Proserpinaca palustris .... 247

FIG. 364. — Skull Gap, Scutdlaria galericulata 247

FIG. 365. — Cardinal Flower, Lobelia cardinalis 248

FIG. 366. — Shooting Star, Dodecatheon meadia 249

FIG. 367. — Wild Hyacinth, Camassia esculenta 249

FIG. 368. — Wild Onion, Allium cernuum . . . . . . .250

FIG. 369. — Culver's Root, Veronica virginica 250

FIG. 370. — Golden Old Man, Zizia aurea 250

FIG. 371. — Brown-eyed Susans, Rudbeckia'hirla .'. . . .251

FIG. 372. — Coneflower, Brauneria pur pur ea 251

FIG. 373. — Rosinweed, Silphium terebinthinaceum 252

FIG. 374. — Dropseed Grass, Sporobolus cryptandrus . . . .252

FIG. 375. — Prairie Phlox, Phlox pilosa 252

FIG. 376. — Rattlesnake Master, Eryngium yuccifolium . . .253
FIG. 377. — Prairie Clover, Petalostemum purpureum . . . .254

FIG. 378. — Lead Plant, Amorpha canescens 254

FIG. 379. — Chimney of Burrowing Crayfish 254

FIG. 380. — Striped Gopher, Citellus tridecemlineatus . . . .255

FIG. 381. — Pocket Gopher, Geomys bursarius . ... . . . 255

FIG. 382. — Pennsylvania Meadow Mouse, Microtus pennsyhanicus . 256
f a, The Two-lined Locust, Melanoplus bimttatus; b, Red-
legged Locust, M. femur-rubrum; c, The Short-winged
Grasshopper, Xiphidium brevipenne; d, The Meadow
Grasshopper, Orchelmium vulgar e; e, The Sprinkled
Grasshopper, Chlocaltis eonspersa; f. The Green-
legged Locust, Melanoplus viridipes

FIG. 384. — Sawflies and Larvae 257

FIG. 385. — The Cutworm and Its Moth, Feltia subgothica . . . 257
FIG. 386. — The Salt-Marsh Caterpillar, Estigmena acraea . . . 257
FIG. 387. — The Yellow Bear Caterpillar, and Moth, Diacrisia virginica 257
FIG. 388. — The Woolly Bear Caterpillar, and Moth, Isia Isabella . 258

CHAPTER XII

FIG. 389. — Bluff with Xerophytic Vegetation 260

FIG. 390. — The Common Scouring Rush, Equisetum hyemale . .261

FIG. 383.

256

xxiv LIST OF ILLUSTRATIONS

PAGE

FIG. 391. — Clay-Bank Spider, Pardosa lapidicina .... 261

FIG. 392. — Mouth of'Ravine 262

FIG. 393. — Ravine with Vegetation on Sides 263

FIG. 394. — Sarsaparilla, Aralia nudicaulis 264

FIG. 395. — Fragile Fern, Cystopteris fragilis 264

FIG. 396.— Bladder Fern, C. bulbifera 265

FIG. 307- — A Common Liverwort, Marchantia polymorpha . . .265

FIG. 39&.—-Selaginella 265

FIG. 399. — Meadow Rue, Thalictrum dasycarpum 266

FIG. 400. — Boneset, Eupatorium perfoliatum 266

FIG. 401. — Queen Anne's Lace, Wild Carrot, Daucus Carota . . 266
FIG. 402. — Leaf and Fruit of Wild Parsnip, Pastinaca saliva . . 266
FIG. 403. — Leaf .of Angelica, Angelica atropurpurea . . . .266

FIG. 404. — Alumroot, Heuchera americana 266

FIG. 405. — Whitlow grass, Draba caroliniana 266

FIG. 406. — Rattlebox, Crotalaria sagittalis 266

FIG. 407. — Walking Fern, Camptosorus rhizophyllus .... 266
FIG. 408. — Wild Hydrangea, Hydrangea arborescens .... 267

FIG. 409. — Rock Polypody, Polypodium vulgare 268

FIG. 410. — Toad Bug, Gclastocoris oculatus 269

FIG. 411. — Hooded Grouse Locust, Paratettix cucullatus . . . 269

FIG. 412. — Spotted Sandpiper 270

FIG. 413. — Long-bodied Spider, Tetragnatha labor iosa . . . .270
FIG. 414. — Kentucky Coffee Tree, Gymnodadus dioica . . .271
FIG. 415. — Vines Draped on Trees in River Bottom . . . .272

FIG. 416. — Bladdernut, Staphylea trifolia 273

FIG. 417. — Prickly Ash, Zanthoxylum americanum . . . 273

FIG. 418. — Moonseed, Menispermum canadense . . . . 273

FIG. 419. — Smilax, Smilax hispida 273

FIG. 420. — Skunk Cabbage, Sympiocarpus foetidus . . . .273

FIG. 421. — Cheveril, Chaerophyllum procumbens 273

FIG. 422. — Fringed Loosestrife, Steironema ciliatum . . . . 273

FIG. 423. — Honewort, Cryptotaenia canaden.sis 273

FIG. 424. — Cow Parsnip, Hieracleum lanaium 273

FIG. 425. — Short-tailed Shrew, Blarina brevicaudata .... 274

CHAPTER XIII

FIG. 426. — Ny mphs of Anax, A eschna, and Boyeria, dragon flies . 281

FIG. 427. — Horned Dace, Semotilus atromaculatus 281

FIG. 428. — Red-bellied Dace, Chrosomus erythrogaster .... 282

Fig. 429. — Blunt-nosed Minnow, Pimephales notatus .... 282

LIST OF ILLUSTRATIONS xxv

PAGE

FIG. 430. — Johnny Darter, Boleosoma nigrum 282

FIG. 431. — Rainbow Darter, Etlieostoma coeruleum .... 283

FIG. 432. — Common Sucker, Catostomus commersonii .... 283

FIG. 433. — Stone Roller, Campostoma anomalum 283

FIG. 434. — Top Minnow, Fundulus dispar 284

FIG. 435. — Hog Sucker, Catostomus nigr leans 284

FIG. 436. — Straw-colored Minnow, Notropis blennius .... 285

FIG. 437. — Rock Bass, Ambloplites rupesiris 285

FIG. 438. — Black Crappie, Pomoxis sparoides 285

FIG. 439. — Sucker-mouthed Minnow, PhenacoUus mirabilis . . 286

FIG. 440. — Fan -tailed Darter, Etheostoma flabellare .... 286

FIG. 441. — Black-sided Darter, Hadropterus aspro .... 286

FIG. 442. — Sharp-headed Darter, Hadropterus phoxocephalus . . 287
FIG. 443.— Net Building Caddis Fly, Hydropsyche . . . .288

FIG. 444. — Caddis-Fly Larva, Helicopsyche 288

FIG. 445. — Water Penny, Larva of Psephenus lecontei . . • . . 288

FIG. 446. — Brook Beetle, Psephenus lecontei 288

FIG. 447. — A Common Rotifer 288

FIG. 448. — The Lower Galien River — Plant Zonation in Foreground . 20)0

CHAPTER XIV

FIG. 449. — Map of Potato-Beetle Invasion 299

FIG. 450. — Map of Cotton-Boll Weevil 301

FIG. 451. — Map of Tree Distribution 302

FIG. 452. — Map of Chicago Localities 311

CHAPTER I
THE CHANGING FACE OF NATURE

| HICAGO is the center of a region of quiet
but varied beauty. He who limits his
excursions to the city parks or the im-
mediate vicinity of the city sees only a
monotonously level plain, but to him
who wanders along the North Shore,
explores the Dunes, or rambles over the
wooded hills of the nearby moraine
country there are presented bits of landscape that charm even the
Casual observer with their wealth of form and color. The encir-
cling horizon line shrouded in the shimmering haze of the lake or
broken by the billowy hills, the nearby woodlands, the cloud
shadows that"pia.V among them, the cleared land checkered by
its varied harvests or 'dotted with grazing cattle, the brook
playing hide and seek among"tfcevtangled shrubs and ferns, the
bird song whistled from the bough tip^~all are sources of exqui-
site pleasure. Poet and painter fairly astotl^d us with the revela-
tion of beauty which they, with fine sensitiveness-, perceive in
even so commonplace an outlook. Science too isv& reve'aler. It
adds a third dimension to the landscape; it gives depth. It
delves below the surface to the foundation. It gives the per-
spective of time. To the thoughtful man the outstretched view
is not alone a beautiful prospect ; it is a voice from the past and
speaks of history as eventful as do the care-wrought furrows of
the human face.

Many agencies of land formation, disintegration, and alter-
ation have been at work in times past to produce the present
features of this region, and most of them are still at work chan-
ging its appearance slowly but surely. Go out along the shore

2 A NATURALIST IN THE GREAT LAKES REGION

where high clay bluffs stand at the water's edge, as at Fort
Sheridan or Lakeside, and see, during a storm, the pounding
waves gnawing at their bases. As they are undermined the
unsupported upper portions slide down, carrying the vegetation,
even the trees, the soil, and contained bowlders into the insatiable
maw of the lake (Fig. i), all to be ground up by the wave action
and deposited in time out in quiet water as beds of sand or clay,

FIG. i. — Clay.'oluffs near Winnetka on shore of Lake Michigan, showing
erosion. The bfise is torn up by waves and the whole unsupported side is moving
down, as sh()wn by shrubs and trees in various stages of transit from top to bottom.

or transported and thrown up on shore in sandy or muddy
beaches. This process of wave erosion and deposition goes on
ceaselessly and has been going on for ages, not only on the shores
of Lake Michigan, but wherever land masses are exposed to the
attacks of the waves. Serried ranks of billows (Fig. 2) armed
with rock fragments hurl themselves in relentless fury on the
slow-retreating land. «The softer portions of the shores, even
the rock-bound shores, in the age-long battle are worn away
rapidly and form deep bays. The more resistant sections stand

THE CHANGING FACE OF NATURE

out as bold headlands, only in time to also yield to the continu-
ous charges (Frontispiece) . When it is realized that this battle-
line of sea and land is 175,000 miles long and that in a storm
the waves strike with the force of several tons per square foot
and bombard the shore with rock fragments that weigh up to a ton,
it is evident that the oceans and the great lakes have been and
still are mighty agents of
erosion, in time destroying
even the most resistant land
masses.

Running water in rivu-
lets, creeks, and rivers is
another powerful agent of
land erosion. Follow any
stream and you will not have
traveled far before you will
find some place where it is
cutting its banks (Fig. 3).
Thorn Creek, near Glenwood,
Salt Creek, one-half mile up-
stream from Brookfield, the
Desplaines at Lockport, and
Fraction Run, above Delwood
Park, give excellent demon-
strations of the cutting power of a stream. In newly upheaved
sections, like mountain areas, the streams are torrents (Fig. 4)
that wear down their narrow valleys, cutting deeply and
rapidly, both by virtue of their terrific force and by the
angular rock fragments they carry that act as graving tools.
When the stream has cut down to somewhere near the level of the
body of water into which it flows, it runs more slowly, meanders
back and forth across its valley, attacking and undermining the
bounding hills, thus gradually widening its influence. Then its
valley changes from the deep a-1 •'.. narrow canyon of a young
stream to the broader basin of an old river (Fig. 448) . A river

FIG. 2. — Ranks of billows

4 A NATURALIST IN THE GREAT LAKES REGION

valley, then, is largely the work of the stream it contains. The
whole valley, limiting hills, meanders, flood plain, cuttings, and
fills, may be seen in perfection in many of the smaller streams,
such as Salt Creek near Brookfield, Thorn Creek near Thornton,
Pettibone Creek at North Chicago.

FIG. 3. — A stream cutting its banks. Photo by Fuller

The Chicago region shows many stages in the formation of
the valley. Where the lake shore is high, as it is from Glencoe
northward or on the eastern shore from New Buffalo north,
the melting snows and spring rains find their way to the shore
along irregular depressions, then plunge down the steep bank in
headlong turmoil, cutting rapidly a steep-sided ravine. Gradu-
ally the stream eats its way back toward the relatively level
meadowland. You may follow down its course from where the

THE CHANGING FACE OF NATURE

FIG. 4. — A mountain torrent. Note the valley is steep-sided

FIG. 5. — The beginnings of a ravine

6 A NATURALIST IN THE GREAT LAKES REGION

little runnel is starting out from some grassy depression (Fig. 5) ,
pass the fairly level upper stretches where it meanders, cutting
an irregular course as it grows by minor tributaries, enter the
V-shaped valley (Fig. 6) in which it is flowing with irresistible
vigor straight for its goal — a valley that deepens and widens with
every advance — and finally arrive where for a few rods it may
proceed a placid little river just before it enters the lake.

FIG. 6.— A later stage, the deep V-shaped ravine

Valleys which exemplify similar stages of development are
seen where the stream cuts its way down through the rock, only
in this case the valley sides are likely to be very precipitous if
the cutting is at all recent, since it takes much longer for the
forces of erosion to crumble down the valley sides. No better
illustration of such valleys cut out of the rock can be found than
those exhibited in the neighborhood of Starved Rock on the
Illinois River, Oregon on the Rock River, and the Dalles of
the Wisconsin (Fig. 7), all beauty spots easily accessible from
Chicago. Standing on the. top of Starved Rock, the valley
lies spread out before your eye, bounded on either side by

THE CHANGING FACE OF NATURE

FIG. 7.— The Dalles of the Wisconsin. The trees on the rocks at right are
white pines, Pinus strobus. The rock is St. Peter's sandstone.

8 A NATURALIST IN THE GREAT LAKES REGION

precipitous hills (Fig. 8). The rock of the region is a rather soft
sandstone and the river has cut its way deeply into this, scouring
out its valley as it shifts from side to side in its meandering way.
The surrounding country is slightly rolling farm land, giving
the impression of a level plain. It is startling to walk or drive
across this country and then suddenly find yourself on the brink
of a deep valley with precipitous sides, 100 feet sheer, and look

FIG. 8. — The Valley of the Illinois River, looking from Starved Rock to the
bluffs on the opposite side.

across to the opposite side, 3 or 4 miles away. The tributary
streams flowing to the river from the plain plunge down in foam-
ing falls which eat their way back through the sandstone, form-
ing narrow chasms that end abruptly at their head in a rock wall
down which, when the stream is full, the water thunders (Fig. 9).
There is a small but very interesting rock canyon cut in the
limestone on the south side of the valley of the "Calumet
Feeder" i mile east of "Sag" Station on the Chicago & Joliet
Interurban (Fig. 393). Fraction Run cuts through the limestone

THE CHANGING FACE OF NATURE

FIG. 9. — A narrow rock ravine ending in a waterfall. Deer Park Canyon near
Starved Rock. Photo by O. W. Caldwell.

FIG. 10. — In the Canadian Rockies, a glacier made by the confluence of
several smaller glaciers emanating from the snow fields on the mountains in the
background.

io A NATURALIST IN THE GREAT LAKES REGION

and makes some short canyons near Joliet, one of which is included
in Delwood Park. Sugar Creek has cut a gorge nearly fifteen
feet deep in the suburbs of Joliet, crossed by the Chicago &
Alton main-line tracks going south.

Water may be quite as efficient an agent of land destruction
when running underground as it is when on the surface, particu-
larly in limestone regions. Percolating through soil filled more

FIG. ii. — Clay pinnacles, erosion remnants, near Lakeside, Mich. Note
white pine, Pinus strobus, and juniper, Juniperus communis, on crest. Inset,
details of other nearby pinnacles.

or less with disintegrating organic matter that liberates CO2 the
water becomes charged with this gas. In such a condition its
power to dissolve limestone is relatively great. Following some
crevice, joint, or bedding-plane, the water excavates the rock,
carries it away in solution, and underground caverns are formed,
at times of great extent and wonderful beauty. While none are to
be found in the immediate Chicago region except small ones
discovered as the limestone is quarried, yet we are near enough

THE CHANGING FACE OF NATURE n

to the caverns of southern Indiana and of Kentucky so that their
fame is familiar.

In frigid regions the rivers, which in our latitude rise in lakes
and pursue their lively way down the outletting valleys, may be
replaced by streams of ice (Fig. 10) which take their origin in
the great snow fields of the mountain basins and plow their
way down the valleys slowly but with irresistible force. The
loose soil is pushed before them; the solid rock is worn away by
the terrific grinding force of the ice, hundreds of feet deep, hold-
ing in its grip the fragments of rock that abrade like giant's
sandpaper in the hands of Hercules. Once upon a time, as will
be detailed later, the Chicago region was covered by the glacial
ice cap that overspread nearly all of northern North America.
The surface of the bed rock here is planed off, covered with
scratches and parallel grooves made by the moving ice sheet
(see Fig. 41), and the earth that overlays the rock is full of
bowlders of granite, greenstone, diorite, and other foreign rock
transported from the ledges far to our north, worn smooth and
scored with striations in their progress (see Fig. 40).

The pelting rain is no insignificant agent of erosion. Each
drop seems a puny thing, but multiply them endlessly and let
them act age after age and they do wear away the land. The
wash on steep hillsides is very apparent. The water runnels
during the heavy rains cut steep-sided valleys, between which
there stand up sharp-edged clay ridges and pinnacles (Fig. u).
These serve to call attention strikingly to an agency that works
so unobstrusively it might easily go without notice. Such
pinnacles in clay, the result of rains and spring freshets, are seen
along the lake shore as, for instance, near Lakeside where the
clay moraine comes to the lake. In a similar way the rock itself
is worn away by the pelting rain, and pinnacles are left standing
mute testimony of the former height of all the land, now largely
gone through erosion.

The heave of water in the rock crevices when it transforms
to ice is another destructive action of water. Man realizes its

12 A NATURALIST IN THE GREAT LAKES REGION

might when it fragments the cement sidewalk or tears the
plaster from the exterior of a house. But it is quite as powerful
when it operates on the rock of a cliff or the disintegrating
bowlder. At the base of a rock cliff is often found a pile of rock
debris, the talus, the accumulation of the incessant disintegra-
tion of the rock above (Fig. 12).

The moisture-laden atmosphere is always busy producing
destructive changes on the exposed rocks. Crack open any

FIG. 12.— A talus at foot of cliff and outwash from, the hills

field bowlder and you will see a layer of weathered material
on its outer portion that crumbles readily. The rock piles,
excavated in mining or quarrying, show nicely the results of
this weathering. The great angular blocks that were dumped a
decade or more ago are crumbling into heaps of rock fragments,
many of them sufficiently disintegrated to make coarse soil
where weeds and some trees are beginning to root. This process
of the transformation of blocks of rock into soil may readily be
seen on the dumps of the local quarries or along the line of the

THE CHANGING FACE OF NATURE 13

Chicago Drainage Canal, conveniently reached at Willow Springs,
or on the rock dumps of the coal mines near Braiderwood, on the
Chicago & Alton Railroad.

Wind must be regarded as an agent of land destruction, and
a transformer of the landscape. One needs only spend a day in
the Dunes to realize its efficiency, if that day be a windy one.
There is visible evidence that the wind is moving the sand; the

FIG. 13.— A moving dune invading a swamp and burying pines and junipers
on its margin.

air is full of it. Close to the ground it is drifting along and
strikes one's hand or face, when lying down, with stinging force.
The hills of sand are moving inland (Fig. 13) covering up the
forests, invading the streams, and turning them from their
courses. The movement of the great dunes, hills of sand
hundreds of feet high and thousands of feet long that sweep
along like snow drifts, is quite rapid. The steep front may
advance several feet a year, by actual measurement from stakes

14 A NATURALIST IN THE GREAT LAKES REGION

set at regular intervals to serve as fixed standards. Forests are
covered, killed, and uncovered.

When on the old dunes, covered now with woods, a great
tree falls and so exposes the loose sand again to the wind, or when
the changing contour of the land sets the wind currents against
some new and poorly protected spot, a great hole is blown out
of the land and the sand is carried inland to be deposited in some
new spot as a moving dune. These blow-outs (Fig. 14) are

FIG. 14.— A blow-out in the dunes

characteristic features, marked with the wreckage of former
forests.

As has been suggested above, these agents that wear away
the land are also agencies of land formation. The ocean, whose
waves pound the shore debris into sand and still finer mud,
carries this material by its undertow and currents out into the
quieter portions and drops it offshore in sand bars and mud
banks. These deposits accumulate to great depths, hundreds
and even thousands of feet in thickness. The rivers bring down
their tons of material to add to the accumulation. Thus the

THE CHANGING FACE OF NATURE 15

Mississippi discharges annually into the Gulf of Mexico as much
debris worn away from the land in its course as would a thousand
cargo, ships each carrying ten thousand tons. Dip a pailful of
water from the Des Plaines at Riverside when the spring freshet
is on or from the Illinois at Starved Rock; let the suspended
mud settle, collect it, dry it, and then weigh it, and you will be
surprised to see how much soil one cubic foot of water is carrying.
Measure the width of the stream, its average depth, and its
rate of flow by getting the distance a floating chip goes in five
or ten minutes; calculate from this data the volume of water
that passes in an hour's time, then the weight of sediment it
carries, and 'it foots up an incredible amount. All the streams
that flow into Lake Michigan are ceaselessly filling in the lake.
The wave action along its shores tends to make it wider, but also
shallower since the eroded material is carried out to settle in the
quieter, deeper portions. The constant necessity of dredging out
harbors and their approaches is readily understood when one
appreciates this incessant deposition.

The ultimate fate of a lake or pond is to be transformed into
land as it is filled up by the material washed into it from the
surrounding hills and by accumulating plant debris (Fig. 15).
Becoming shallower, water weeds and rushes grow farther and
farther out in it until it transforms into a marsh. Even then the
filling does not cease, for each year's crop of marsh grass and
water weeds piles up and, only partly decomposing, affords the
following year a slightly higher footing for the next crop. Wolf
Lake and Lake Calumet are both shallow and filling rapidly.
Already many of their bays are marsh rather than pond areas.
Indeed, along the margins of these lakes it is very easy to trace
all stages from pond to prairie land.

The river builds land instead of eroding it wherever its
current is checked. The carrying power of a stream depends
on its rate of flow and its volume. The swift current can keep
coarse material moving that is deposited when the movement is
sluggish. When the stream flows into pond or lake, its rate of

1 6 A NATURALIST IN THE GREAT LAKES REGION

•hE-: ViT ' 1

FlG. 15.— A filling pond, with water lilies and cat-tails growing in profusion

FIG. 16. — A flood plain where deposits occur during overflow. At the right
the bluff marks the edge of the flood plain.

THE CHANGING FACE OF NATURE 17

flow is lessened, in consequence of which a bar is often formed at
its mouth or in larger streams, a delta. Deposits are laid down
below an obstruction like a bowlder in midstream. While the
stream cuts on the outside of a wide curve where its flow is rapid,
it deposits on the inside where it is slow. Often the spring
freshets raise the height of a river so it overflows its usual channel.
The current beyond this is relatively sluggish so that over the
flood plain there is formed a deposit of mud washed from the
hills upstream (Fig. 16). This flood plain is frequently enriched
by this annual addition of humus, so that river bottoms proverbi-
ally have good soil.

The accumulated soil and rock debris swept from a continent
by the various agencies of erosion and transportation deposited
in quiet bays or ocean deeps gradually transforms to rock again,
so new lands are formed as old ones are destroyed. When exten-
sive deposits accumulate offshore or in the deltas of great rivers,
the very weight of material seems to cause the earth's crust to
gradually sink. Thus the deposits may continue to accumulate,
as is apparently the case in the Gulf of Mexico, until they become
very thick. Then the lowe.r mud layers, pressed upon by the
thousands of feet of overlying layers, baked by the heat of the
interior, since they are ever sinking farther from the surface,
are transformed into rock in a way analogous to the manner in
which we make brick or artificial stone, by compressing, then
heating the mud or clay. So sedimentary rocks have formed,
probably are forming in our Great Lakes now. Certainly they
have so formed here in the Chicago region, for our dominant
bedrock, the limestone, is of sedimentary origin.

Movements of the earth's crust often upheave these beds of
mud transformed to rock, so adding to the surface of the land.
The outer crust of the earth is relatively cool, the inner portion
of the earth still exceedingly hot. Like any hot body it gradually
cools, and cooling shrinks; so it tends to shrink away from the
already cooled crust. This, of course, can never actually happen ,
for the heavy crust crumples down on to the shrinking central

i8

A NATURALIST IN THE GREAT LAKES REGION

portion .being thrown into f6lds, some of which thrust the rock
layers up, some down (Fig. 17). These changes in level of the
earth's crust sometimes are so sudden as to cause an earthquake,
but usually they are so gradual as to be imperceptible except as
comparisons are made at long intervals. The northern shores of
Lake Michigan are now rising — have risen on the west side of
the lake two feet or so in a generation. We know that the lime-
stone that makes up the bedrock of the Chicago region, now

FIG. 17. — Up-arched rock strata

dry land, was formed under the surface of the ocean, for
it contains fossil remains of animals and plants, shellfish, and
seaweed that live only in the sea. We shall see evidence of
many changes in level in our region.

Along the Atlantic Coast there is evidence of a sinking shore.
Stump lands along the coast are now completely under water.
The Hudson River Valley is shown by soundings to continue
well out to sea, its lower end having been "drowned" as the
land sank there. Along the western coast of South America
coral reefs are found well up on the sides of the mountains.

THE CHANGING FACE OF NATURE

19

FIG. 18. — The edge of an old lava outflow, now basalt, covering a wide area

FIG. 19. — Glacial moraine in the foreground deposited by the glacier, right
and rear.

20 A NATURALIST IN THE GREAT LAKES REGION

Evidently they must have formed below sea-level, and the
mountains have been reared since then.

Volcanoes are another agency of land formation. The lava
welling from their craters or from cracks in the earth pours out
in great sheets (Fig. 18) while molten, only to harden as it
cools into beds of rock. Fortunately for our peace of mind no
volcanoes exist in the Chicago area, though we do have lavas,
like the granite and greenstone glacial bowlders that have been
transported by the ice from the old lava beds to the north of us
into our region.

The glacier builds as well as destroys. The ice mass incorpor-
ates into itself the rock fragments torn from its bed and sides, so
the onward moving river of ice is loaded with debris and abraded
material. At some place it encounters a temperature sufficiently
high to melt it as rapidly as it pushes forward. Here it must
drop its load of rock powder and rock fragments and so it
forms a great pile along its front, a terminal moraine (Fig. 19).
Streams of water made by the melting ice pour out of gaps in the
moraine on to the country beyond, carrying gravel and sand that
are deposited in great fans or along the valley, if the outwashing
stream follows such, in elongated heaps or valley trains. These
and other forms of deposit characteristic of the glacier are found
about Chicago as will appear in a later chapter.

CHAPTER II
THE WORLD IN THE MAKING

]HE world passed through a long period
of development before there were any
oceans or rivers or atmosphere upon it to
serve as agents of erosion or deposition.
The earth on which we live is one of
several similar bodies called planets that
move about the sun. These planets, in
order from the sun outward, are Mercury,
Venus, Earth, Mars, Jupiter, Saturn, Uranus, and Neptune.
Around many of these planets as centers there are other smaller
bodies known as moons. The earth has one attendant moon,
Jupiter four, Saturn ten. Planets and moons appear bright when
seen from the earth, shining by the reflected light of the sun. The
planets look like stars to the naked eye ; the ones near our earth are
very bright and are familiar as evening and morning stars. Our
sun, on the other hand, shines because its substance is so intensely
hot that it is perpetually emitting light. It is a true star and not a
very large one either, but it is so near our earth, comparatively
speaking, that its light and heat seem much greater to us than that
of much larger suns or stars that are very far away. The diam-
eter of one of the stars in the constellation Orion, Betelgeuse by
name, recently measured by a newly devised instrument, is some
three hundred times that of the sun. Sun and planets, moons,
and some still smaller bodies that revolve about the sun together
make up our solar system. Probably the other stars are also
centers of planetary systems.

The eye unaided counts four or five thousand stars, but the
telescope enables us to locate hundreds of thousands, and each
new telescope more powerful than its predecessors adds to the

22 A NATURALIST IN THE GREAT LAKES REGION

number. These stars are themselves not fixed but are moving
through space with terrific speed. Our sun, carrying the other
bodies of the solar system along with it, is swinging along in
its orbit at the rate of some twelve miles per second, but
neither the size of its orbits nor its center has as yet been
determined.

What a tremendous tangle of pathways is woven by these
onrushing suns, their circling planets, and the moons that move
about them. The criss-crossing railroads of our country present
a simple maze in comparison. What a splendid opportunity for
an occasional smash-up if two of the suns or two of the yet more
numerous dark bodies should dispute with each other the right
of way at some crossing of their pathways. Astronomers tell
us that this sort of thing occasionally happens, resulting in the
blazing out of a new star as two of the dark bodies rush head-
long together, generating thereby enough heat to change their
substance into a cloud of incandescent material.

Even more frequently two bodies will come close enough
together as they rush by each other to disrupt each other, each
being torn more or less to pieces by opposing forces, the momen-
tum of its own precipitate motion in its pathway, and the attrac-
tion of the other body. It is from some such wreckage that our
solar system is supposed to have originated. The largest
remaining fragment or coterie of fragments dominated the rest
and became the nucleus of reorganization, the central sun.
About it, as a resultant of their original impetus and the force
of mutual attraction, the smaller fragments revolved, drawing in
turn about them the still smaller ones.

Our earth began, then, as a knot of dense material in the
cloud of fragmented material. By its attraction it drew to
itself the smaller bits about it and they moved toward it with
increasing momentum, finally smashing down on to its surface.
Gradually the earth nucleus grew as it accumulated these tiny
revolving bodies, the planetesimals, whose pathways brought
them within reach of its quite powerful attraction.

TEE WORLD IN THE MAKING 23

Naturally the great central mass, our sun, grew even more
rapidly, for its pull was in proportion to its mass, so that it
reached out in its might to draw to itself many times the
number of planetesimals that the relatively small earth could
reach.

This process has been going on for long ages and still goes on.
The earth comes near some small mass moving in its orbit and
by its tremendous gravity pulls it toward itself. It rushes
toward the earth, passes through the outer air with such ve-
locity that the friction heats it intensely; it continues to fall a
burning mass and usually is consumed, but at times may reach
the earth's surface. These bodies we call meteors or, improperly,
falling stars ; if a star should hit the earth we would not live to tell
the tale. H. A. Newton estimates from his careful observations
that sixteen millions of these meteorites enter our atmosphere
every twenty-four hours. According to William H. Pickering
they add over one hundred tons to the earth each year. "By
far the most of them are so minute that they are consumed before
they reach the ground, though about one thousand do that every
year, some of them of considerable size." The meteorite that
Peary brought down from the North now in the American
Museum of Natural History, New York, weighs more than thirty-
seven tons. There have probably been much larger ones.

Not far from Flagstaff, Arizona, is a remarkable crater-like depression
[Fig. 20]. The rim of it, rising about 140 feet above the plain, can be seen
from the railroad, passing Canon Diablo. The depression has a diameter
of about three-quarters of a mile, and the bottom is 500 feet below the top
of the rim, 350 feet below the surface of the plain. No one can look upon
this remarkable phenomenon without thinking of the craters of the moon.
But there are no signs of volcanic action ever having taken place in this
region; the thing is out of the question. The rim piled around the crater
has not come from the interior of the earth, but is composed of sandstone,
which in some way has been lifted above the plain. Some of the great
masses of this sandstone have apparently been highly heated and crystal-
lized, but most of the rock has been crushed and shattered. The whole
neighborhood is sown with meteors.

A NATURALIST IN THE GREAT LAKES REGION

FIG. 20. — Portion of so-called "crater" of Canon Diablo, probably made by
the falling of a great meteorite.

FIG. 21. — A spiral nebula with centers of condensation, the great central one
giving rise to a sun, the others to planets and satellites, Photo by Mount
Wilson Observatory,

THE WORLD IN THE MAKING 25

Without much question the depression and surrounding rim
mark the spot where some huge meteoric mass has plunged into
the earth. Lunar "craters" likely have had a similar origin.

So according to the planetesimal hypothesis our earth can
trace her history back to the time when she was one of the larger
knots of matter in the arm of a spiral nebula (Fig. 21). Because
of the original size of this knot and the abundant meteoric
material her changing orbit brought her into, she grew apace as
falling planetesimals were added to her bulk, and now she is
the fifth largest of the planets in our solar system. Jupiter, the
largest, is more than thirteen hundred times the size of our earth.
Saturn, Neptune, and Uranus are also larger. Venus, Mars, and
Mercury are smaller.

As the earth thus grew in size it also became hot. The
succession of blows delivered by the hail of planetesimals gen-
erated heat, as the anvil becomes hot under repeated hammer
strokes or a nailhead is heated when the nail is being driven.into
hard wood. This heat was superficial and quickly radiated.
The central portion of the earth was, however, constantly being
pressed upon by the overlying accumulating mass. As the earth
grew constantly by accession the central portion was condensed
more and more. We are all familiar with the fact that heat
makes things expand. The mercury in the thermometer bulb
expands more than the glass and so rises in the tube with
increased heat. The opposite of this is also true : as substances
condense heat is liberated; so the earth's interior became heated.
The condensation of the central mass also caused molecule to
rub against molecule as crushing went on and so added to the
central heat. The pressure was so great near the center that
the rock material could not actually melt. But nearer the
surface, especially where up-arching of the crust relieved the
pressure temporarily, the rock material melted, oozed up toward
the surface, infiltrated between the piled-up chunks and dust,
cementing these into a solid mass as the molten material cooled.
Thus formed, likely, the early igneous rocks.

26

A NATURALIST IN THE GREAT LAKES REGION

If we should make arn ideal section of the earth at this early
stage (Fig. 22) the surface layer would be very irregular, due to
the indiscriminate infalling of planetesimals. The next zone
would be very porous, similar to the contents of a basket filled
with large potatoes, only the fragments would be vastly larger,

more or less cemented
with lava. The zone
below would be less
porous, as the planet-
esimal matter would be
pressed together by the
weight of the zone on
top of it. The central
core of the planet would
be very compact, due to
the pressure of the zones
above it. The diagram
shows the later rock
layers on the outside of
this early earth.

Meanwhile the young
earth, growing, reached
a stage when it doubtless
could hold the begin-
nings of an atmosphere.
As the earth's gravity
gradually increased it
would first be able to
hold the gases that are heaviest and least volatile. Carbon
dioxide is the heaviest of all the gases that make up our atmos-
phere. Oxygen is next in weight; then nitrogen, water vapor,
and hydrogen follow in succession. The earth is still not large
enough to hold much hydrogen.

When the earth had reached such a size as enabled it to hold
water vapor the atmosphere was piled high with clouds. Rains

FIG. 22. — Diagrammatic section of the earth

THE WORLD IN THE MAKING 27

poured upon the surface only to evaporate promptly, it was so
hot. Gradually the surface cooled sufficiently so water could
remain. Then the little drops of water congregated in the
spaces between the rocks in the upper zone. Gradually these
cracks were filled with water and the water overflowed and
formed little pools. The pools grew into lakes, and the lakes
joined each other and formed oceans.

The torrential rains washed the rock not covered with water
and formed rivers that carried the sediment down and deposited
it on the rocks under the oceans. This continued long ages.
In this way the ocean floors had the weight of the waters upon
them and the added weight of the deposited material. This
made them sink, deepening the ocean basins and pushing up the
land masses, making the continental platforms higher.

Now, no sooner were the continental areas raised above the
ocean level than all the agencies of erosion were turned loose
upon them. The waves beat upon the land, the rain pounded
it, the brooks and rivers furrowed it, underground waters honey-
combed it, in time snownelds thrust out huge ice sheets to grind
down the hills and deepen the valleys, frost shattered the rock
cliffs, the gases of the air united with the rocks to alter them into
soft materials easily eroded, earthquakes rent the land, the
sand-laden winds, the chemical action of organisms growing on
the rocks — these all aided in the rock disintegration and soil
formation and prepared for the transportation of materials by
these same agencies to lower levels and finally to the lakes and
seas.

This process of transportation was as incessant as erosion.
Ponds and lakes constantly filled up with the wash from the
uplands. Rivers carried immense loads of sediment into the
oceans. The United States Geological Survey estimates that
the material washed from the surface of this country and carried
off by the rivers annually amounts to over one-quarter billion
tons. And so the material that was originally rock and had
been eroded, transported, and deposited began to form rock

28 A NATURALIST IN THE GREAT LAKES REGION

again. The deeper layers of those vast accumulations of sedi-
ment in ocean deeps, in inland seas, and great bays were under
the terrific pressure of the overlying layers and fathoms of
ocean waters. They became intensely heated, for they were far
enough below the surface to feel the heat of the earth's interior,
retained by the blanket of overlying layers. So they were trans-
formed into rock.

These beds raised the temperature of the older underlying
rocks almost to the point of fusion, establishing a line of weak-
ness here so that as the crust movements, due to unequal shrink-
age, occurred these areas of weakness were readily upheaved, the
sedimentary rock strata were arched, sometimes crumpled, and
thrown up above the sea.

Similarly all over the earth the sedimentary rocks, formed in
successive geological ages, have been upheaved and occasionally
exposed to our inspection. These rocks often contain fossils,
the remains of animals, and plants that lived in past geological
times. Such animals and plants living in the water or washed
from the land into the streams possibly by spring freshets were
carried seaward and deposited with other debris, with sand and
silt in the great mud banks in lakes and oceans. These, by the
process outlined above, were changed to stone, and so the
bones or shells of animals, the bark, fruits, and even leaves of
plants have been preserved, gradually assuming a stony texture
(Fig. 34, 36). Or if the softer parts rotted away, the cavity
left filled in with rock in time and so made a cast of the organism
showing to this day all the delicate details of the original. These
fossil remains, when carefully studied, yield an interesting history
of living things upon the earth. The .science which deals with
these fossil remains is paleontology, a special department of
geology.

Our western plains are, in places, particularly rich in the
fossil remains of some of the great vertebrates. Scarcely a
summer passes that scientific expeditions are not organized to
go out and explore these regions and find the fossils. The

THE WORLD IN THE MAKING 29

scientists of the expedition then skilfully remove them from the
rock, often spending days in chiseling away the rock from around
the cast of some old bones or in cementing together the more
or less cracked remains so they may be transported safely. They
are then shipped to the great museums, where they can be
leisurely set up and carefully studied.

The paleontological record is at no place on the earth com-
plete. It would seem at first thought as if in digging deep mines
we might hope to begin excavations in rocks of recent formations
and then dig down deeper and deeper through successively older
rocks. So we could find animal and plant remains that would
enable us to reconstruct readily the history of living organisms.
But the task is not so simple.

In an ideal section of the earth's crust (using the term in
the sense of the outer accessible layer) we should find the oldest
rocks deep down, then later and later rocks in successive layers
upon them, and finally the very recent rocks at the surface of
the earth. Such a condition is purely ideal; it exists only in
the mind of the geologist. It is fortunate that this is so, for if the
oldest rocks were always buried miles and miles deep under the
layers of later formations we could know nothing about them. As
it is they have often been upheaved and recent rocks have been
eroded off from them. The rock layers, by violent upheaval,
have been turned upside down in places so that the older rocks
are on top.

Whenever the sedimentary rocks with their fossil remains have
been upheaved above the ocean level, the process of deposition
has been thereby stopped and so the fossil record has been inter-
rupted. Moreover, no sooner were these rocks lifted above the
ocean than erosion began, and the historical record that had been
made was rapidly destroyed.

Thus the paleontologist reads the history of life upon the
earth from a great book whose leaves are the rock strata on which,
in fossil characters, the record is inscribed. Just as ancient
human history must be patched together by the experts from

30 A NATURALIST IN THE GREAT LAKES REGION

fragmentary bits, a clay tablet dug up from some old ruin in
the Euphrates Valley, some bit of papyrus taken from an
Egyptian pyramid, some roll unearthed from ash-covered
Herculaneum, so must this geological record be constructed
out of authentic scraps of information gathered from the rocks
of the several continents. Much of the record is covered up
under layers of soil and is inaccessible. Only in the quarry, the
mine, the chance exposure of rock strata by railroad cut, the river
gorge, or mountain ledge can the explorer find the fossil remains.
These give opportunity for the study of a mere fraction of the
whole record. It is surprising that the geologist has been so
successful in reconstructing the history of life upon the earth in
the face of such difficulties.

The historian divides the time of the enactment of human
history into the modern age, the medieval, the ancient, back
still farther, an age of myth and folklore in which events are
dimly seen, and finally a prehistoric age when the happenings
must be matters largely of conjecture. So the geologist sub-
divides the history which he reads in the strata of the earth's
crust into the Cenozoic, Mesozoic, Paleozoic, Proterozoic, and
Archaeozoic eras. Then just as man subdivides historical ages
into smaller periods, as for instance the age of ancient history,
into the Babylonian period, the Egyptian period, the Grecian
and Roman periods, so the geological eras are subdivided. The
tabulation at the end of the chapter will show the main divisions
and subdivisions of geological time and will serve as reference
to place the events about to be recorded. It will also facilitate
the reading of the bulletins in the bibliography at the end of the
book.

The different rock strata are referred by the experts to various
of these time divisions according to the time of their formation.
Thus we speak of carboniferous rocks — -those that were deposited
during the Carboniferous period. The relative age of any rock
layer is determined by finding what rocks are below it, what
are above it, and by the chasacter of the fossils it contains.

THE WORLD IN THE MAKING

Under the eras, periods, and their subdivisions are given at
the left the names of the better-known formations belonging to
each, mostly those of the eastern states, while at the right are
those of Illinois and adjacent regions. Unless the names are
identical, those on the same line in the two series are not to be
taken as necessarily equivalent.
CENOZOIC ERA
Quaternary

Recent period

Pleistocene period
Tertiary

Pliocene period

Miocene period

Oligocene period

Eocene period

MESOZOIC ERA

Cretaceous period
Comanchean period
Jurassic period
Triassic period

PALEOZOIC ERA
Permian period
Upper Permian
Rustler

Castile gypsum
Lower Permian
(Brazos or Oklahomian)
Delaware Mountain
Dunkard shales, sand-
stones, and limestones
Pennsyhanian period

Monongahela shales, sand-
stones, and limestones

Conemaugh shales, sand-
stones, and limestones

Allegheny shales, sand-
stones, and limestones

McLeansboro series, including clay,
limestone, slate, sandstone, and
the LaSalle first- vein coal, also
known as Streator No. 7

Carbondale series, clay, limestone,
slate, sandstone, and LaSalle

A NATURALIST IN THE GREAT LAKES REGION

Pottsville sandstone or con-
glomerate (Millstone
grit)

Mississippi period
Upper Mississippian
(Chester series)

Grand Rapids series
in Michigan

Marshall series in Michigan

Lower Mississippian

(lowan series)
Meramce

St. Genevieve limestone

St. Louis limestone

Spergen sandstone

Warsaw
Osage

Keokuk limestone

Burlington limestone

Fern Glenn limestone
Kinderhook

Chautauquan limestone

Hannibal shale

Sulphur Springs sandstone

Louisiana limestone

second- (Springfield No. 5) and
third-vein (LaSalle No. 2) coals,
the latter just above the Potts-
ville series, including clays and
sandstone

Typically exposed in southern Illi-
nois

Kincaid limestone
Degonia sandstone
Clare limestone
Palestine sandstone
Menard limestone
Waltersburg sandstone
Vienna limestone
Tar Springs sandstone
Glen Dean limestone
Hardensburg sandstone
Golconda limestone
Cypress sandstone
Paint Creek limestone
Yankeetown formation
Bethel sandstone
Renault limestone
Aux Vases sandstone

Names of formations are for the most
part the same in the Central West

THE WORLD IN THE MAKING

33

Devonian period
Upper Devonian
Chautauquan series
Catskill sandstone
Chemung sandstone or

shale
Senecan series

Portage sandstone or

shale

Genessee shale
Tully limestone
' Middle Devonian
Erian series
Hamilton shale
Marcellus shale
Ulsterian series

Onondaga limestone
Schoharie grit

Lower Devonian

Oriskanian series
Esopus grit
Oriskany sandstone

Helderbergian series
Becraft limestone
New Scotland limestone
Coeymans limestone

Silurian period

Upper Silurian (Cayugan)
Manlius limestone
Rondout limestone
Cobbleskill limestone
Salina beds

Middle Silurian (Niagara)
Guelph dolomite
Lockport limestone

Rochester shale
Clinton beds

Mountain Glenn shale
Alto 'formation

Lingle limestone
Misenheimer shale

Grandtower limestone
Dutch Creek sandstone
Clear Creek chert

Backbone limestone
Bailey limestone

Monroe series, Mich.

Guelph dolomite
Reef limestone
Upper coral beds
Lower coral beds
Sexton Creek
Edgewood

A NATURALIST IN THE GREAT LAKES REGION

Lower Silurian (Oswegan)

Brassfield sandstone

Medina sandstone

Edgewood limestone

Tuscarora

Cataract sandstone or shale

Becksie limestone
Ordomcian period

Upper Ordovician (Cincin-
natian)

Garoche

Richmond limestone

Mayville or Loraine
Eder or Utica shale
Middle Ordovician (Cham-

plainian)

Collingwood limestone
Trenton limestone
Black River dolomite
Lowville limestone
Chazy limestone
Stones River limestone
St. Peter sandstone
Lower Ordovician (Canadian)
Fort Cassin dolomite
Beekmantown or Prairie

du Chien dolomite
Oneota limestone
Madison sandstone
Mendota limestone
The last three are possibly
to be put in a separate
period, the Ozarkian
Cambrian period

Upper Cambrian (Croixian)

mostly limestones
Middle Cambrian (Acadian)

mostly limestones
Lower Cambrian (Wauco-
bian)

Girardeau

Richmond shale and shaly limestone
(Maquoketa)

Kimmeswick and Flatten
Galena limestone
Platteville limestone

St. Peter sandstone

Shakopee dolomite, cement rock, and

sandstone

New Richmond sandstone
Oneota dolomite
Jordan and Madison sandstone
St. Lawrence dolomite

Franconia glauconitic sandstone
Potsdam (Lake Superior sandstone)

Dresbach shale and sandstone
Lowest sandstone •

THE WORLD IN THE MAKING 35

PROTEROZOIC ERA

The chief rock systems in this era in the Great Lakes region are in
northern Michigan, Wisconsin, and Minnesota. In northern Michigan
they are as follows :

Upper Keweenawan

Freda sandstone

Nonesuch shale

Outer conglomerate

Lower Keweenawan

Lake shore trap (basic lava)
Great conglomerate
Eagle River and Ashbed

group (acid lava intru-

sives)

Mesnard epidote
Central mine group (basic

lavas)
Conglomerate (acid lava

intrusives)
Bohemia Range (mostly

basic lavas)
Upper Huronian

Clarksburg formation
Michigamme slate and

schist
Goodrich formation (mostly

quartzite and conglom-
erate)

Middle Huronian
Presque Isle granite
Quinnisec schist
Tyler and Hanbury forma-
tions
Negaunee, Vulcan, and

Ironwood formations
Ajibik, Siamo, and Palms

formations
Hemlock formation (basic

lavas)
Kona, Randville, and Bad

River formations
Mesnard, Sturgeon, and

Sunday formations

(mostly quartzite)

ARCHAEOZOIC ERA
Laurentian
Keewatin

CHAPTER III

THE STORY OF OUR ROCK FOUNDATION

HE rock immediately underlying the soi
in the Chicago area is the Niagara lime-
stone. It has a thickness of 25o-4oc
feet. It is exposed in many places aboul
the city as in the quarries at Stony Island
Thornton, Hawthorne, Elmhurst, on th<
Chicago & North Western Railway
McCook, on the Atchison, Topeka &
Santa Fe Railway; and Lockport, on the Chicago & Alton
Railroad. There are mile-long heaps of it beside the drainage
canal from which it was excavated from Willow Springs to Lock-
port, and also beside the branch canal from Blue Island to the
Sag. At Lockport the rock comes to the surface and forms the
bluffs bordering the Desplaines River Valley on the south, and
there are similar bluffs on the north side of the valley at Lyons.
As a rule the strata of the limestone are approximately hori-
zontal, dipping slightly to the south. But at Stony Island they
are sharply inclined (Fig. 23) and that in opposite directions on
the two sides of the present low ridge, showing that this eleva-
tion is the eroded remnant of what was once a mountain fold of
no mean height. Similar folds of the strata on a smaller scale
are seen in many of the quarries.

Below the Niagara limestone occurs a succession of rocks
which in a deep boring at Lockport were disclosed as shown in
the accompanying diagram (Fig. 24). Other similar borings
have given like results. Presumably if the drill had gone deeper it
would have encountered the still older rocks of the Proterozoic era
and then the complex of the Archaeozoic. The history of the for-
mation of these rocks of our immediate vicinity is most interesting.

THE STORY OF OUR ROCK FOUNDATION

37

FIG. 23.— The east and west quarries on Stony Island. Note the strata dip
in opposite directions.

38 A NATURALIST IN THE GREAT LAKES REGION

J_L L

Sandstones, limy shales, limestones and coal.

j

I Limestone and shales.

•* Below this level are the rock strata of the Chicago area as i

cago area as revealed
in a well bored at Lockport (after Alden, U.S. Geological Survey).
Above strata found to south and east; the Devonian is slightly
represented at Chicago.

Niagaran, dolomitic limestone .

Richmond (Cincinnati) shale.

230 ft.

.. no ft.

Galena-Platteville (Trenton) limestone 300 ft.

St. Peter sandstone .

. . 210 ft.

> Lower Magnesian formation 395 ft.

Dolomitic limestone, red marl, and shale, or shaly limestones.

Potsdam formation 686 ft.

Sandstone, red marl, and shale or shaly limestones.

FIG. 24.— Diagram of strata in the Chicago region

THE STORY OF OUR ROCK FOUNDATION

39

Concerning the earliest rocks that made up the outer cool
portion or crust of our earth we know nothing except by inference,
for they are nowhere subject to observation. Probably they
were lavas that had outflowed from the deeper layers on to the
surface, forming not only what lands there were, but also the
bottoms of the seas and oceans. These rocks were attacked by

FIG. 25. — Basaltic dyke intrusive in granite, the latter lichen-covered, south
shore of Partridge Island (Marquette), Lake Superior.

the various agents of erosion, and disintegrated. The material
so eroded was used to build up other rocks as indicated in the
preceding chapter. These newer rocks, sandstones, shales, etc.,
such as are forming today under similar conditions, accumulated
through long ages, were upheaved by the crumpling and folding
of the crust, occasionally into great mountain ranges, and thereby
metamorphosed into quartzites, slates, and schists. The rock
layers were by the same convulsions fractured, and into the

40 A NATURALIST IN THE GREAT LAKES REGION

great cracks and crevices fresh lavas forced their way, often
separating the strata, raising the upper ones as domes and filling
the spaces so formed. So these rocks where they are accessible
today are seamed with dykes (Fig. 25), as these cooled lava
intrusives are termed, and where their upper layers have been
removed by erosion the old masses of lava that filled the domes
stand up as rounded hills or monadnocks (Fig. 26).

How often this process of rock destruction, reformation, and
metamorphosis was repeated we do not know. In time simple
plants and animals appeared. Through their action beds of

FIG. 26. — A monadnock, Ishpeming, Michigan

carbonaceous material — probably peat — of iron oxide, and of
magnesian limestones were laid down with the sandstones and
shales. These also were transformed by metamorphosis into
graphites, iron ores, and dolomitic marbles. The early lavas^
granites, diorites, and such were in many cases also greatly
altered by later strains and stresses, to which they were sub-
jected by crustal movements. So the earliest rock masses to
which we have access consist of highly nietamorphic quartzites,
slates, schists, marbles, seamed and infiltrated with granites and
with basic lavas that are often so abundant as to dominate the
formation. These old rocks are so folded, crumpled (Fig. 27),

THE STORY OF OUR ROCK FOUNDATION 41

and eroded that we may now often examine their upturned
edges as they become exposed. The accessible rocks of these
early eras are exceedingly thick, possibly one hundred thousand
feet thick, thicker than all the formations that came after them.
The amount of erosion that they have undergone is tremendous.
Rock layers miles in thickness have been removed from these

FIG. 27. — Folded and crumpled rock on the face of a vertical cliff of jasper
and hematite at Ishpeming, Michigan.

early land masses that were of continental proportions. Pre-
sumably then, the Archaeozic and Proterozoic eras represent
longer periods of geological time than any of the later eras, and
are to be counted in tens of millions of years, possibly hundreds
of millions.

The early lands, made up of these primitive rocks that served
as the nuclei for the formation of the North American continent,
were a group of great islands. In general the oceanic depressions
and the continental elevations have existed from Archaeozoic
time, possibly from the very first, much as they now are. These

42 A NATURALIST IN THE GREAT LAKES REGION

islands, therefore, arose from a shallow sea that covered the
continental elevations. In this sea on the flanks of these early
nuclei were deposited the materials eroded from them that made
up the succeeding formations of the early Paleozoic, somewhat
as nowadays in the Gulf of Mexico or the Mediterranean are
accumulating the deposits of mud that in all probability will in
time transform to rock which may be upheaved to form new
land masses.

In general it may be said that the rocks of the later eras —
Paleozoic, Mesozoic, Cenozoic— were laid down in the North
American region in these shallow epicontinental seas, seas that
constantly changed their shape as the surrounding lands were
raised or depressed by crustal movements, or as the ocean
changed its level when its floor sank or rose, in which latter
process accumulating sediments were a major cause. Some-
times the land above the ocean was a group of islands, sometimes
it was a continent with more or less of its central area covered
by a sea and this latter was connected by wide straits with the
Atlantic, Pacific, the warm tropical ocean, the cold Arctic, one
at a time or two or more simultaneously. The characters and
affinities of the animals and plants whose remains are found in
the successive rock formations give us the best evidence regard-
ing the oceanic connections of the seas in which these formations
were deposited.

The large island made up of the Proterozoic rock complex
nearest to the Chicago region was extensive, covering what is
now northern Wisconsin, a part of the upper peninsula of
Michigan, much of Minnesota, and a large area extending north-
ward into Canada. This region now consists of quartzites,
shales, schists, and dolomites with the intrusive granites,
diorites, and other lavas. If one were to start, say, at Stevens
Point or at Grand Rapids, which places in Wisconsin mark about
the southern limit of the exposed Proterozoic rocks in our vicinity,
and travel southeastward to central Illinois, he would pass over
he edges of the succession of rock formations laid down one on

THE STORY OF OUR ROCK FOUNDATION

43'

FIG. 28.— Map of the exposed geologi-
cal formations in the Great Lakes area.

s, pwsandstone

44 A NATURALIST IN THE GREAT LAKES REGION

top of another but with many interruptions on the southern
flank of this continental nucleus (map, Fig. 28, compare Fig. 37).
The underlying formations would not everywhere be the same
because in some places the surface rock is one of those deposited
early, and consequently has few members of the series below it,
and in other places (those farther south), the rock is a later forma-
tion and has many members below it. Often one or more
members of the series may be absent at a given locality if that
spot was land when said member was being deposited as might
readily be the case since the sea was so incessantly changing its
shape from period to period.

When such a term as the Niagara limestone is used it does not
imply that the formation is necessarily homogeneous; it may
consist of successive strata of different sorts of rock or, if of the
same sort, the succeeding layers show by the unlike animal and
plant fossils they contain that they belong to different successive
fragments of geological time. The Niagara limestone, the bed
rock of the immediate Chicago region, was laid down in this
interior sea without any very violent interruptions, but the out-
let of the sea was shifted several times during its deposition so
that the fossil remains in successive levels of the formation are
quite unlike, some having affinities with arctic forms, some with
tropical, and some with those of the Atlantic and Pacific. The
formation is thus divisible into several distinct sets of strata.
In the Chicago region there are at least the lower coral beds, the
upper coral beds, the reef limestones (Fig. 29), and the Guelph.
Similarly, the Potsdam sandstone exposed farther north consists
of three quite distinct sets of strata, the lowest sandstone that
has a thickness of about a thousand feet, the Dresbach shale and
sandstone, and the Franconia sandstone, the two latter each
about two hundred feet thick. The names applied to the succes-
sive rock formations encountered in Illinois and adjacent terri-
tory are shown in the table at the close of the preceding chapter.

The character of the rock often tells much of the conditions
prevailing at the time of its formation. Beds of sand and gravel

THE STORY OF OUR ROCK FOUNDATION

45

are usually deposited in the ocean nowadays close inshore, unless
the streams bringing in the sand are swift or unless rapid ocean
currents carry the sand well out from the shore line. Fine mud
may be carried in suspension long distances by the water. It
settles only in the quiet parts of the ocean, which are usually
the deepest ones, or in isolated bayous free from the turbulence
of the waves, from currents, and from undertow. Limestone Is
made up of the more or less completely ground up shells of
animals like clams, oysters, and other similar forms, or the hard

FIG. 29. — A coral reef exposed in the quarry at Thornton, Illinois. Men are
standing at the center of the concentric lines of growth. Photo by Link.

parts of corals or of other animals whose skeletons are composed
largely of lime. By pressure and infiltration this pulverized
material is later transformed to the limestone. Now animals like
corals and clams will not live where the water is very muddy.
Corals especially must have fairly deep and clear water in which
to thrive. Wherever an area of limestone is found, especially if
it contains coral beds in situ, it means that the body of water
at whose bottom it formed must have been fairly deep and
sufficiently far removed from the shore line to be beyond the
deposits of sand or any large amount of mud.

46 A NATURALIST IN THE GREAT LAKES REGION

With these brief hints of the sort of evidence on which the
geologist relies to reconstruct the physiographic features of past
ages we may sketch in bare outline the history of the Chicago
region and adjacent territory during the time the rocks here-
abouts were depositing. During the Acadian period (Fig. 30) the
Potsdam formation, largely sandstone with shales, was laid
down as sand and mud washed by erosive agencies from the
adjacent land and spread out on the sea bottom and transformed
into rock. Then followed the Canadian period (Fig. 31), during
which limestones, sandstones, and shales were formed. The
conditions must, of course, have frequently changed to permit
of such varied types of deposits. First there were laid down
thick beds of magnesian limestone interrupted by layers of shale
and marl when evidently the sea became shallower and muddy
or possibly even so shallow as to allow abundant vegetation that
was instrumental in forming the marl. Later sandstone formed
and then more limestone.

There was next (Ordovician period) a change to a shallow
sea with swiftly flowing currents and a nearby shore. The sea
contracted and its margins transformed to dry land. Possibly
much of the time the sea completely disappeared from this
locality, its shores lying farther south, and the drifting sand
blew inland in great dunes covering wide areas. This sand in
time solidified to form St. Peter sandstone. Again the land sank
and the interior sea reformed, inundating the entire area about us
as well as areas considerably to the north. The sea bottom was
now deep enough along shore and free enough from mud to allow
the abundant growth of animal and plant life. Here where
Chicago stands were forming great beds of limestone, the
Platteville- Galena (Trenton) made of the wave-worn fragments
or even of the perfect shells or skeletons of animals then living
along the shores, the nearest of which were somewhere up in
what is now mid- Wisconsin. Animal life was abundant. There
were corals, brachiopods, pelecepods, and trilobites. There were
also extensive beds of seaweed growing luxuriantly just as

THE STORY OF OUR ROCK FOUNDATION

47

FIGS. 30-33. — Fig. 30. — Map showing land and sea when the Potsdam sand-
stone was depositing (Upper Acadian). Fig. 31.— When Magnesian limestone
was depositing (Beekmantown). Fig. 32. — When Richmond shales were depositing
(Cincinnatian). Fig. 33. — When part of the Niagara limestone was depositing
(Mid-Silurian). Land is white, sea finely lined; black shows areas of present
outcrop. All after Schuchert.

48 A NATURALIST IN THE GREAT LAKES REGION

they do 'now along the coral banks of the Gulf of Mexico. No
fish were swimming in the waters; they had not yet appeared
upon the earth. The land areas would have seemed strange, too,
for the vegetation did not consist of trees and grasses and flower-
ing herbs, but lowly plants like algae, liverworts, and ferns.
No insects were flying, no vertebrates, neither snakes nor frogs
nor birds, had yet evolved.

Toward the close of the Ordovician period another extensive
change in level of the sea occurred. The central sea decreased in
size in this region though widening in the north (Fig. 32), coastal
plains emerged hereabouts, and from them and across them
great quantities of mud were washed so the shallow sea became
unfit for many animals. Many kinds were forced to migrate to
deeper seas, many perished, and their remains are very abundant
in the beds of shales and sandy limestones known as Richmond
shales. This stratum formed in the Chicago region to a depth of
100 feet and elsewhere in the interior sea became even thicker.

The formation of the Richmond shales and sandstone was ter-
minated by a rise of the land so that the northern portion of the
interior sea including the Chicago region became dry land, subject
then to the destructive forces of erosion. So closed the Ordovician
period, and the Silurian period was ushered in. As it advanced
the sea deepened rapidly (Fig. 33) until conditions were favor-
able again for an abundant animal life along the shore and for
corals in the deeper waters. Many, many generations of animal
forms with calcareous skeletons lived and died and left their shells
or other hard parts to form the thick deposits that later trans-
formed into Niagara limestone to a depth of from 250-400 feet
in the Chicago region.

This rock is full of fossils that help us gain a clear idea of the
animals that lived upon the sea bottom where today Chicago
stands and that contributed their skeletons and shells to help
form the rock out of which Chicago's inhabitants constructed
their buildings in the days before cement so largely replaced
building stone (Fig. 34).

THE STORY OF OUR ROCK FOUNDATION

49

AKF^

FIG. 34. — Animal fossils from Niagara limestone in the Chicago region.
a, a coral, Favosites niagarensis Hall; 6, Phraginoceras neslor Hall; c, Penlamerus
oblongus Sowerby; d, a trilobite, Calymene celebra Raymond; e, Amphicoelia
neglecta McChesney; / and g, crinoids: /, Eucalyptocrinus as per Weller;
g, Caryocrinites ornatus Say; h, Strophostylus levatus Hall; i, a straight-shelled
cephalopod, Dawsonocerus annulatum Sowerby. Photo by Fenton.

50 A NATURALIST IN THE GREAT LAKES REGION

There were great reefs of corals off the shore of the nearby
land, and other species of corals that lived solitary lives rather
than in colonies were abundant. There were sponges, grap-
tolites, polyps, crinoids like stemmed starfish, ordinary star-
fish, lamp shells or brachiopods, clams, snails, cephelopods,
somewhat related to the pearly nautilus of today, only having
long, straight shells instead of coiled ones; there were primitive
crustaceans like the trilobites. Undoubtedly on the land about
the sea grew giant club mosses, tree ferns, cycads, and the lower
types of flowering plants such as the conifers and the grasses.
Centipedes and lowly types of insects were also probably seen.

A period of upheaval followed the deposit of the Niagara
limestones closing the Silurian period, and the Chicago region
was once more dry land undergoing erosion. How long this
condition persisted it is hard to say, but there followed another
period of depression when the sea again occupied this site. The
inland sea was becoming more restricted, however, deposition
was going on in limited basins, and the wash from the land was
increasing as the land area grew. In this Devonian period the
strata formed consisted of shales and limestones. Only remnants
of them exist in a few locations about Chicago, however, for the
sea disappeared in our region rather promptly and all the Devo-
nian rocks that had formed were eroded away leaving the Niagara
limestone bare except where an occasional fissure in it had
happened to receive and retain some of the Devonian deposits.
Such have been found at the quarry at Elmhurst and at Lyons.
These deposits, though scanty, are exceedingly interesting, for
they contain many sharks' teeth, local evidence of the presence
of the fishes in the Devonian seas; they were so abundant, so
dominant, that the Devonian is known as the age of fishes.

So far as we know, the ocean never again overflowed the site
of Chicago. This immediate region remained exposed, subject
to the action of the elements, undergoing extensive erosion
during the rest of the Paleozoic and during all of the Mesozoic
and the Cenozoic. Our local rocks afford no evidence of the

THE STORY OF OUR ROCK FOUNDATION

changes that occurred through all these eventful ages, except the
tokens of the glacial period that came in late Cenozoic time, as
will be described shortly.

The whole central region of Illinois is occupied by rocks of
the later Paleozoic era (map, Fig. 28) commonly known as the
coal beds. The seas (Fig. 35)
in which these rocks were
deposited were at times suf-
ficiently deep to allow mud
deposits to accumulate that
later were transformed to
shales and slates ; then again
they became so shallow they
were covered with swamp
vegetation. Here grew
dense jungles of cycads and
calami tes*, rushes and sedges,
gigantic ferns and probably
conifers, a rank growth
whose trunks and stems
and leaves falling into the
shallow water accumulated
until a thick bed of vege-
table matter lay upon the
floor of the sea. This was
covered by mud during the
next period of depression and gradually by pressure and heat
was converted into coal.

The old dump piles of refuse slate, shale, and poor coal afford
excellent opportunities to secure fossils of this period. Fern
leaves, bark of the tree-fern trunks, calamite stems, fossils of
various animal types, including an occasional fish skeleton, and
that of the early amphibians are to be had by patient search
(Fig. 36). You can easily imagine the picture of the region
when the coal was forming: the dark swamp forest, the moist,

T FlG- 3S;-North America in the Upper
Pennsylvania!! when the Illinois coal beds
were being deposited. Land white, seas lined.
Black areas indicate land where these strata
are now surface formations. After Schuchert.

ILLINOIS

LIBRARY

52 A NATURALIST IN THE GREAT LAKES REGION

warm air heavy with abundant carbon dioxide, tree ferns,
cycads, grasses, rushes — an almost impenetrable jungle — a loose,
swampy soil, a vegetable slush into which the fallen trunks sink,
insects somewhat like roaches crawl over the vegetation — some
like immense dragon flies are darting about in the air.

In the adjacent sea are sponges, corals, graptolites, sea
urchins, starfish, crinoids, brachiopods, clams, snails, trilobites,
shrimps (Fig. 360), cephalopods, fish of the lower types, amphibi-
ans, and boring in the mud banks are sea worms of various sorts.

Centuries passed by in the Chicago region, hundreds of them.
In the distant seas were forming the thousands of feet of rock
strata that make up the remainder of the Paleozoic, the Mesozoic,
and the Cenozoic rocks. Undoubtedly the rocks of the Chicago
area, disintegrated slowly under all the processes of weathering,
formed deep soil, and upon this there grew a rank vegetation.
Here, in time, occasionally perhaps roamed those huge reptiles
whose fossils are to be seen in the collection of the Field *Museum
and still later various types of mammals that were precursors of
present-day forms. The map (Fig. 28) gives the positions and
relations of the main formations occurring as surface rocks over
a wide area about Chicago.

A great fold of the strata occurs in Illinois, a broad up-arching,
its axis running southeast-northwest and continuing into Wis-
consin on the one hand and into Indiana on the other. The rock
originally lying on the top of this arch has been removed by
erosion as a result of which, it will be observed, there is in the
northern part of the state a broad central band of Galena-
Platteville limestone bordered on the east and west by the Rich-
mond (Maquoketa) shale, while farther out still lie bands of the
Niagara limestone on the eastern one of which Chicago is situated
(see Fig. 37).

The nearest point to Chicago at which the Richmond shale
is found is in the neighborhood of Joliet, at the mouth of Rock
Run, near the old canal some four miles southwest of the city
and in the same neighborhood in an abandoned quarry near

THE STORY OF OUR ROCK FOUNDATION

53

FIG. 36. — Fossils from the Pennsylvania!! coal measures, Mazon Creek, 111.
All plants except e. a, Alelhopteris ambigua Lesqx.; b, Neuroptcris vermicularis
Lesqx.; c, a horsetail, Annularia stellata Schl.;' d, Sphenophyllum marginatum
Brougn.; e, a crustacean, Acanthotelson stimpsoni M. & W.; /, Palmatopteris fnrcata
Potonid.; g, bark of SigUlaria sillimani Brougn. Plant photos by P. O. Sedgwick.

54

A NATURALIST IN THE GREAT LAKES REGION

the lower end of Flathead mound where, however, it is nearly
covered by the crumbling Niagara limestone above it.

The map will show the nearest point at which the Galena-
Platteville is exposed. In several counties along the crest of
the arch the streams have cut down sufficiently to expose the
St. Peter's sandstone that underlies the Galena-Platteville and
in a very few spots to expose the deeper Lower Magnesian lime-
stone (Prairie du Chien). Such cutting to the St. Peter's occurs
in eastern Carroll County, in Ogle County south of Oregon on
the Rock River, and along many streams in southwestern
Wisconsin. The cutting runs deeper, even to the Lower Mag-

FIG. 37.— Diagrammatic section across the arch of rocks in Illinois. The
lower section cuts through Joliet (J), Marseilles (M), Ottawa (O), and Prince-
ton (P). The upper one is farther north, (i) Lower Magnesian formation;
(2) St. Peter's sandstone; (3) Galena-Platteville formation; (4) Richmond shale;
(5) Niagara limestone; (6) Devonian; (7) Pennsylvanian.

nesian on the Illinois River in the neighborhood of La Salle
and Utica. Between these it is exposed along the railroad
tracks. It is also seen near the mouths of several creeks flow-
ing into the Vermilion River.

The Illinois is here flowing through country of which the sur-
face rock belongs to the Pennsylvanian coal measures, so the river
has cut through these, through the Galena-Platteville limestone
and St. Peter's sandstone, to the Lower Magnesian limestone.
The rocks of the Pennsylvanian formation are most easily reached
from Chicago at Braiderwood or Coal City, on the Chicago &
Alton Railroad and Atchison, Topeka & Santa Fe Railway,
respectively, where they may be examined in the rock dumps

THE STORY OF OUR ROCK FOUNDATION 55

of the coal mines. The rocks of the Devonian and Mississippian
are older than the Pennsylvanian but are not exposed in the state
nearer than its western side near Rock Island. They are found
nearer Chicago, in Wisconsin just north of Milwaukee, and also
in southwestern Michigan. Remnants of the Devonian rocks
are preserved occasionally in the cracks and crevices of the
Niagara limestone in this immediate vicinity.

CHAPTER IV

THE GLACIAL PERIOD

REAT glaciers came out of the north in
recent geological time covering all the
northern part of North America (Fig.
38), Europe, and Asia, glaciers compara-
ble to the great ice cap that now covers
all the antarctic lands or to the one
that still over-rides Greenland. The
glacial period probably came on gradu-
ally. The snow accumulated in the north more rapidly during
the long winters than the summer's diminishing heat could
melt it. It grew deeper and deeper. The chill of the great
snowfields was felt in the lands south of them where the climate
became more rigorous and the snows began to pile up ; thus the
snowfields became more extensive. In the far north the snow
banked up miles deep until the lower layers under the terrific
pressure were transformed into ice and were squeezed out,
moving southward over once fertile lands and transforming
them into arctic desolation. This same process is going on now
on a small scale in the high mountains all over the world where
lakes of snow in the upper valleys outlet by rivers of ice that
slowly push their way down the slopes (Fig. 10).

What agencies brought on the glacial period has been a
matter of interesting conjecture. The uplift of the northern
part of the continent to Alpine height, a shift of the warm ocean
currents so they did not flow into the northern oceans, a change
in the position of the earth's axis so that winter came in the
northern hemisphere when the earth in its orbit was farthest from
the sun instead of nearest as now, a change of eccentricity of the
earth's orbit, an increase in the amount of carbon dioxide in the

56

THE GLACIAL PERIOD

57

atmosphere which would shut out much of the sun's heat — all
these have been suggested as possible causes, and each has been
judged more or less incompetent to produce the results. Possi-
bly several causes co-operated to produce the glacial age. It is
estimated by Penck that a reduction in the average annual
temperature of less than 15°
F. would bring on a return
of the glacial period in North
America, a slight change
apparently to produce such
far-reaching consequences.

If the exact causes still
are matters of debate, the
fact is certain that the Chi-
cago area was covered with
a deep glacier and that not
once but several times, for
there is good evidence that
a succession of glacial
periods have followed each

other in North America.

FIG. 38. — Map of North America at
the time of the glacial period. Note that
the southern limit of the glacier was a
little short of the southern boundary of
what is now Illinois and Indiana and that
there was an unglaciated area in Wiscon-
sin and northwestern Illinois. (See Fig. 51.)

These have been designated
the Aftonian or Jersey an, the
Kansan, the Illinoian, the
lowan, and the Wisconsin.
The oncoming of the Wis-
consin ice sheet occurred
possibly twice as long ago as has elapsed since the last ice dis-
appeared completely here, a matter of some ten thousand years.
The lowan began, roughly, four times as long ago; and the
Illinoian, eight times or more. The time in which we live may
be one of the interglacial periods, and it may be that many of
the mighty works of our much vaunted civilization will, in the
distant future, be blotted out by the renewed ruthless advance
of the great ice cap.

A NATURALIST IN THE GREAT LAKES REGION

While, as suggested in the last chapter, there is no evidence
that rock strata were laid down in the Chicago region after the
Devonian period of geological time, in the long stretch of ages
that elapsed between then and the onset of the last glacial period
many changes were going on in the area. For many centuries
the forces of erosion were active. The Devonian rocks and

FIG. 39. — An attempted reconstruction of the preglacial drainage of the
Great Lakes region. Present lakes, streams, and boundaries in dotted lines.

possibly later ones on top of them were worn away until only
vestiges of them were left and the removed material was carried
off into the oceans. The surface of the hard Niagara limestone
and of the softer Richmond shale was dissected by the rivers
into steep-sided valleys that later broadened and became less
abrupt while rounded hills of goodly height stood between. The
rocks gradually disintegrating through hundreds of thousands
of years formed deep soil. Vegetation flourished and animal
life found abundant shelter and food. Probably where Lake
Michigan now stands was a broad and fertile valley.

THE GLACIAL PERIOD 59

It is now impossible to be certain of the topography of the
country hereabout before the glacier came to make its changes,
for that old surface was undoubtedly greatly altered, its rock
foundation pretty completely covered by the debris the glacier
left. Still, knowing the general lay of the old rock strata and
their nature, and learning something from the rock hilltops that
crop out of the glacial deposits and from well borings that pene-
trate to the rock surface, it is judged that the old valley now
occupied by Lake Michigan extended past the site of Chicago,
through rugged hill country, and that in it flowed a river, part
of the preglacial river system, a more or less conjectural diagram
of which is shown in the accompanying figure (Fig. 39). Fortu-
nately there is one region not far removed from Chicago which
presents no evidence of the recent glacier, and it is believed it
escaped the late ice covering — an island in the broad ice flow.
This is the unglaciated region of northwestern Illinois and south-
western Wisconsin. It is a well-drained region with much
branched rivers flowing in deeply cut valleys between the
rounded hills. It is not a region of lakes or ponds. The soil
grades insensibly into the rock — -fine soil on top, coarser below,
finely broken rock, coarser fragments, then the rock ledge just
beginning to disintegrate. It is probably quite typical of the
Chicago region in preglacial times except that the processes of
erosion had not gone so far here before they were interrupted
by the onset of the glacier.

As the great glacier came pushing its way southward it
shoved ahead of it some of the soil scraped from the land, soil
that had been accumulating through many centuries of rock
decay; or else the frozen soil, together with the rock fragments
below it, was over-ridden by the glacier, frozen to its base, and
so became a part of the onward-moving mass and ultimately was
incorporated in the plastic ice. Then this same material became
in the grip of the glacier, an efficient grinding and polishing tool,
This is found to be true of present-day glaciers. They are
mighty agents of erosion. While the ice itself glides over the

6o

A NATURALIST IN THE GREAT LAKES REGION

bed rock with little wear or tear, rock fragments held by the ice
make deep grooves, imbedded sand grains stria te the rock sur-
face in the direction of glacial motion, while finer particles like
clay polish it. Such work necessarily wears away the graving
tools. Rock fragments held by the ice and pressed against the
rock over which it moves are themselves planed off, polished,
and scratched, first on this side, then on that, as they turn in

FIG. 40. — A good-sized glacial bowlder on Lake Michigan shore near Glencoe

the somewhat plastic ice. Ultimately they are ground to powder
unless they are dropped in the morainal material, in which case
they are subangular stones more or less marked by their use
(Fig. 40). The bed rock where freshly uncovered in the Chicago
region often shows a polished surface, sometimes striated, occa-
sionally deeply grooved, mute evidence of events that were
transpiring here during the great ice age. In general these
markings are parallel and have a northeast-southwest direction,

THE CL-.

PERIOD

61

showing the compass point from which the glacier came here.
At times the scratches cross each other, indicating at least local
changes in the direction of movement of the ice (Fig. 41).

At last in its onward flow the glacier pushed its way south-
ward into a region so warm that the front of the glacier melted
away as rapidly as new ice arrived. The bulk of the coarse
rock fragments it was carrying, together with much of the finer

FIG. 41. — Grooves and scratches on bed rock due to glacial erosion, Stony
Island, Chicago.

stuff, was deposited along this line where the glacier front stood
perhaps for hundreds of years, piling up in great unsorted heaps
as the moving ice continually brought fresh supplies. Thus it
formed out of this debris pillaged from a continent the terminal
moraine. The Illinois glacier is the first one to leave undisputed
evidence of itself in our state; it pushed south approximately to
the present location of the Ohio River and deposited its terminal
moraine. This glacier, therefore, extended past our present loca-

62

A NATURALIST IN THE GREAT LAKES REGION

tion at Chicago some three hundred miles. Nansen found in cross-
ing Greenland that the ice surface rose for the first 75 miles
from the west coast nearly 90 feet per mile, then at a decreasing

FIG. 42. — The moraines of the glacier about south end of Lake Michigan;
old Lake Chicago in heavy horizontal shading, Lake Morris in broken hori-
zontal lines.

rate averaging 26 feet per mile. On this basis of calculation the
ice of the Illinoian sheet at Chicago must have been about
twelve thousand feet deep. Even if, to be on the safe side, this
estimate were cut in half, it would still make the mass more than
a mile in thickness, a ponderous thing, capable of over-riding

TLE GLACIAL PERIOD 63

hills and planing down their tops, of gouging out valleys, and of
transporting incalculable loads of debris.

Gradually the rigorous climate of this early period was
mollified. Spring came earlier as the years passed and the
autumn days grew warmer, so that the glacier beat a slow retreat.
As the front slowly melted back through many, many years the
rock and soil debris held in the ice was deposited all over the
smoothed and scored rock surface in an unsorted condition,
the finer material containing subangular rocks and bowlders of
all sizes, polished and scratched. It is the same sort of drift
that makes up the terminal moraine but now constitutes the
ground moraine, the deposit laid down by the retreating glacier.
This withdrawal of the ice was irregular; it would fall back
only to advance again as a few cold winters reinforced its reserves.
Its front was constantly shifting as melting or temporary advance
went on at some points more rapidly than at others, due to local
conditions. The deposited drift was therefore left in erratically
arranged heaps with irregular hollows between. The drift some-
times buried great blocks of ice which later melted, leaving de-
pressions. Most of the valleys were without outlets except as
chance arranged them, so that later they were occupied by
lakes, ponds, bogs, marshes, and swamps.

This Illinoian ice age was followed by a long interval when
the surface of the soil was subject to erosion; when in all prob-
ability forests developed and grassy plains and valleys lay
luxuriant in the warm sunshine. Other ice sheets again invaded
the region, however, bringing desolation. In these later ages,
the lowan and the Wisconsin, the ice in the Chicago region was
nowhere nearly as thick as in the case of the Illinoian. These
later ice sheets apparently over-rode the early drift deposits,
piling up their moraines and other deposits upon the earlier ones.
The average depth of the drift in the Chicago region is probably
130-140 feet, as determined by wells, with a maximum thickness
of somewhat over twice this figure. Most of this is the deposit
of the Wisconsin period. In some places in our immediate

64 A NATURALIST IN THE GREAT LAKES REGION

region it is underlaid by a deposit that has been regarded as
belonging to one of the earlier ages, probably the Illinoian. A
coarse conglomerate made up of glaciated pebbles, 5-10 per cent
of which are of granite or diabase, is seen underlying the Wis-
consin drift north of Lockport just beside the Chicago and
Joliet trolley line and at several points within the city limits of
Joliet, one opposite the brick switch house about a mile north of
the Rock Island Depot. This deposit is well cemented together
with carbonate of lime, transforming the original bed of gravel
into rock. Its surface is said to give some indication of having
been abraded by the later ice sheet. It seems more probable
that these deposits are part of the valley train described
below.

The surface features of the Chicago area are chiefly due to the
deposits of the last of the great glacial periods — the Wisconsin —
and to postglacial changes in these. The front of this ice sheet
retreated by several steps, standing still long enough several
times to make a succession of terminal moraines as seen on the
accompanying maps (Figs. 42, 43).

Each of the moraines marks a stage in the recession of the ice border,
when the rate of melting was temporarily checked and the edge of the ice
became nearly stationary. At such times the drift, which was being moved
forward to the melting border and deposited there, accumulated to great
thickness. When the ice border receded a relatively smooth lowland was
laid bare behind the belt of thick drift. This extended to the point where
another halt of the ice caused the making of another ridge of drift.

Of these moraines the last formed — -the one nearest Chicago,
the Valparaiso moraine — is the highest and broadest. It marks,
evidently, a prolonged stand of the glacier's front. Its sur-
face varies from an almost smooth or gently undulating plain
(Minooka Ridge) to typical rounded hills and saucer-shaped
valleys with contained ponds or swamps. The last type is well
seen on Mount Forest Island, as one walks south from Willow
Springs, or in the hill territory about Palos Park. The hills and
valleys are not so abrupt or so high as they are in the kettle-

ACIAL PERIOD

FIG. 43— Map of Illinois moraines. Bulletin State Geological Survey

66 A NATURALIST IN THE GREAT LAKES REGION

moraine territory of southern Wisconsin about Gary, for instance;
still it is very evidently moraine topography (Fig. 44).

The melting front of the glacier was pouring out torrents of
water that discharged in a mighty river do vn a valley occupied
now by the Desplaines, then the old preglacial valley and much
deeper than the present one. The river discharged for a time,
at least, into a lake that occupied the Morris Basin (see map),
and this in turn had its outlet along the present Illinois Valley
then also much deeper. This great river laid down material
along its course, for it came away from the glacier so charged

FIG. 44. — Typical moraine country, kettle-shaped hills and valleys, the
latter often with ponds o lakes with no outlet.

with sediment that wherever its current was checked in the least
it deposited the gravel and sand. So it filled up its valley, and
tributary streams rilled up theirs with long-drawn-out deposits
known as valley trains. It spread out a great fan-shaped delta
at its entrance into the lake of the Morris Basin. The old valley
was filled to a level some fifty feet above the present stream as is
evident from the remnants of the old valley train still recogniz-
able. "Opposite Lockport where the road to Plainfield leaves
the valley floor" is a flat- topped gravelly ridge, a part of the
old valley fill. Some four miles below Joliet there are flat-topped
areas of gravel standing up conspicuously in the present valley,

THE GLACIAL PERIOD

67

generous remnants of the old valley train. The formation is
known as "Flathead" (Fig. 45). At a level corresponding to its
top on the north side of the valley may be seen a conspicuous
shelf of similar gravel along which the upper road runs for some
distance. These gravel deposits are rapidly being removed for
commercial purposes.

Small streams rushing from points at the front of the glacier,
charged with sediment, often deposited such material close to the

FIG. 45.— Flathead near Joliet. Detail at right, to show size of the gravel

glacier's edge as the current was checked when the stream spread
out on to the open plain. Such mounds of debris, always irregu-
larly stratified , are known as kames. Good examples of such are to
be seen one and one-half miles northeast of Naperville, where the
road to Wheaton passes between two dome-shaped hillocks, both
kames. There is a large one east of Glen Ellyn, cut by the
Aurora, Elgin and Chicago Electric Railroad. The east branch
of the DuPage River is turned out of its southerly course by it.
In the southern portion of the glacier the warm sun melted
the ice on its top as ice and snow melt in the early days of spring.

68

A NATURALIST IN THE GREAT LAKES REGION

and the water, finding its way through cracks and crevices, flowed
along in a stream underneath the glacier. Such streams often
carried and then deposited material in elongated heaps of more
or less stratified gravel and sand. Now that the ice is gone, these
show as elongated hills known as eskers.

This glacial drift is made up of soil through which are scat-
tered bowlders, small and large, or if the material is sorted by
water, it is laid down in layers, coarse or fine according to the
speed of the current that carried it to the present location. The

FIG. 46.— Crystals; at left cubes of galenite, at right quartz with a single
quartz crystal in center foreground, in rear of it tourmaline crystal in matrix.

bowlders and stones are subangular and more or less scratched and
grooved. A large percentage of them are limestone, since the
bed rock for a couple of hundred miles to the north is also lime-
stone. But there are many samples of sandstone, quartzite,
granite, gneiss, schist, diorite, diaba'se, and greenstone that have
been brought into our region by the glacier from the ledges in
northern Michigan and Canada where are located the nearest
outcrops of these rocks in the direction from which the glacier
came.

A rock is either a mass of some one mineral or made up of
grains of several minerals. A mineral is a homogeneous inorganic

THE GLACIAL PERIOD 69

substance of definite or nearly definite chemical composition, and
it crystallizes into regular and constant form. Thus quartz, one
of the most common of all minerals, is an oxide of silicon, SiO2,
with some water added if in crystalline form. The crystals are
six-sided prisms with six-sided pyramids at each end, if perfect
(Fig. 46). This mineral may occur in great masses or it may

FIG. 47. — Piece of orthoclase feldspar showing cleavage

be merely one constituent of complex rocks. It is, for instance,
an essential element in granite.

Not many minerals occur as conspicuous ingredients in the
rocks of the Chicago region. It would be well to study these
few in the collections to be found in the local museums like that
of the Chicago Academy of Science or the Field Museum so as
to be able to recognize them. Small collections may be had
cheaply from any of the well-known dealers like Ward's Natural
Science Establishment, Rochester, New York. The following

70 A NATURALIST IN THE GREAT LAKES REGION

tabulation will give the distinguishing characters of the com-
monly occurring minerals. A few terms need definition at
the outset as they will be used in the descriptions. Certain
minerals like calcite, galenite, and feldspar have a tendency to
split easily along certain planes so that the pieces are bounded
by smooth surfaces. This is known as cleavage (Fig. 47).
Galenite cleaves into cubes, feldspar into blocks of which the
opposite faces are parallel while the adjacent faces meet in
angles that are either a little more or a little less than right
angles. Fracture is the surface produced when a mineral breaks
in any other direction than along its cleavage planes. Thus flint
has a conchoidal or shell-shaped fracture. Streak is the color
given when the mineral is rubbed on a piece of unglazed porcelain
or when it is scratched. Luster is the appearance when light is
reflected from the surface of the mineral. This may be vitreous
like the reflection from a freshly broken piece of glass, resinous,
pearly, silky, etc. — terms that carry their own meaning plainly.
One of the chief means of distinguishing minerals is the hardness.
So important is this that a definite scale of hardness has been
agreed upon. Thus, talc has a hardness of i, gypsum 2, calcite
3, fluorite 4, apatite 5, orthoclase 6, quartz 7, topaz 8, corundum
9, diamond 10. For ordinary purposes the hardness may be
indicated in a less exact way, still the numbers given after each
mineral indicated the hardness on this scale.

Sedimentary rocks. — As we have seen in the previous chapters,
sedimentary rocks are originally laid down as beds (i) of cal-
careous materials like shells, corals, or their water-worn frag-
ments, (2) beds of angular rock fragments, (3) of gravel, (4) of
sand, (5) of clay, or (6) of plant debris. Later these, by means
of cement, by pressure or by heat, acting singly or in unison, are
transformed to stone. The calcareous material, really calcite or
calcium carbonate, makes limestone a rock that can be scratched
with a knife, effervesces with an acid, and often contains fossils.
Angular rock fragments cemented together form a breccia, while

THE GLACIAL PERIOD 71

if the fragmei- -,, c waterworn, as gravel, the result is a pudding
stone or conglomerate. The sand beds transform to sandstone
and clay to shale, readily known by the ease of its separa-
tion into flakes. The plant material transforms into peat and
coal.

So soft they can
be scratched with
the fingernail

Easily scratched
with a knife

Chalk, 0.5-2.5

Chlorite, 1.5-4.0

Gypsum, 1.5-2.0

Kaolin, 0.5-2.5

Mica, 2.2-5.0

Galenite, 2.5

Serpentine, 2.5-4.0

Calcite, 3

White to gray, dull, crumbles in
fingers, no earthy odor when
breathed upon, effervesces with
acid.

A green mineral of pearly to
vitreous luster with greasy feel-
ing. It usually occurs in grains
or scales in basic rocks.

Many colors, streak always
white. Massive (alabastine),
fibrous (satin spar), foliated (if'
transparent called selenite).

Many colors, streak like color.
Feels greasy. Strong clay odor
when breathed on. Dull to
pearly luster; brittle.

Perfect cleavage; very thin
elastic scales can be obtained.
The black sort is biotite; the
colorless, gray, or pale green,
muscovite.

Lead gray, streak same. Metal-
lic luster. Very heavy; cleaves
in cubes.

Color, shades of green. Luster
greasy, waxy, or earthy. Feels
smooth or greasy. Compact and
amorphous, making a rock of
the same name.

Many colors, streak white to
gray. Always cleaves into
rhombs. Effervesces in dilute
acid.

A NATURALIST IN THE GREAT LAKES REGION

Easily scratched
with a knife
(continued)

Scratched with a
knife with dif-
ficulty

Scratched by
quartz but not
with a knife

Sphalerite, 3.5-4.0
(Zinc blende)

Yellow, red, brown, black.
Luster resinous when yellow.
Perfect cleavage. Brittle.

Chalcopyrite, 3.5-4.0 Brass yellow, often tarnished,
(Copper pyrite) then showing iridescence.
Streak green-black. Softer than
pyrite.

Dolomite, 3.5-4.0
(Pearl spar)

Mica, see above
Limonite, 5.0-5.5

Pyroxene or
Augite, 5-6

Amphibole or
Hornblendes, 5-6

Hematite, 5.5-6.5
Feldspar,* 6.0-6.5

Pyrite, 6.0-6.5
(Fool's gold)

White, gray, green, black.
Streak white. Transparent to
translucent. Crystals curved
like saddles.

Dark brown, streak yellowish
brown. Of ten fibrous; if earthy,
color is yellow. In cubical
crystals.

Green to black. Fracture un-
even to conchoidal. Usually in
short, thick, eight-sided prisms.
Cleavage poor; faces meet at 90°.

Brown, green, or black, darker
than augite. Fracture as above.
Luster pearly on cleavage faces.
Crystals long, slender, six-sided,
faces finely cross-striate. Cleav-
age faces meet at 124°.

Cherry red to iron black; streak
red. Metallic luster, massive or
fibrous or scaly.

Many colors, streak white.
Cleavage perfect, faces at nearly
right angles. Light colored,
orthoclase; darker, plagioclase.

Brass yellow, tarnishes brown.
Streak greenish black. Metal-
lic luster. Crystals, cubes or
dodecahedra. Harder than
chalcopyrite.

THE GLACIAL PERIOD 73

Olivine, 6.5-7.0 Green, streak white. Trans-

parent to translucent. Usually
occurs in rounded grains.

Quartz, 7 Color anything from black to

As hard as white. Luster vitreous or waxy

quartz in chalcedony. Fracture con-

choidal. Crystals six-sided
prisms ending in pyramids;
blue, amethyst, banded agate,
onyx, jasper. In massive
nodules occurs as flint.

* The term feldspar stands for a group of minerals. Orthoclase is a silicate of
aluminum and potassium — a "potash-feldspar." Its cleavage angle is a right
angle, or nearly so. It is usually light in color, white, gray, pink. It commonly
occurs in rocks in which quartz is present fairly abundantly and seldom associates
with the plagioclase group. This plagioclase group includes the soda-lime feld-
spars like oligoclase and labradorite. The plagioclases have an oblique cleavage
angle, and certain cleavage faces are marked with numerous fine parallel lines.
The plagioclases, especially the oligoclase and the labradorite, are strongly basic,
seldom occur with quartz in any quantity, often are present with augite or horn-
blendes. They are usually dark colored, blues, grays, or dull reds.

Igneous rocks. — Sedimentary rocks are largely formed from
the disintegration of previously existing rocks. The original
rock masses, together with many of those of later times, were
formed from the cooling of molten material. Such are igneous
rocks. When lava outpours on the earth's surface in volcanic
regions it forms rock as it cools — volcanic rock. Such rock
usually has a glassy appearance or, if it is crystalline, the crystals
of which it is composed are small, usually indistinguishable, for
it cools too rapidly to permit a thorough crystallization. Such
volcanic rocks are liable to be quite porous on account of the
bubbles of gas contained in the molten lava. The holes formed
by the included bubbles of gas may later be filled by material
deposited by percolating water. The grains of such deposited
minerals are naturally rounded, and the rock so altered is known
as an amygdaloid. Molten material, on the other hand, that
cools off slowly way down below the surface makes coarse-grained
rock, the crystals being large. Such rocks are called plutonic,
in distinction to the volcanic. If one mineral is present in large

74 A NATURALIST IN THE GREAT LAKES REGION

crystals while the others are minutely crystallized or more or
less glassy, the rock is called a porphyry. Plutonic rocks are
dense, since formed below the surface under great pressure.
Naturally there will be all intergrades between the plutonic and
the volcanic rocks, since the cooling lava may be in any one of
many situations from the deep-seated reservoir to the surface
flow.

The molten material differs greatly 'in chemical composition
in different regions of the earth and even two successive lava
flows from the same volcanic crater may be quite unlike. If the
lava contains much silica it is an acid lava and gives rise to rocks
with many silicates and much free silica or quartz. If, on the
other hand, it contains strong bases like calcium, magnesium,
and iron, it is a basic lava and the resulting rocks will contain
little free silica or quartz, though they will contain silicates of
the basic elements mentioned in the form of such minerals as
plagioclase, hornblende, augite, etc. The following scheme with
the brief characterizations that follow will aid in the determina-
tion of the igneous rocks of the Chicago area. Nothing like a
complete key or complete descriptions can be given here, and
the interested student will secure some good lithology and
study it in connection with the specimens of typical rocks found
in the museums. This scheme will help the observer to make a
start on interpreting the past history of a rock from its present
structure. Five rock groups are given in the order of their
increasing basidity so that, from left to right in the series, quartz
is becoming less abundant, the rocks are darkening in color and
increasing in weight as the plagioclases replace the orthoclase,
and the augite, hornblende, and olivine. at the end largely
replace even the plagioclase.

Vertically in each column the members of any group are
named from distinctly volcanic rocks down to those that are
wholly plutonic. Going down the column, the members of the
families are less porous, less glassy, the component crystals are
constantly larger, and the rocks increase in specific gravity.

THE GLACIAL PERIOD

75

The granites contain quartz and orthoclase, often with some
hornblende, mica, or augite. (The composition of the gneisses
is the same, but they show evidences of stratification — see below.)
If any one or two minerals are especially conspicuous, the granite
is named accordingly, as hornblende granite, biotite-hornblende
granite. If quartz is present in twin crystals in a matrix of
feldspar, giving an appearance of cuneiform writing on a feld-
spar background, the granite is pegmatite.

Granite-Rhyolite Group

Syenite-
Trachyte
Group

Diorite-Andesite
Group

Gabbro-Basalt
Group

Peridote
Group

Quartz and Orthoclase
Dominant

Orthoclase
Dominant:
Quartz
Absent or
Present in
Negligible
Quantity

Plagioclase and
Hornblende Dom-
inant: the Latter
Equaling or Ex-
ceeding the Feld-
spar in Amount

Feldspar (Lab-
rador! te) and
Pyroxene Dom-
inant: the Latter
Equaling or Ex-
ceeding the Feld-
spar in Amount

Feldspar
Absent or
Nearly So:
Hornblende,
Pyroxene,
Olivine, the
Dominant
Minerals

Rhyolite pumice (porous)
Rhyoliteobsidian (glassy)

Basalt tuff
Basalt breccia

Trachyte
(included in
the felsites)

Andesite
(included in the
felsites)

Basalt dolerite
Basalt

Granite (crystalline)
Other minerals may be
present but not dom-
inant giving biotite-
granite, hornblende-
granite, etc.

Syenite

Diorite

Diabase
(Oli vine diabase,
olivine gabbro,
green stone)

Gabbro

Peridotite

Porphyritic granite
Pegmatite granite

Diorite
porphyry

Diabase
porphyry

Syenite contains an abundance of orthoclase, usually the
red varieties and little or no quartz. Hornblende, mica, and
augite may any one or all be present. It is a plutonic rock and
therefore usually coarse grained. The corresponding volcanic
rock is trachyte, finer grained, more porous, and lighter in
weight.

In the diorites the dark feldspars are predominant, though
sometimes the lighter-colored plagioclases are abundant. Quartz

76 A NATURALIST IN THE GREAT LAKES R. -

is present and also often mica and hornblende but not in predomi-
nating quantities. The diorites are plutonic, the corresponding
volcanic rocks being the andesites.

Gabbro and basalt are respectively the plutonic and the
volcanic members of the next family. They are dark, heavy
rocks with labradorite and augite as the predominant minerals.
Biotite, chlorite, magnetite, pyrite, olivine, etc., may be accessory
minerals. The gabbro is distinguished from the diabase by its
coarser crystallization and the large quantity of pyroxene it
contains. The presence of chlorite in these rocks gives them a
distinct green color and they are then known as greenstones. It
is difficult to distinguish the finely crystalline ingredients of
trachyte and andesite in the field sufficiently to distinguish
them, so they are usually called collectively "felsite" as dis-
tinguished from the darker and heavier basalt.

Metamorphic rocks. — Both sedimentary and igneous rocks
may be altered by pressure, crumpling, heat, and other agencies,
so that their original character is quite changed; such rocks are
called metamorphic rocks. Thus the limestones become crystal-
line and transform to marbles, as do also the dolomites. The
effervescence with acid still distinguishes them. Dolomitic
marbles effervesce only in strong or hot acid, the ordinary marble
in cold, even weak, acid. Sandstone is compacted, the sand
grains fused to make quartzite — a rock that may have any color
but can be distinguished by its hardness and conchoidal fracture.
It is not as vitreous in luster as is quartz itself, and shows more
or less its granular character. Shales are changed to slates,
recognized by their easy separation into thin layers like roofing
slate. Sedimentary rocks composed of the disintegration of
granites are by metamorphosis altered to schists and gneiss.
The latter contains the same minerals as granite, but there is
evidence of stratification and the crystals or grains of the com-
pressed minerals are arranged with their long axes in one plane.
If the compression has been so great as to flatten the component
grains or crystals into scales, the rock becomes a schist, easily

THE GLACIAL PERIOD 77

broken down by the fingers, especially when it is somewhat
weathered. Schists are commonly named from the mineral that
is so predominant as to give them their chief character, as mica
schist, chlorite schist, etc.

Granites seem also to have been transformed directly by
metamorphic agencies into gneiss and the schists, so that the
end result of metamorphism on such igneous rocks and on sedi-
mentary rocks derived from them may be identical.

CHAPTER V

LAKE CHICAGO AND ITS OLD SHORE LINES

S THE ice sheet finally melted (Fig. 48)
and retreated farther north there formed
between the Valparaiso Moraine and
the front of the glacier a lake, called
now Lake Chicago (Fig. 50). This had
its outlet through the gap in the mo-
raine known as the Sag. Two streams
from the lake — one on the north, one on
the south of Mount Forest Island (Fig. 53) — converged to this
point. It was probably just chance inequalities of deposition
that determined the location of these two channels, thus form-
ing Mount Forest Island, but the Sag was likely predetermined
by the fact that here ran the old preglacial valley, a deep rock
cut, which though partly filled by glacial drift still made a distinct
break in the restraining moraine. Besides Mount Forest Island
another isolated mass of drift stood out of the water in the
Chicago region, namely Blue Island. This now stands above
the level of the Chicago plain, once the old lake bottom, as a
ridge several miles long and one-half mile or so wide stretching
north from the town of Blue Island to Beverly Hills. The
Rock Island suburban line runs close to its east side. It is
encountered as an abrupt rise on Western Avenue about Eighty-
seventh Street. Anywhere along its crest one looks westward
over level country, old lake bottom, to the distant hills of the
mainland of the moraine or of the other islands.

Lake Chicago stood at one level for a long time, long enough

for its waves to eat into the hills along its shores and deposit

extensive beaches of sand just as Lake Michigan is doing now

along its present shore line. The highest of these beaches stands

78

LAKE CHICAGO AND ITS OLD SHORE LINES

79

at a level some sixty feet above the present lake level (581 feet
above sea- level) . It is by following these plainly marked beaches
that the position of the shore lines of early Lake Chicago is
determined (Fig. 49). On the map (Fig. 53, page 85), can be
traced the shore line of what is known as the Glenwood stage of

FIG. 48. — The Wisconsin ice sheet at its maximum. Border of ice represented
by heavy feathered line.

Lake Chicago (Fig. 50), so named because the beaches are par-
ticularly conspicuous at Glenwood near the Industrial School
(Chicago & Eastern Illinois Railroad). Northwest from this
point the old beach runs to the north of Homewood (on the
Illinois Central Railroad) about a mile southwest of Rexford
(on the Rock Island) to the north of Palos Springs (Wabash).
It is plainly seen on the east side of Mount Forest Island (driv-
ing west on Ninety-fifth Street) or in approaching the island from
Summit on the Chicago and Joliet interurban. At McCook

8o

A NATURALIST IN THE GREAT LAKES REGION

(Atchison, Topeka & Santa Fe Railway) and to the north of
La Grange (Chicago, Burlington & Quincy Railroad) it is par-
ticularly plain, marked by steep cliffs that have been more or
less obscured by the later erosion and deposits. Galewood
and. Norwood Park are on it. Thence it runs northeast and

FIG. 49. — An old shore line of Lake Chicago

terminates in the Chicago region at the present lake shore in
high bluffs at Winnetka.

In the northern part of Winnetka, a short distance south of the pumping
station, the cliff and terrace of the Glenwood stage appear halfway up the
lake cliff and extend inland with pronounced form for three-quarters of a
mile. The terrace is about 55 feet above Lake Michigan .... behind it
the bluff rises to a height of 20-30 feet, with a very steep slope.

To the east of Glenwood the shore line swings southeast toward
the lake, passes through Furnessville, runs roughly parallel to
the present shore, and abuts on the shore north of New Buffalo.
Notice Desplaines Bay on the map (Fig. 53), into which the
river now bearing that name then emptied. See also the sand

LAKE CHICAGO AND ITS OLD SHORE LINES

81

spit at the mouth of this bay and the spits at the ends of Blue
Island. There was a great branching spit running south and
west from a point below the present Winnetka reaching Niles
Center, which spit then inclosed Skokie Bay and now forms the
irregular eastern border of Skokie Marsh. The waters of the

FIG. 50. — Lakes Chicago, Saginaw, and Maumee. Lake Maumee at an
earlier stage was more extensive and outletted down the Wabash Valley as indicated
by dotted lines. All three lakes now discharge through the Chicago outlet. This
represents about the Glenwood stage of Lake Chicago. Modified from Leverett
and Taylor.

lake, moving toward the outlet or currents set up by the prevail-
ing north winds checked by these projecting points, dropped
their load of sediment in sand bars. The wash of the waves
piled the material up above the lake level in these spits, just as
they are formed along the lake shore today by the same agencies.
Lake Chicago continued to grow in size as the front of the
glacier retreated. But what is more important from our interest

82 A NATURALIST IN THE GREAT LAKES REGION

in its alteration of local topography, it changed its level, dropping
so as to expose the bottom, hereabout, long enough for vegeta-
tion to become rank and form extensive peat deposits. This was
probably due to the uncovering, by the retreat of the ice, of
some outlet to the north, at a considerably lower level than the
Chicago outlet. These peat beds are found in excavations such
as some made in Rogers Park and Evanston several years ago,
and they lie on the beaches of the Glenwood stage. They are
overlaid, however, by deposits of the next or Calumet stage.

The lake rose again as possibly the glacier advanced tem-
porarily and again covered the northern outlet. It assumed a
level about twenty feet below the Glenwood stage, 35-40 feet
above present level or 615-20 feet above sea-level. It again
outletted down the Desplaines Valley. Undoubtedly during the
Glenwood stage the valley had been deepened by river erosion.
When the old river came directly from the front of the glacier
before the lake was formed behind the Valparaiso Moraine, it
was heavily charged with sediment and built up an extensive
valley train as already described. But when the river became
the outlet of the lake, the debris held by the glacier was dropped
in the lake and the outflowing stream was clear, ready to pick
up a load in its rapid current instead of making a deposit. So
from the time Lake Chicago was formed the outletting stream
had been working to erode and carry away the silt, sand, and
gravel that it had earlier laid down. So the old valley formed
by the preglacial stream that came down the broad valley where
Lake Michigan lies and that continued down what is now the
Desplaines and Illinois valleys was filled below the terminal
moraines by the valley train deposited by the river that carried
the outwash from the glacier and still later was again partly
uncovered by the outlet of Lake Chicago.

This latter erosion was apparently checked in the upper
valley when the river encountered a rocky ledge below the sand
and gravel, a ledge running from the present location of Lock-
port to Joliet. This could not be worn away rapidly and so the

LAKE CHICAGO AND ITS OLD SHORE LINES 83

level of the lake was held at this point for a long period. During
this time the waves and currents made such inroads on the shore
and such extensive deposits that we trace them today in a series
of beaches and sand bars that are referred to this Calumet stage
(Fig. 51). The course of the Calumet beach can be traced on
the map (Fig. 53). The old Desplaines Bay was now dry land,

FIG. 51. — Lake Chicago at a later stage (the Calumet) and Lake Warren.
A tremendous volume of water must have been going through the outlet past the
present site of Chicago. After Leverett and Taylor.

and the river emptied into the lake near the present site of
Lyons. Salt Creek flowed in at the same point. Evidently in
the lake during the Glenwood stage a great sand bar had formed
in the lea of Blue Island and a smaller one out in the south channel
of the outlet. These now appear, the former as a portion of the
large island that included Mount Forest Island and Blue Island,
the latter as a separate islet, Lanes Island. Note the long sand

84 A NATURALIST IN THE GREAT LAKES REGION

spit thrust out from the north end of the large island, its elbow
at what is now Summit, sheltering a big bay then probably an
extensive marsh.

FIG. 52. — Lake Algonquin; some water was still going out of the Chicago
outlet but most of it discharged down the. Trent River Valley to Champlain Sea.
Note also the Hudson and Mohawk estuaries. This represents about the Tolleston
stage. After Leverett and Taylor.

Jefferson Park, Cragin, Riverside, Summit, Washington
Heights, Oaklawn, Dal ton, Thornton, etc., are all on the old
Calumet beach. Eastward it follows closely the Glenwood shore
line to which it is roughly parallel. There was a great offshore
bar built up at this stage. This now terminates near Rose Hill

LAKE CHICAGO AND ITS OLD SHORE LINES

Fig. 53. — Map of the Chicago plain and adjacent moraine.
^x'x Land bordering Lake Chicago at the Glenwood stage.
/// Added land as the lake dropped to the Calumet stage.
\ \ \ Land added by drop to Tolleston stage.

Land added by drop to present level in white.

Sand bars dotted.

86

A NATURALIST IN THE GREAT LAKES REGION

Cemetery and it is named the Rose Hill Bar. It runs north and
east through Rogers Park and Evanston, where for six miles it is
followed by "Ridge Avenue." It rises some twenty feet above
the surrounding plain. The outlet to the north of Mount Forest
Island was apparently partially blocked, possibly by the Summit
sand spit and the others that were formed offshore, so that at
this Calumet stage the main outflow was through the present
Lake Calumet region, past the south end of Blue Island along
the outlet to the south of Mount Forest Island. The great

FIG. 54.— When the outlet of Lake Chicago was chiefly to the south of Mount
Forest Island the swift river current, carrying rocks, wore grooves and potholes
in the limestone bed. They are seen here where excavations for the new canal
freshly expose the bed rock.

potholes in the bedrock here, uncovered in the construction of
the Calumet branch of the Drainage Canal, worn by rocks in
the grip of eddies, indicate a large and rapid river (Fig. 54).

The rock barrier in the bed of the outletting river at Lock-
port which held the lake at the Calumet level could not stop the
lowering of the valley floor indefinitely. The obstruction was
made up of the inclined strata of Niagara limestone against
which, near Joliet, lay much softer shale. The river had no
difficulty in cutting away these shales, but the limestone was a
more difficult proposition. However, the limestone strata were
so inclined that the river rushed down the incline, which was at

LAKE CHICAGO AND ITS OLD SHORE LINES 87

the downstream end of the obstruction, forming a rapids with
violent current that worked furiously at cutting out the rock.
Gradually the rapids ate their way through these strata until
finally they reached the upper end of the rock dam. The rock
barrier once removed, the stream rapidly cut through the gravel
of the old valley train to the lake and another drop in the lake
level occurred, of some fifteen feet. A reference to the map
(Fig. 51) will show that through the Chicago outlet was flowing,
during the Calumet stage, not only the waters from the front of
the Michigan lobe, but also that from much of the Saginaw and
Erie lobes. This great stream was undoubtedly a vigorous
worker.

So Lake Chicago assumed a new level, the Tolleston stage
(Fig. 52), some twenty feet above present lake level or about six
hundred above sea-level. It held it long enough to cut*a new
shore line and deposit extensive beaches. The location of these
Tolleston beaches is shown on the map (Fig. 53).

The main Tolleston beach abuts on the lake shore not far
north of the campus of Northwestern University which it crosses
from North Gate, running inland beneath Herck and University
Halls. It runs through the city on the east side of Chicago
Avenue and in South Evanston is followed pretty closely by
Clark Street. Thence it continues south of Calvary Cemetery,
through Rogers Park and Rose Hill, bordering the old Rose Hill
Bar. From Garfield Park to Hawthorne it is very plain. It is
easily traced east from Summit, thence southeast through
Auburn Park and Burnside. Stony Island, an island new born
at this Tolleston stage of the lake, appears here close offshore,
and the Tolleston beach is very plain on its northern side. From
Burnside the beach runs south through Kensington, then swings
east and follows quite closely the general present contour of Lake
Michigan.

It will be noted that both north and south outlets on either
side of Mount Forest Island are pretty well closed by the end
of this stage, for a great sand spit had been built all across the

88 A NATURALIST IN THE GREAT LAKES REGION

north outlet, a natural embankment later used by railroads
entering Chicago from the east. The Desplaines no longer
emptied into the lake but was flowing south through the channel
of the old outlet. Below the main Tolleston beach are one or
two others showing apparently considerable fluctuation at this
stage. It is thought that Lake Chicago had become a part of
the greater Lake Algonquin, which included Lakes Superior,
Michigan, Huron, and more (Fig. 52). It was discharging
through Lake Erie. Probably some of these Tolleston beaches
were the shore lines of this greater lake. There is evidence that
the level of the water in the lakes dropped considerably below
its present level when for awhile the great lakes discharged
through Georgian Bay, the river Trent across Ontario to an
arm of the sea in northern New York (Champlain Sea) (Fig.
52). But finally through a gradual rise in these northern areas
the level of the water rose to the present grade, and the discharge
through Lakes Huron and Erie was resumed.

It is interesting to note how human affairs are determined
by events that transpired hundreds of thousands of years ago,
long before man had even appeared on the earth. The route
followed by two great transcontinental railroads in entering
Chicago — the Chicago & Alton Railroad and the Atchison,
Topeka & Santa Fe Railway — is that of the old outlet of Lake
Chicago, and its location was determined by the presence of
the preglacial valley whose position was fixed by the lay of the
rock strata deposited in Paleozoic time. The same thing is
true elsewhere. The Lackawanna and the New York Central,
in leaving New York City for the West, follow the valleys of
old rivers that carried the main outwash from the glacier, and
their location was fixed by the lay of rock strata that were
deposited aeons ago. Lake Michigan, Desplaines River, and
the Illinois River were made a great north and south artery of
travel when the old preglacial valley continued past the present
site of Chicago down what later became the Illinois Valley. And
when the Valparaiso Moraine happened to so deposit that the

LAKE CHICAGO AND ITS OLD SHORE LINES 89

portage from the Chicago River to the Desplaines was fixed
within the present city limits, Chicago's site was practically
settled. Even the locations of our fashionable residence sec-
tions, streets, railroad approaches, recreation parks, and sewage
system were more or less completely settled by the deposits of
moraines, locations of old beach lines, sand spits, and dunes of
the old glacial lake.

CHAPTER VI

DISTRIBUTION AND ADJUSTMENT

]HE purpose of this and the succeeding
chapters is to show how the physio-
graphic features of the Chicago region,
the origin of which has been outlined in
the preceding pages, determine the dis-
tribution of plants and animals, not
directly but by shaping in large meas-
ure the interplay of those factors that
do condition the plant and animal life. The chief factors for
plants are available moisture and light; for animals, the oxy-
gen supply, food, nest-forming materials, light, heat, currents,
foes, etc. Furthermore, plants and animals are nicely adjusted
in structural peculiarities and habits to the complex of these
limiting factors, and it will be the aim of succeeding pages to
point out also some of these adjustments.

It is a matter of common knowledge that, the world over,
there is a zonation of life. The vegetation of the tropics is
totally unlike that of the temperate regions, and the life of the
latter zones is quite different from that of the arctic. The ascent
of a mountain carries the traveler through a succession of life-
zones, from the luxuriant growth about the base through scant
vegetation and disappearing animals to a bleak and almost
uninhabited peak.

Temperature is on the whole a, very great factor in the deter-
mination of the abundance and character of both plant and
animal forms. Locally its effect is to settle the distribution in
time rather than fix the place in which animal or plant shall
grow, for naturally there is no very great difference in tempera-
ture in the various parts of the Chicago area unless it be a

90

DISTRIBUTION AND ADJUSTMENT

contrast between the deeper parts of lakes and their surface
waters. But there is a seasonal distribution of both plants and

FIG. 55. — Spring flowers of the forest floor: Upper left, spring beauty, Claytonia
mrginica; upper right, toothwort, Dentaria laciniata; lower left, Dutchman's-
breeches, Dicentra cucidlaria; lower right, yellow adder's-tongue, Erythronium
amerieanum.

92 A NATURALIST IN THE GREAT LAKES REGION

animals locally. Thus we have a distinct spring flora. Note,
for instance, the early annuals of the oak woods — spring
beauties, anemone, toothwort, trillium, hepatica, Dutchman's-
breeches, dogtooth violet, bloodroot — these and others like them
are all plants that are up and in blossom before the trees are in
leaf to shade them (Fig. 55). They get through with their life-
cycle — bud and flower and fruit — here on the forest floor while
the great trees overhead are just beginning to stir with the thrill
of the spring awakening. These plants have found an unoccupied
part of the season, and they make the best of it. They all
possess underground stems loaded with stored food that enable
them to make this very rapid growth, then slowly accumulate
during months of shade a supply sufficient for the next spring.
Moreover, in many cases their tender leaves that appear while
frosts are still common are clothed in dense hair — a veritable
fur coat to protect them. They are replaced later by other
plants that have become adjusted to growing in the dense
shade of the summer under the trees. Those mentioned need
abundant sunlight to carry through their brief program of rapid
maturation.

The temporary grassy ponds that result from the melting
of the snows are the homes of a group of animals that appear
marvelously indifferent to the low temperatures of early spring;
they thrive in the ice-rimmed water. There is the so-called
fairy shrimp, Eubranchipus (Fig. 56^), not a shrimp at all, though
its airy grace and mysterious appearance make the rest of the
name appropriate enough. It is a reddish-brown crustacean,
a quarter of an inch long when first seen, but growing rapidly
to an inch in length. It swims on its back, waving nineteen
pairs of feathery legs to propel itself. The head bears a pair of
staring compound eyes. The egg sacks of the females are con-
spicuous early, and strings of slender eggs can be seen in the
semi-transparent body on their way to be discharged into the
icy water. The adults soon die; the whole life-history occupies
only a month or so of early spring. The eggs lie dormant in

FIG. 56. — Some fresh-water crustaceans a, Asellus, the water sow bug;
b, Gammarus, the bender; c, Palacmonetcs, the true shrimp; d, Eubranchipus, the
fairy shrimp; e, Canthocampus; f, Cyclops; g, Cypris, side and top views; h,
Daphnia, the water flea.

94 A NATURALIST IN THE GREAT LAKES REGION

the bottom of the pond. When it dries up they dry, too.
They may blow about in the wind to new locations. They
freeze with the winter cold; in fact they will not hatch until
they have dried out and frozen. And so they are ready to
start the next generation in the ponds of the following
spring.

Other inhabitants of these ponds are the red water mite,
Hydrachna; a tiny crustacean with a bivalve shell, looking like
a very small clam until it sticks out its feathery swimming
organs (Cypris marginata) (Fig. 56^) ; the water sow bug (Fig.
560); the bender (Fig. 566), a crustacean that swims rapidly
with even speed, but which when taken in the hand bends and
unbends rapidly; Cyclops, Daphnia (Fig. 56 /, h); some clado-
cerans; the green flat worm. Here, too, one may find, if low
prairie is near, the spring peeper, Chorophilus nigritus, that
marsh tree frog whose clear peep is almost like a bird note.
It takes to the ponds to lay its eggs almost before the ice is gone.
The eggs are laid in gelatinous clusters that fill the palm of the
hand and in the pond are attached to the grasses along the
margins or to sticks in the shallow places.

The frog's egg is admirably adapted to hatch on these cold
days. It is covered with a transparent jelly layer that retains
the sun's heat like the glass of a greenhouse. It has a black
upper surface that absorbs heat like a black dress. The egg is
laid so early that it avoids many of the insect larvae that would
later prey upon it. It is inconspicuous, its black upper surface
harmonizing well with the dark pond bottom when seen from
above, and its light under surface with the clouds when seen from
below, so that it easily escapes detection.

Just as there are an early spring flora in the woods and a
spring fauna in the temporary ponds, so there are early spring
plants and animals in the swamps, on the dunes and in other
typical localities. In each place the spring types are followed
by early summer types, by midsummer and autumnal species.
One need only call attention to this seasonal distribution to have

DISTRIBUTION AND ADJUSTMENT

95

it substantiated by many commonplace facts. Thus we name
many insects by the time of their appearance, as May flies,
June beetles, the fall army worm, etc. Just as the appearance
of the robins and the bluebirds marks early spring, so we think

20-60%
60- 80%
80-100%
100-110%
110-130%
130-150%
150-180%
180+ %

FIG. 57. — Map showing relation of rainfall to evaporation in Eastern United
States. Unmarked lower left, rainfall 20 per cent or less of the evaporation.
The other markings are explained on the figure.

of midsummer as butterfly time, and the chirp of the cricket as
the first voice of fall.

In the local place distribution of plants, moisture is of prime
importance, or rather the ratio between rainfall and evaporation.
If the water supply greatly exceeds the evaporation, then the
plant grows in a pond or marsh and is designated a hydrophyte.

96

A NATURALIST IN THE GREAT LAKES REGION

At the other extreme are the xerophytes, plants growing where
the evaporation tends greatly to exceed the water supply. The
open dunes give an excellent illustration of such conditions.

Unmarked (lower, left)— desert

— -^~ Semidesert

Western xerophytic forent, dwarf
junipers, etc.

~*ZZ~ Transition desert to grass land

V<y.'V/;,: Transition grass land to deciduous
••:- •''•'•'•<•' forest

• J* Deciduous forest

tyffffif, Transition to evergreen forest

A * Evergreen forest. No attempt is made
* + to distinguish northern and southern

vX'$ Grass land ^ ^> Swamp

FIG. 58. — Map of vegetation areas in Eastern United States. After Shreve

The great majority of plants grow where there is neither excess
nor dearth of water and are known as mesophytes. This ratio
of evaporation to rainfall is a very important factor in deter-

DISTRIBUTION AND ADJUSTMENT

97

mining plant distribution on a large scale as well as locally.
This is apparent from a comparison of the accompanying maps,
one (Fig. 57) showing the ratio of rainfall to evaporation in the
various parts of the United States, the other (Fig. 58) the forest,
prairie, and plains areas. The general coincidence of forest
distribution and of the areas occupied by prairies and plains
with the areas of a decreasing rainfall is very striking.

That physiographic features must affect the moisture content
of the soil is evident on reflection. A poorly drained area

Intensity of evaporation
Standard, open garden, Normal School
Sta. Ill, b. Mixed prairie and young fo
Sta. II, a. Grassy area, Panicum
Sta. II, a. Grassy area, Euphorbia
Sta. IV, a. Upland, open woods
Sta. HI, a. Silphium on black soil
Sta. II, a. Colony of 5. laciniatum
Sta. IV, b. Ravine slope, open woods
Sta. IV, c. Dense climax forest cover

FIG. 59. — Diagram of the relative evaporation in different prairie and forest
habitats, showing the great reduction in evaporation with the development of a
dosed forest canopy of a climax forest; Charleston, Illinois. After Adams.

develops swamps, bogs, and wet prairie. A rock surface is prone
to be xerophytic; so too will be the steep side of a clay bluff.
On the other hand, the side of a rock ravine may furnish hydro-
phytic conditions, for the sunlight penetrates so little that the
temperature is low, the evaporation is slight, and even though
water be not abundant, it may be so well conserved as to be
adequate to moisture-loving plants. The accompanying dia-
gram (Fig. 59), modified from Adams, will show how great differ-
ences there are in rate of evaporation in contiguous regions, and
also that temperature differences, while not great, may still be
sufficient to influence animal and plant distribution.

98

A NATURALIST IN THE GREAT LAKES REGION

Many marked structural peculiarities and adaptive life-
habits go along with the ability of the plant to endure drought
or excessive moisture. Since the loss of water goes on largely
through the leaves, the leaf surface of the xerophyte is often
reduced in proportion to its volume by the leaf being needle
shaped rather than flat and thin. The leaf surface may be
covered with hairs, and so evaporation becomes reduced, or the

FIG. 60. — The cactus, Optmtia Rafinesquii, in fruit in the dunes

surface may be covered with impervious wax; such a weed as
the mullein, growing in open waste territory, is a familiar example
of the former, and the glossy-leaved plants of the ground
stratum in the pine dunes — like the wintergreen, shinleaf, and
prince's pine — are examples of the latter, as is also the very
common field milkweed. The oak leaf and that of the cotton-
wood are both thicker and glossier than the leaf of the hard
maple or beech that grows in the mesophytic conditions of the
climax forest. The leaf stem or underground portions of the

DISTRIBUTION AND ADJUSTMENT 99

plant may be thick and succulent, storing up water in time of
plenty to use in time of drought. The common cactus of the
dunes is a good illustration (Fig. 60). The plants growing where
moisture is lacking often develop an extensive superficial root
system to gather up the dew and the showers before the water
has time to dissipate or sink deep into the parched soil. One
can pull out fine stringlike roots in the open dunes that run just
below the surface for hundreds of feet to the tree or bunch grass.

FIG. 61. — The six-lined lizard, Cnemidophorus sexlineatus

Many of the animals of the open dunes are in hiding during
the day, some of them like the burrowing spider, Lycosa wrightii,
in holes that run down to the cool and moist soil layers. The
surface of the sand is covered in the early morning with the fresh
tracks of many animals that have been out during the cool
of the night to satisfy their needs, while the same areas are
apparently uninhabited by day. The six-lined lizard (Fig. 61),
that like the cactus is a desert form left in this sandy oasis
by the lake, excretes its uric acid in solid form, a conservation of
water common to many reptiles.

100 A NATURALIST IN THE GREAT LAKES REGION

The light relation determines not so much where the plam
grows as its habits of growth in a locality fixed chiefly by th(
water supply. Thus, some plants are said to be shade loving
They are found forming the ground stratum in the forest witt
other plants, a shrub stratum, over them, plants less able tc
endure the shade, though they in turn are overgrown by a tree
stratum whose members insist on getting up into the full glare 01
the sunlight (see Fig. 297). The entire association is due to the

IQO+X

FIG. 62. — Diagram showing relative evaporating power of air as influencec
by prairie and forest vegetation. After Adams.

mesophytic conditions that all need, and probably the stratifica-
tion is due quite as much to the relative amounts of evaporation
(see Fig. 62) as to the varying light intensity. How dim the
light is in the ground layers of the forest becomes apparent in try-
ing to take pictures in the beech-maple woods; the exposure meter
indicates an intensity one-twentieth that of the surrounding
open pastures; so undoubtedly the light factor is to be regarded
as. of great importance. This is made more evident when the
fact is recognized that the same shade-loving plants found on
the forest floor are also often found in the rock ravine. Thus, the
clearweed, the touch-me-not, and such characteristic ferns as the
beech fern, the fragile fern, and the spleen wort, A splenium angusti-
folium, are common in both locations (Figs. 270, 273, 274, 395).

DISTRIBUTION AND ADJUSTMENT

101

Some plants growing in the intense light of the marsh and
prairie have very interesting habit adaptations that avoid the
intense light and heat of midday. The upright position of
the leaf in the grasses, the iris, and cat-tails accomplishes this,
for the edge or tip of the leaf is presented to the midday glare,
the broadside of the leaf catch-
ing the less intense early
morning or late afternoon sun.
The common lettuce (Fig. 63)
and the compass plant, Sil-
phium laciniatum, both have
the habit of turning their
leaves so that they are in a
vertical position at noon, the
tips north and south, one edge
up, the other down, so show-
ing the edge rather than the
broad side to the noon light.

No single line of demar-
cation in the distribution of
animals is as^ clear cut as that
between the water animals —
the water breathers as they
are commonly called — and the
air breathers. Of course in each case the oxygen in the air is the
important element taken, but in the water forms this is absorbed
from the supply dissolved in the water, while the others take it
directly in the respired air. Probably in the course of evolution
most animal as well as plant life was aquatic in its origin. The
hydrophyte and the hydrozooid are the primitive types, and
these early forms lived not only where water was abundant
but they lived under water. Such an existence necessitates on
the part of complex forms some special device for taking the
needed oxygen, for every living thing must have this essential
gas since it is only by constant oxidation that the energy supply

FIG. 63. — A compass plant, wild let-
tuce, Lacluca scariola.

102 A NATURALIST IN THE GREAT LAKES REGION

is maintained, by means of which all live and move and have
their being. The simple plants and animals can absorb the
oxygen and give off the carbon dioxide, together with other
waste products of combustion, directly through the moist skin.
But the higher types have needed to develop gills or similar
structures and some sort of circulation to take the gas to the
working cells. The more complex plants growing totally sub-
merged have their leaves dissected so that they consist of numer-
ous threadlike filaments or else they are long and narrow,
ribbon-like, so that every part of the leaf is near the oxygen
supply of the water. See, for instance, the leaf of water milfoil,
of bladderwort, of hornwort, all common to our ponds or streams
(Fig. 64). The water buttercup at times grows submerged, again
only partly so. The submerged portions have leaves that are
finely dissected, the aerial portions the usual buttercup leaf. It is
interesting to note that the animal gill is built on the same general
plan as the submerged leaf, a series of filaments, sometimes
branched. In the animal these are provided with vessels that take
up the needed oxygen and carry it to the distant internal organs.
The transition from water-inhabiting animal to land dweller
is seen in the life-history of our common toad. The eggs are
laid in the water, hatch into tadpoles that are vegetarians, and
breathe by means of gills. In time these develop legs, resorb
their tails, come out on to the land, replacing the gills by lungs
and feeding entirely on insect food. When the first sea worms
crawled out of the water to make their burrows on land, a wealth
of food was awaiting them in their virgin hunting ground, for
the land was largely unoccupied by animal life. When some
primitive fish crawled out on the mud banks, using its fins as
legs — and there is one that does this still — it was rewarded by
a lot of food which others of its kind could not get. But soon
the earth swarmed with life, and even the air supported a full
complement. Then, apparently some of the animals that earlier
forsook the water for the land or air went back again to hunt in
the water, and no more interesting series of adaptations is to

FIG. 64. — Leaves of water plants: a, Anacharis; b, Ceratophylhim or hornwort;
c, Caboma or water moss; d , Myriophyllum or milfoil; e, Utricularia, or bladderwort.

104 A NATURALIST IN THE GREAT LAKES REGION

be found than those enabling the land animals to live in the
water. Insects likely evolved from land forms and never did
live in the water until some of them took to it as a secondary
consideration. They are primarily air breathers, taking the
air in through numerous spiracles on the sides of the body to a
system of internal, ramifying air tubes. When they took to the
water they were forced to strange devices. Some diving beetles
like Dytiscus and some of the Hemiptera like the giant water
bug carry down a supply of air between the concave back of the
abdominal portion and the overlying convex wing covers. The
spiracles or breathing pores, which on most insects are on the
sides of the abdomen, are now on its top, which is the bottom of
the air chamber. Other animals enmesh enough air in the hairs
of body and legs to last them awhile; they seem to carry a film
of silver over the parts, the air film reflects so much light. The
common water scorpion has a long air tube at the posterior end
of the body so it can stand submerged on some aquatic plant and
still breathe through its air tube, the open tip of which is kept
at the surface (Fig. 212).

Even the spiders have taken to the water. Some common
locally walk on the water and count it no miracle, they even run
with celerity, capturing flies and gnats out of the reach of their less
fortunate kind. One, the diving spider, hunts under water, even
spins its silken nest below the surface. This nest is cup shaped , the
opening down, and the adult spider carries down to the eggs and
young a supply of air enmeshed in the hair of abdomen and legs
that it scrapes off so as to keep the cup full until the young are
old enough to come to the surface for their own supply (Fig. 213).

Some insect larvae are also air breathers and must come to
the surface to renew their supply. Such, fortunately for us, are
the mosquito larvae that we may exterminate by oiling the ponds
and ditches where they breed, so they cannot get to the top.
Such, as also the adult insects already described, are really air
breathers. But there is a host of insect larvae that are true
water breathers, taking in the oxygen by means of gills. These

1

DISTRIBUTION AND ADJUSTMENT 105

may be platelike structures, as in the damsel-fly nymph, or they
may be filamentous, as in the larvae of stone fly, May fly, or
whirligig beetle (Fig. 212). In the nymph of the common dragon
fly respiration is accomplished through the wall of the large
intestine, and a special chamber for the purpose is attached to
this organ, the water flowing into it through the anal opening.

Snails, clams, and fish have largely remained water breathers,
as have also most of the crustaceans. Some of the latter like
the land sow bug have taken to damp situations on land, as under
old logs and under the bark of stumps. The common chimney
crayfishes live much of the time out of the water near the tops
of their burrows, still breathing however by gills (see Fig. 379).
Many snails have come to be land dwellers, always in damp
situations, though, but still they breathe by means of a lung as
do even some of the pond forms. Locally we have no fish that
live out of the water, but there are such that run around on the
mud banks or even climb logs and inclined tree trunks in search
of insects; and in some — the African lung fish, for example —
respiration is accomplished in the air by means of the modified
swim bladder, an organ that in most fish is a float, but that
serves in this one the purpose of a primitive lung.

We do have examples in abundance of the higher vertebrates
that have taken to the water as a hunting ground and must
modify their air breathing to suit the exigencies of the case. The
frogs, turtles, some snakes, such birds as the grebes, and mammals
like the muskrat are cases in point. The muskrat has ring
muscles about its nostrils by the contraction of which he can
close these openings when he dives. The bones of grebes have
spongy interiors as indeed do those of all birds. The lung
cavities connect with these porous portions so the air-supply
that can be taken below water is increased. The frog spends
its winter entirely submerged, hibernating in the mud at the
bottom of the pond. Its mouth and nostrils are then closed
air tight and what respiration goes on is accomplished through
the skin, a return to the primitive method.

ip6 A NATURALIST IN THE GREAT LAKES REGION

The amount of oxygen contained in the water plays a very
important part in determining the distribution of the water-
breathing species. Some can live only where there is an abun-
dance of it. Thus, some sorts of insect larvae, snails, and fish
are found only in the rapids of the brook where the constant
turmoil of the water brings in an abundant oxygen supply; such
will not live at all in the nearby quieter reaches. Other kinds, on
the contrary, can get on very well even in the stagnant pools
where the decomposing organic debris is abundant, the oxygen
content low, and the carbon dioxide content high. The details
of such distribution will be considered in a later chapter on the
brook community.

Another exceedingly important factor in determining the dis-
tribution of animals, probably the most important locally, is the
location of the food supply. Thus one sort of animal may feed
on a single species of plant or those of one genus, and then its
distribution is determined by that of its food plant. Anosia
plexippus, the monarch butterfly, is found the world over only
where the milkweed grows . This i s not only because the butterfly
feeds upon its blossoms, by no means exclusively, however, but
because the young feed on the leaves. Similarly the young of the
anglewing butterflies are reared on violet leaves and locally they
are abundant along the borders of wood or on moist prairies where
the violet abounds. One hunts for the pawpaw butterfly,
Papilio ajax, and for the spicebrush swallowtail, Papilio troilus,
only in the climax forest, though of course occasionally one may
wander some distance from its customary habitat. This mobility
of animal life as contrasted with the fixity of most plants makes
it more difficult to fix the limits of animal associations ; and yet,
making due allowance for the wanderer, they are quite as definite.
So important is the food plant that one could almost name animal
communities after the plants that serve as centers of attraction,
either directly as a food or indirectly by harboring animals that
are the prey of the carnivorous types. The common milkweed
has such a host of visitors — nearly four hundred, though not all

DISTRIBUTION AND ADJUSTMENT

107

in any one locality — that the group may be collectively called
the milkweed association. So we may speak of the corn plant
association, a group of plants and animals that directly affect the
crop and so assume large practical significance. Such a grouping
of animals would, of course,
make as many societies as
there are food plants, a multi-
plication of detail that fortu-
nately is obviated by the fact
that plants are grouped into
societies by the interplay of
certain factors, so that the
animals, as far as the food
factor is concerned, tend to
a like grouping. This will
appear in detail in the suc-
ceeding chapters.

This relation of a specific
animal to a particular plant
as its source of food is the
foundation of some of the
most remarkable adaptations
to be found in nature. The
nectar of the flowers, much
sought by insect epicures, is
available only to a favored
few. Thus the common weeds,
butter and eggs and the closed
gentian (Fig. 65), both bear blossoms that shut with so firm a
spring that only the strong and heavy bumblebee can force an
entrance. He pays for their hospitality by carrying the pollen
so essential to flower fertilization and seed production. A rosin
weed common on the prairie, Silphium perfoliatum, bears water
cups, ensheathing the stem, formed by the bases of the leaves
(Fig. 66) . These effectually keep crawling insects away from the

FIG. 65. — The closed gentian, Gentiana
Andrewsii.

io8 A NATURALIST IN THE GREAT LAKES REGION

blossoms so the nectar may be reserved for the flying forms that
alone serve the plant in pollination. The wild pink accomplishes
the same object by rings of sticky substance exuded on its stem
at the nodes. Flowers with long tubular corollas like evening
primrose, trumpet vine, and Jimson weed are so deep that only
insects with long sucking tubes like the moths and butterflies
can reach the nectar, though sometimes the bumblebee bites
through the base of the blossom and steals a meal. The hound's
tongue, whose blossom is the color of aging
meat and which has a corresponding odor,
is visited chiefly by flies that seem partic-
ularly adapted to enjoy its sweets and to
transfer its pollen. Sometimes a flower is
so constructed as to require the presence
of a single sort of insect to take out and
carry its pollen; such is the case with
the Yucca, grown as an ornamental plant
in our gardens and dependent on the
yucca moth that is always associated
with it.

On the blossom clusters of a fall aster
FIG. 66.— Cup formed with white-ray flowers and yellow-disk

about the stem at base of J

leaf petioles, Silphium flowers one often finds a' spider that has a
perfoliatum, the cup yellow body and white legs. Lying thus

plant. i i i • i • •

concealed by its harmonious coloring, it
pounces on the visiting flies and so secures its food.

There is a plant louse or aphid that feeds on the roots of our
common field corn. It in turn furnishes to the common brown
ant a fluid excretion that serves as food and seems to be highly
prized. The ant takes the eggs of the aphid into its burrows in
the fall, rears the aphids, and in the spring sets them out to feed,
on the tender shoots of weeds until such time as the corn germi-
nates, when they are transferred by the ants to the corn roots.

Light is an important factor in the distribution of animals.
Thus many species inhabiting the ground, the subterranean

DISTRIBUTION AND ADJUSTMENT 109

fauna, are repelled by strong light. Such is the case with the
earthworm. An electric flash light will reveal in the garden or
forest at night many earthworms, their anterior ends projecting
from the burrows in search of decayed leaves, their chief article
of diet. The bright light causes their instant withdrawal. The
sow bug, woods cockroach, bark beetles, wood borers, slugs, and
many spiders prefer the dark or the dim light and are to be found
by day only in their retreats under bark or stones or in similar
situations.

There is a whole host of water forms that, while minute, are
the chief source of fish food. They are so sensitive to light that
they migrate from the deeper waters to the surface and back
again as the light wanes or brightens. There are protozoa,
rotifers, and many tiny crustaceans in this association, together
with a variety of microscopic plants on which they feed. Alto-
gether this assemblage of living things, a floating or free swim-
ming population, is known as plankton. In Turkey Lake, Indiana,
at the time of its maximum, it constitutes more than one-half
per cent by volume of the water; in Lake Michigan scarcely a
thousandth as much. Such a density as that in Turkey Lake
means more than fifty million organisms to the quart. Kofoid
found in the Illinois River at the State Biological Station about
five millions per quart, a million of which were animals. Since
tiny fish feed on these organisms they follow the plankton in its
diurnal migration, and the larger fish that are carnivorous go along
too. Any fisherman knows that trolling for bass is best in the
early morning or late afternoon, and that luck is better on a
cloudy day than a bright one. The plankton and the small
fry are near the surface in the dim light, and so, too, are the big
fellows that feed upon them and that may by mistake try the
fisherman's lure.

Nesting sites and nest-building materials are factors that
help to determine animal distribution. The muskrat and his
northern relative, the beaver, are found along the streams, not
alone because his food is here abundant, but also because the

no A NATURALIST IN THE GREAT LAKES REGION

material for the house is here. The cliff swallow prefers natural
rock walls beside the water to which to affix his mud jugs for
nesting purposes. The woodpecker must live in the forest, not
only because his food is there, but also because he needs a tree
for his nest site. The marsh wren away from the marsh would
probably find it more difficult to find substitute for the rushes
she uses to make her globular nest (see Fig. 345) than she would
to secure her insect food. Shelford found that, giving the tiger
beetle, which is found on the clay bluffs along the shore, oppor-
tunity in the laboratory to
deposit eggs on steeply in-
clined and level clay, sand,
and loam, in all cases the
females chose the clay in
which to deposit the eggs
and that two-thirds of the
holes made in oviposition
appeared on the steep clay.
Complex adaptations, both
of structure and of habit,
have arisen in connection
with the use of specific loca-
tions or of particular mate-
rials in nest building. A
single instance must here suffice. In the cotton wood zone
in the Dunes there is a digger wasp that excavates a burrow
in the sand in which to deposit its eggs (Fig. 67). The
wasp is a little larger than a house fly. It stands on the
sand to dig, and proceeds very much like a dog digging a
hole in the ground. It uses the forefeet as excavating tools
and throws the dirt out from under its body between the
hind legs. It makes the dirt fly, too, at a great rate. The
animal's front foot is expanded and provided with bristles along
the edge that further enlarge it and make quite an efficient
digging tool. The burrow usually starts on a sloping hillside

FIG. 67. — Digger wasp of the Dunes,
Bembex spinolae, X4. Below, the front
foot, Xio.

DISTRIBUTION AND ADJUSTMENT in

and runs in, inclining downward from the mouth. It is three
or four inches long. In digging it the wasp cannot throw the
sand out from the far end at once, but must move it several times,
about an inch each time, by the method already described.
While digging she comes to the mouth of the burrow frequently,
backing out always, stands still a moment, and goes back to
work unless some inadvertent movement of the observer scares
her, when she flies away to return shortly if all is quiet. The
burrow completed, the mouth is closed, the wasp throwing the
earth into it from all sides, changing her position repeatedly to
do this. Then she flies off to secure insects with which to stock
her excavation. She apparently uses dead flies chiefly, which
she secures from the dead insects washed up by the waves along
shore. On her return with a fly she drops it on the sand near
the nest site. She runs around erratically to locate the hole
exactly, uncovers the opening, quickly seizes the fly, and goes
in with it. She reappears almost immediately, covers the open-
ing, and flies off for another. When four or five flies are secured
she remains in the burrow somewhat longer with the last,
emerges backward as usual, and then spends considerable time
closing the opening and pawing the sand about until all trace
of her work is obliterated. Presumably the egg or eggs are laid
in the burrow, possibly on the flies that are to serve as food for
the growing grubs. The most remarkable thing in this whole
story is that when, after many days, the young female emerges
from her gravelike nursery she shortly proceeds to dig a hole,
stock it with flies, lay the eggs, and cover up the nest with con-
summate skill, yet she has received no instruction, has not even
seen the job done. Somehow in her nervous system is registered
the racial instinct, and she goes through the whole performance
unerringly, untaught.

CHAPTER VII
THE DUNES AND THEIR PLANTS

|O REGION about Chicago manifests such
rapid changes in physiographic features
as the dune region, and nowhere are
the effects of these changes more ap-
parent on the distribution of plants and
animals. It is, therefore, a very favor-
able region for an initial study of plant
and animal societies.
It extends from Gary east along the shore of the lake and
well up the eastern shore. The area is from a quarter of a mile
to several miles in width and with occasional interruptions where
clay bluffs come to the shore it is a hundred miles or so long.
In general it consists of a succession of sandy ridges that are
roughly parallel to the lake. These vary in height; the crests
of the tallest stand 200 feet above the level of the lake. Those
nearest the shore are quite barren, but those farther back are
increasingly covered with trees and associated shrubs and
herbs. Between these steep-sided hills are valleys occupied
often with long narrow ponds or with marshes and swales (see
chap. ix).

The effective storm winds in the Chicago region come out
of the northwest. These pile up the waves that erode the shores
and heap the sand upon the beaches. After a heavy storm a
newly formed sand bar offshore is a common sight (Fig. 68).
Since the shores of Lake Michigan lie north and south, the effect
of these furious winds is to tear down the lateral shores by wave
action and drive the debris by currents gradually southward.
Ultimately this debris will be pulverized by the waves, deposited
in bars, and thrown up in sandy beaches on the east side and the

THE DUNES AND THEIR PLANTS 113

south end of the lake. These same stiff winds pick up this sand
after it has dried out on the shore, and carry it inland. So the
winds that blow vigorously inshore are sand laden, ready to
scour with the vigor of a sandblast but also ready to deposit
wherever their velocity is checked.

Clumps of growing plants are the most effective agencies in
checking the wind and causing deposition. Wherever the bunch

*

,JP

FIG. 68. — A newly formed sand bar

grass is growing, or where a grapevine or a low juniper spreads
its interlaced branches on the surface of the sand, there the sand-
laden air driving into the mass of vegetation is checked and so
deposits some of its burden before it escapes (Fig. 69). But such
sand heaps are small. The interlaced stems and branches of
young trees and shrubs make the most successful device for
enmeshing the sand and forcing the wind to deposit it in larger
dunes. A clump of red-osier dogwood or a thick stand of
cottonwoods are buried quite rapidly, and did they not grow

U4 A NATURALIST IN THE GREAT LAKES REGION

more rapidly than the sand piles up, they would be completely
engulfed by the drifting sand.

A dune, therefore, usually starts on some low-lying area near
the shore where the sand is sufficiently moist to allow many
cottonwood seeds to germinate, yet far enough from the storm
beach so the seedlings are not uprooted by the heavy waves.
Such a low, moist germination bed is known as a panne (Fig. 70) .
That cottonwoods are the predominant growth in such a locality
is due to the fact that these poplars are the commonest trees in

FIG. 69. — Small dunes held by bunch grass and prostrate juniper, Jimipcrus
horizontalis.

the neighborhood, as will be explained shortly, and also because
their seeds are small, tufted with a silky pappus that insures
their ready transportation by the wind. Other plants that might
take kindly to such a place, like the red-osier dogwood, have
seeds that are not wind-blown. A wagon crossed a low area
near the lake west of Mineral Springs in the spring of 1912. The
ruts left in the moist sand facilitated the lodgment of poplar
seeds, and the next year a double row of seedlings was found and
photographed on the spot (Fig. 71). In two years' time a dune
was forming, as is seen from the photograph of the same spot
in 1915. In fact, in that time the sand had piled up somewhat
over two feet, and now it is shoulder-high.

THE DUNES AND THEIR PLANTS

We shall have occasion to remark constantly in the succeed-
ing chapters on the adaptation of particular plants and animals
to specific environmental conditions. Indeed it is to be the
major purpose of the remainder of the book, to show how plants
and animals are grouped in societies that are determined by the
ability of the several organisms to endure similar conditions. In
the dune region the associations are roughly parallel to the shore
and for plants succeed each other in the following order: (i) the

FIG. 70. — A panne near Miller, Indiana

beach association; (2) the fore-dune association; (3) the cotton-
wood association; (4) the pine association; (5) the black oak
association; (6) the mixed oak association; (7) the oak-hickory
association; (8) the maple-beech association.

Along the border of the lake is the wave-swept beach, where
no living thing can maintain permanent residence. Even here
there are transients among the animals as will be explained
shortly. There is a stretch of wind-blown, shifting sand, the
storm beach pounded by breakers raised by the heavy winds;
this also is nearly barren of life. A few annuals grow here dur-
ing the summer when severe storms rarely occur. The sea rocket

n6 A NATURALIST IN THE GREAT LAKES REGION

FIG. 71. — Upper: A double row of cottonwood seedlings near Mineral Springs,
Indiana. Lower: The same two years later. Note the forming dune is nearly
knee-high.

FIGS. 72-80: Fig. 72.— Sea rocket, Cakile edentula; Fig. 73.— Bugseed,
Corispermum hyssopifolium; Fig. 74 — Beach pea, Lot hyr us maritimus; Fig. 75. —
Cinquefoil, Potentilla Anserina; Fig. 76. — Wormwood, Artemisia caudata; Fig.
77. — Rye grass, Elymus canadensis; Fig. 78. — Winged pigweed, Cycloloma atriplici-
folium; Fig. 79. — Green milkweed, Acerales viridiflora; Fig. 80. — Seaside spurge,
Euphorbia polygonifolia.

Ii8 A NATURALIST IN THE GREAT LAKES REGION

and bugseed are the most common plants. Back somewhat
farther the pioneers of vegetation begin to get a foothold in the

permanent beach association;
such are the beach pea, beach
cinquef oil, wormwood, cocklebur,
and sand thistle.

The sea rocket (Fig. 72) is a
plant with succulent stems and
thick fleshy leaves. The flowers
are light purple, appearing
like those of the garden radish.
The pods are two-jointed. The
bugseed (Fig. 73) is an annual
with slender awl-shaped leaves.
The fruits are numerous, small,
hard, and have a winged mar-
gin. The beach pea (Fig. 74) is
a stout trailing plant with leafy
expansions or stipules at the
base of the compound leaves.
The flowers are large, an inch or

more long, purple. The beach

FIG. 81. — Leaf and one fruit of
cocklebur, Xanthium echinatum.

cinquefoil, Potentilla canadensis, is a plant with palmately com-
pound leaves, having three to
five leaflets. It multiplies by
runners somewhat as a straw-
berry plant does. The blos-
soms are somewhat like those
of the strawberry, though
small and pale yellow to white.
Another species, Potentilla
Anserina (Fig. 75), is found in

i r xir j FlG- 82-— Sand thistle> Cirsium Pitcheri

the same locality. Wormwood

(Fig. 76) is a plant with a finely dissected, densely hairy leaf.
It is very bitter to the taste. Cocklebur (Fig. 81) is so common

THE DUNES AND THEIR PLANTS 119

a weed everywhere that its burrs and coarse leaves are familiar.
The sand thistle (Fig. 82) is a pale, hairy thistle with very weak
prickers and heads of cream-colored blossoms.

Then comes the fore-dune association (Fig. 83) including, in
addition to the foregoing, the sand reed grass, marram grass,
rye grass (Elymus) winged pigweed, green milkweed, seaside
spurge, mullein, sand cherry, and the furry willow. The sand
reed grass (Fig. 84) grows in clumps from underground running
root stalks. It bears its seeds in a spreading cluster. Where
its leaves sheath the stalk they bear a ring of short hairs.

FIG. 83. — The beach, the storm beach, fore-dune, pine and oak associations.
The cottonwood zone is missing here.

Marram grass (Fig. 85) also grows in clumps, springing from
underground running root stalks, and bears its seeds on a dense
spike. Its leaves are tipped with a long slender point. There
is no ring of hairs on the leaves where they clasp the stem. Rye
grass (Fig, 77) or wild rye looks like growing grain. The leaves
are broad. The seedlike fruits grow in a spike, each one bearing a
long bristle or awl. The winged pigweed (Fig. 78) is a much-
branched, coarse annual. Very small scattered flowers give it a
characteristic appearance shown in the illustration. Green milk-
weed (Fig. 79) has milky juice and broad, glossy, almost sessile
leaves. Its flowers are green, and their hoods have no crests

120 A NATURALIST IN THE GREAT LAKES REGION

such as are present in common field milkweed. Seaside
spurge (Fig. 80) has milky juice. The leaves are long and

narrow, with squarish ends. It
is a much-branched plant, low
and spreading. Mullein is the
common weed known by its
thick leaves, densely covered
with hair which gives them a
velvety feel. It is also known
as velvet plant. Sand cherry
(Fig. 86) has a smooth, reddish
bark characteristic of cherry
trees. This bark peels off in
thin sheets and is marked by
horizontal lenticels. The
leaves are long, narrow, larger
at the outer end than at the

FIG. 84. — Long-leaved
Calamovilfa longifolia.

stem, and the fruit is a good-sized cherry, one-half inch or more
in diameter, that is quite tasty though somewhat acrid. The
furry willow (Fig. 87), Salix
syrticola, is a low shrub with
twigs and leaves covered with
dense hair. The leaves have
large stipules. The broad-
leaved willow, Salix glauco-
phylla, is also found on the
fore-dune zone. It is also a
shrub with leaves that are
dark green, shiny above, and
light green below.

Next comes the cottonwood
zone (Fig. 88). The cotton-
wood tree is the one tree that
can stand the open dunes. It is one of the poplars (Populus
deltoides}, recognized by its broadly triangular leaves that are

FIG. 85. — Marram grass, Ammophila
arenaria.

THE DUNES AND THEIR PLANTS 121

borne on flattened stalks. The buds are long, tapering, and
curve outward. The twigs especially on young trees have sharp
ridges running down the bark below the buds. It thrives as the
sand buries it. While other trees sicken and die, the cottonwood
literally rises to the emergency, and grows so as to keep its head
above the accumulating sand. Moreover, it sends out roots all
the way up and down its buried trunk to help secure needed

FIG. 86. — Sand cherry, Primus pumila, in the fore-dune association

moisture for its vigorous growth. What appear like low cotton-
woods on top of a dune are really the topmost branches of a
tree whose original roots may be buried a hundred feet below
the rising crest of the dune. Gottonwood roots run out many
yards through the sand in search of moisture.

Miniature dunes may be built up around clumps of bunch
grass, sand cherry, or prostrate juniper (Fig. 69), but the main-
stay of the big dune is the bunch of cottonwoods whose seedlings
caused it to start, and that have grown as rapidly as the dune

122 A NATURALIST IN THE GREAT LAKES REGION

has increased in height. There are many other plants that

assist the cottonwoods to stay the onward-moving sands.
Bunch grasses and the others mentioned above
are efficient binders. Their intertangled roots
serve to enmesh the sand and prevent its being
blown away. Sand cherry, the smooth and
glandular willows, bittersweet, horsetail, are
all forms that can stand the open sand areas
along with the cottonwood and when once
established help to hold the shifting sand. So
these form a part of the cottonwood association.
To say that these plants thrive here does not
mean that they live only in such barren places.
The cottonwood grows magnificently on rich
soil; but here on the sands it is without com-
petitors. The red-osier dogwood is found
growing luxuriantly on the margins of the

swamps, but it can endure the dunes and keep its head above

even rapidly accumulating sand (Fig. 89).

FIG. 87.— The
furry willow, Salix
syrticola.

FIG. 88. — The cottonwood zone with fore-dune and storm beach in foreground

The efforts of the plants to establish themselves and trans-
form the shifting sands into permanent soil would be in vain
were it not for the fact that the lake is constantly piling up new
dunes in front of those already formed. These, as they grow,
cut off the brunt of the wind from those in the rear so that the
conditions of life are less severe on these protected dunes, ami

THE DUNES AND THEIR PLANTS

123

vegetation may grow more luxuriantly. By the time that
several generations of cottonwoods, together with many more

FIG. 89. — Steep side of a dune with red-osier dogwood, Cornus stolonifera,
and bunch grass serving as binders.

of the shorter-lived shrubs and the associated annuals, have lived
and died, the sand has become so altered by their decomposed

124

NATURALIST IN THE GREAT LAKES REGION

remains as to be capable of holding enough moisture to support
a new set of plants.

Jack pines, then white pines, and a whole new set of associated
plants, begin to change the appearance of the dunes, back in the
pine association (Fig. 90). The arbor vitae, improperly called
the white cedar, the red cedar, the common juniper, and the
prostrate juniper, are conspicuous and give a northern air
to these dune areas. The associated plants are mostly those

FIG. 90. — At the edge of the pine association looking toward the cottonwood
zone. The tall trees at left are white pines, Pinus strobus. At the right are
red cedars, Juniperus virginiana, with little bunches of spreading juniper,
Juniperus communis.

usually recognized as northerners. The bearberry covers the
ground with its glistening leaves; shinleaf, checkerberry, prince's
pine, star flower, and false lily-of-the- valley are common. Blue-
bells, puccoon, horsemint, hairy phlox, St. John's-wort, star grass,
Solomon's seal — both true and false — bellwort, and the wild
rose make these dunes gay with blossoms. Staghorn sumac,
dwarf sumac, aromatic sumac, and red-osier dogwood make
dense thickets of shrubs, while bittersweet, woodbine, poison
ivy, and grape add to their impenetrability.

THE DUNES AND THEIR PLANTS

125

Fig. 91. — The bearberry, Arctostaphylos Uva-ursi: above habitat, below detail

126 A NATURALIST IN THE GREAT LAKES REGION

FIGS. 92-100: Fig. 92. — Spray of arbor vitae, Thuja occidentalis ; Fig. 93. —
Shinleaf , Pyrola elliptica; Fig. 94. — Checkerberry, Gaultheria procumbens; Fig. 95. —
Prince's pine, Chimaphila umbellata; Fig. 96. — Bluebell, Campanula rotundifolia;
Fig. 97. — Puccoon, Lithospermum canescens; Fig. 98. — Horsemint, Monarda
punctata; Fig. 99. — St. John's-wort, Hypericum Kalmianum; Fig. 100. — Bellwort,
Uwdaria grandiflora.

THE DUNES AND THEIR PLANTS

127

The pines among the evergreens bear their needles in clusters,
the jack pine having two short needles in each group, the white
pine five long ones. The arbor vitae (Fig. 92) has scalelike,
diminutive leaves that overlap. The twig is flat and fanlike.
The red cedar is a juniper. All the jumpers have very sharp
needles, rather irregularly borne on the twig. The red cedar
(Fig. 90) is tall, plumelike, growing to be a good-sized tree,
though usually not large in the dunes. The needles are quite

FIG. ioi.— Star flower, Trientalis americana (center foreground) and false
lily-of-the-valley, Maianthemum canadense, in pine zone at the Dunes.

small, crowded in pairs, each one opposite its mate. The
common juniper (Fig. 90) is a spreading shrub, while the
prostrate jumper (Fig. 69) lies close to the ground, a straggling
shrub. The former has the leaves in threes, whorl ed on the
stem, the latter has them in pairs opposite each other. The
bearberry or kinnikinnick (Fig. 91) is a sprawling shrub that
grows often in great masses. The oblong leaves are leathery
and lustrous green the year round. The flowers are little pink,
pendant, urns, the fruit a red berry with seeds that occupy most

128 A NATURALIST IN THE GREAT LAKES REGION

of it. Shinleaf (Fig. 93) , checkerberry (Fig. 94) , and prince's pine
(Fig. 95) are all small, low, shrubby plants with evergreen leaves,

belonging to the heath family.
Shinleaf has rounded leaves,
and its flowers are borne in a
loose cluster somewhat like
those of the lily-of- the- valley.
The checkerberry has three or
four glistening, thick, leathery
leaves. It stands only two
or three inches high. The
flavor of the leaves is that
of wintergreen candy. The
leaves of prince's pine are long,
narrow, toothed on the edges,
and crowded on the short upright stalks. Star flower (Fig. 101)
is a low plant bearing a single, delicate, white blossom above
a whorl of lance-shaped leaves. False lily-of-the-valley (Maian-

FIG. 102. — Blue star grass, Sisyrinchium
angustifolium.

FIG. 103. — False Solomon's seal, Smilacina racemosa

themum canadense) has a raceme of small white flowers borne
on a plant with two or three parallel-veined, thin leaves.
Bluebell (Fig. 96) has linear leaves and delicate blue fairly

THE DUNES AND THEIR PLANTS 129

large, bell-shaped blossoms. Puccoorj (Fig. 97) is a low hairy
plant with clusters of brilliant orange blossoms. Horsemint
(Fig. 98) is an annual plant with strongly serrated leaves. The
yellow flowers are not large but are subtended by conspicuous
yellowish-purple bracts that make the blossom clusters at the
ends of the stalks showy affairs. The phlox in the dunes is so
like the garden flower of the same name it will be promptly
recognized. There are three species here. The hairy phlox has
a hairy stem and sharp, pointed, lance-shaped or linear leaves.
This is the only one common in the pine association, though it is
also found still farther back. The St. John's-wort (Fig. 99) has
leaves that are dotted with fine translucent spots. The flowers
are yellow and of quite good size. Star grass is not a grass really,
though its leaves are long and narrow like those of grass. The star-
shaped flowers, together with the narrow grass! ike leaves, make
it easily recognized . Two species are common : one bears yellow
flowers — the yellow star grass — the other, blue flowers — blue-eyed
grass (Fig. 102). Solomon's seal receives its name from the fact
that it has a long underground stem on which are a number of
circular scars like seals, each being impressed at the point where
a year's growth above the ground was attached. The leaves of
the plant are broadly lance-shaped and parallel- veined. The
flowers are borne in pairs on the axils of the upper leaves of the
pliant, unbranched stem. False Solomon's seal or spikenard
(Fig. 103) is quite similar but a somewhat lustier plant, and the
blossoms are in a cluster at the end of the stem instead of in
the axils of the leaves. Rosa blanda is the common wild rose of
the dunes, though R. humilis and R. acicularis are also found
frequently, and R. Carolina is to be encountered along the borders
of the swales. R. blanda is low, has its smaller branches free
from prickles, and its flowers are usually clustered. Its leaflets
are rounded at the outer end, wedge shaped next the stem.
R. acicularis is well armed ; its flowers are solitary as a rule. Its
leaflets are obtuse at the apex, rounded at the base. R. humilis
is slender stemmed, armed with slender prickles. Its leaflets are

130 A NATURALIST IN THE GREAT LAKES REGION

acute at both ends. The bellwort (Fig. 100) is very abundant
in spots in spring. It also has parallel-veined leaves, lance
shaped, borne on a pliant, unbranched, low stem. The flower
is single, one on each plant, a pendant, yellow, lily-like
blossom.

Staghorn sumac (Fig. 104) is a shrub readily recognized by
its coarse, pithy twigs covered with velvety hairs. The dwarf
sumac (Fig. 105) is a small edition of the staghorn with this
marked difference, that in the latter the leafstalks are margined
with a wing between the leaflets of the pinnately compound
leaves. The aromatic sumac (Fig. 106) is a struggling, low
shrub with softly hairy, young leaves. The leaves have three
leaflets and have a pleasant odor when crushed. In the same
genus (Rhus) of innocent plants comes the poison ivy and its
even more poisonous brothe_r, poison sumac (Fig. 107), also
called poison dogwood or poison elder. It grows in the swamps,
not on the dunes. But the poison ivy (Fig. 113) is very common
in the dunes, particularly in the pine association. It^,a vine,
though often appearing as a shrub. The leaf has three leaflets,
as has that of the poison sumac, and like the latter the fruit is
white, clustered, appearing berry-like. Woodbine, also a vine,
drapes itself on trees and shrubs or creeps along the ground.
Its leaves have five leaflets growing from a common center.
Bittersweet (Fig. 108) is also a climbing vine with glistening,
green, lance-shaped leaves and a red fruit in autumn, looking like
a berry in the center of four yellowish bracts that roll back to
disclose it. Three species of grapes — Vitis cordifolia (Fig. 109),
the frost grape, V. aestivalis (Fig. no), the summer grape, and
V.vulpinus (Fig. in), the river-bank grape — are found in the
dunes — the former on the cottonwood dunes, the latter in the
pine and still later associations. V: vulpinus is most likely
to be found on the margins of swales and swamps. The frost
grape has small, shiny, black berries; the summer grape, black
berries with a bloom ; the river-bank grape, blue berries with a
bloom.

THE DUNES AND THEIR PLANTS

FIGS. 104-112: Fig. 104. — Staghorn sumac, Rhus typhina; Fig. 105. — Dwarf
, R, copallina; Fig. 106. — Aromatic sumac, R. canadensis; Fig. 107. — Poison
, R. Vernix; Fig. 108. — Bittersweet, Celaslrus scandens; Fig. 109. — Frost
grape, Vitis cordifolia; Fig. no. — Summer grape, V. aestivalis; Fig. in. —
River-bank grape, V.mlpinus; Fig. 112.— Sassafras, Sassafras variifolium.

132 A NATURALIST IN THE GREAT LAKES REGION

Back of the pine association comes in order the black oak
association. No single association of the dune complex is more
distinctive than this association, so many of the plants are pecul-
iar to it. The black and chestnut oaks are the common large
trees. There is a wealth of characteristic small trees and shrubs,
sassafras, shadbush, pincherry, chokecherry, hop tree, dwarf
blackberry, known by its stiff
prickers, huckleberry, blueberry,
bush honeysuckle. The conspicu-
ous herbaceous flowering plants are
equally characteristic; the spider-
wort, bastard toadflax, anemone,
columbine, rock cress, lupine, hoary
pea, bush clover, wild geranium,
milkweed, flowering spurge, bird's-
foot, and arrow-leaved violets,
prickly-pear cactus (Fig. 60) , butter-
fly weed, green milkweed, wild
bergamot, lousewort, blazing star
(Fig. 134), the goldenrods, the sun-
flowers, and yellow daisy.

Sassafras (Fig. 112) is readil
known by its green twigs with

FIG. II3.-Poison ivy, Rku, ™^™ taste an<* its Bitten
Toxicodendron; a, spray showing shaped leaves. Shadbush (Fig. 114)
aerial rootlets and leaves; b, fruit also known as SUgar plum, servic

bush, and June berry, is a sm
tree with smooth, light-gray bar

The leaves of the species in the dunes are thin, and the ed
finely saw-toothed. The tree bears clusters of rather large whi
blossoms in the spring and later edible fruits that turn red and th
purple as they ripen. Pin and chokecherries are known by thei
reddish bark that peels off in thin layers like birch bark, though
not so readily, and that is marked by conspicuous horizontal
lenticels. Both trees have the blossoms in clusters. In th

• — both one- fourth natural size
(Farmers' Bulletin No. 86).

'

THE DUNES AND THEIR PLANTS

133

122

FIGS. 114-122: Fig. 114. — Shadbush, Amelanchier canadensis; Fig. 115. —
Pin cherry, Primus pennsylvanica; Fig. 116. — Chokecherry, P. mrginiana; Fig.
117. — Huckleberry, Gaylussacia baccata; Fig. 118. — Bush honeysuckle, Diervilla
Lonicera; Fig. 119. — Spiderwort, Tradescantia virginica; Fig. 120. — Bastard toad -
J flax, Comandra umbellata; Fig. 121. — Anemone, thimble weed, Anemone cylin-
drica; Fig. 122. — Columbine, Aquilegia canadensis.

134

NATURALIST IN THE GREAT LAKES REGION

former (Fig. 115) the individual flower stalks radiate from a
common point; in the latter (Fig. 116) they come off singly from
a common, main stalk. The fruits are, of course, similarly
clustered. The hop tree, really a shrub, is known by its leaf
made of three leaflets and its clustered fruits, achenes with wide,
dry, thin borders, looking somewhat like dried hops. The blue-
berries and huckleberries (Fig. 117) are low shrubs with rather
thick, leathery leaves, pink bell-shaped flowers and bluish berries
for fruits. In the autumn their leaves turn shades of dull red and

give a brilliant cast to great
stretches of the dunes where
they are abundant, like the
autumn colors of the Scotch
heathers. These plants belong
to the heath family. Bush
honeysuckle (Fig. 118) is a low,
opposite-leaved shrub with
yellow flowers in clusters of
three. The corolla is funnel-
form, the flowers conspicuous.
As they age they turn darker
or even scarlet to crimson.

Spiderwort (Fig. 119) is
known by its grasslike leaves
that exude a mucilaginous sap when broken. Bastard toadflax
(Fig. 120) is a low plant with a cluster of small white flowers.
Anemone cylindrica (Fig. 121) and columbine (Fig. 122) are
familiar and may be recognized from the illustrations. Rock
cress (Fig. 124) is one of the mustard family with small white
clustered flowers, each with four petals. The lupine (Fig. 123)
has palmately compound leaves and large spikes of blue, pealike
flowers.

The hoary pea (Fig. 125) or wild sweet pea is an erect,
unbranched plant, a foot or two high, with typical, clustered,
pea-shaped blossoms that are yellowish purple. The leaves are

FIG. 123. — Lupine, Lupinus perennis

THE DUNES AND THEIR PLANTS

FIGS. 124-132: Fig. 124. — Rock cress, Arabis lyrata; Fig. 125. — Hoary pea,
Tephrosia virginiana; Fig. 126. — Bush clover, Lespedeza capitata; Fig. 127. —
Wild geranium, Geranium car olinianum; Fig. 128. — Flowering spurge, Euphorbia
corollata; Fig. 129. — Bird's- foot violet, Viola pedata; Fig. 130. — Butterfly weed,
Asdepias tuberosa; Fig. 131. — Arrow-leaved violet, Viola sagittata; Fig. 132. —
Lousewort, Pedicularis canadensis.

136 A NATURALIST IN THE GREAT LAKES REGION

compound with seven to twenty-five leaflets. The roots are
fibrous and very tough, serving well for string on emergency.
Bush clover (Fig. 126) is a tall slender plant with a covering of
silky hairs. The compound leaves consist of three leaflets which
are long and narrow. The round heads of yellowish blossoms are
sessile in the axils of the upper leaves. The wild geranium of
the black oak association is Geranium carolinianum (Fig. 127).
The leaf is shaped much like that of the sweet-scented, deeply

FIG. 133. — Wild bergamot, M onarda fistulosa

cut leaf of the common garden geranium. The flower is about
one-half inch broad, pale purple, and the seed pod bears a short
beak. Geranium maculatum, a closely related species, is found
farther back in the mixed oak association. Flowering spurge
(Fig. 128) has an erect stem with narrow leaves. At its top a
cluster of stalks arises from a common point surrounded by a
whorl of green bracts. These stalks branch rapidly, and each
branch terminates in a white blossom. The juice of the plant
is milky. Bird's-foot and arrow-leaved violets may be identified
from the figures of the plants (Figs. 129, 131). Butterfly weed

THE DUNES AND THEIR PLANTS

137

is one of the milkweeds, although it does not have a milky juice.
The clustered blossoms are brilliant orange and shaped like

those of the common field

milkweed (Fig. 130). Wild
bergamot (Fig. 133) has a char-
acteristic odor. The corolla is
long, violet or pink, and hairy
in the throat. The blossoms
are clustered and the cluster
is subtended by bracts, the
upper ones of which are col-
ored white or purplish. Louse-
wort (Fig. 132) is a low hairy
plant with pinnately parted
leaves and yellow flowers
crowded by a spike at the top
of the stem. The blazing stars
(Fig. 134) are tall, slender,
unbranched composite plants
with small narrow leaves.
They, are so slender they look
like fuzzy green stakes set in
the ground. The two common
species in the black oak area
are Liatris cylindrica and L.
scariosa. The former has only
a few heads and reddish-
purple flowers, the latter many
heads on the stalk and these
good sized.

The mixed oak association FlG. I34._Biazing star> Liatris spicaia
(Fig. 135) is characterized by

black, chestnut, white, and red oaks (Fig. 136), with a mixture
of slippery or red elms and basswoods, while among the smaller
trees water beech and hop hornbeam are peculiar. Yellow

138 A NATURALIST IN THE GREAT LAKES REGION

lady's-slipper, hepatica, May apple, Geranium maculatum,
Canada violet, the long-spurred violet, and rattlesnake root are
characteristic and indicate the approach of the climax forest
association which will be discussed in a later chapter.

The elms are known by their vase shape and by the fact that
the buds come out on opposite sides of the twigs so that the
branch with its twigs is always flat, spread out fanwise. The

FIG. 135. — Mixed oak-dune area. Note large white oak, Quercus alba, in
center of picture; near it are red oaks, Q. r ultra.

last feature is also common to the basswood, and these are the
only trees in our area that do possess this character. The bass-
wood has large heart-shaped leaves, lopsided at the base. The
bark of the tree is smooth, except that it is often riddled with the
holes of the sapsucker arranged in rows around the trunk.
Water beech (Fig. 137) has a fluted trunk with smooth bark.
Hop hornbeam has a finely shredded bark that pulls off in long
stringy strips. Both these trees have leaves that resemble those
of the elm.

THE DUNES AND THEIR PLANTS

FIG. 136. — Leaves and acorns of the oaks: o, red oak (Qucrcus rubra); b,
pin or swamp oak (Q. palustris); c, northern pin oak (Q. ellipsoidal is); d, scarlet oak
(Q. coccinea); e, black oak (Q. velutina); f, white oak (Q. alba); g, bur oak
(Q. macrocarpa); h, blackjack (Q. marylandica) ; i, swamp white oak (Q. bicolor);
j, cinquapin oak (Q. Miihlenbergii); k, shingle oak (Q. imbricaria) ; I, basket oak
(Q. Michauxii).

140 A NATURALIST IN THE GREAT LAKES REGION

The yellow lady 's-slipper or moccasin flower can be recognized
from the illustration, for it is so unusual a blossom (Fig. 138).
Hepatica or liverwort (Fig. 139) has a three-lobed, dark, mottled
leaf; the pale pink or lavender blossoms come early in the
spring. May apple (Fig. 140) has large circular leaves, the stem
attached at the center. The large creamy white blossoms spring
from the fork of the stem, the blossoming plant always bear-
ing two leaves. Geranium maculatum (Fig. 141) is similar to

G. carolinianum of the black
oak association. Its leaf is
not as finely cut, having
only five wedge-shaped lobes.
The blossom is larger, nearly
an inch across, and is light
purple. Canada violet (Fig.
142) has a branched, leafy
stem. The blossom is yellow
tinged with violet on the out-
side, white inside. The long-
spurred violet (Fig. 143) has
so conspicuously long a spur
that it is not to be mistaken
for any other in the Chicago
region. B oth these violets are
conspicuously present in the
climax forest. Rattlesnake
root, Prenanthes alba, is a composite with a stout and fairly high
stem, bearing leaves roughly triangular, though very variable in
form and lobing. The flowers are white, a dozen or so in a head
with many heads in a cluster (Fig. 144) . The summary of charac-
teristic plants is given in the tabulation at the close of this chapter.
The dune complex is by no means as simple as the foregoing
discussion would seem to indicate, for there are additional
physiographic changes that are constantly going on that inter-
fere with the orderly progression sketched above. Whenever a

FIG. 137.— Trunk of water beech,
Carpinus caroliniana.

THE DUNES AND THEIR PLANTS

141

new dune forms near
the shore it diverts
the strong winds in
its neighborhood, for
they are blocked in
certain directions and
go scurrying around
its ends to blow with
great vigor upon the
older dunes from new
angles. Not infre-
quently a poorly pro-
tected portion of some
old dune is exposed
thus to the scouring
action of the sand-
laden blast, and its
relatively loose soil
begins to blow away.
What was an estab-
lished dune may be
more or less com-
pletely blown away
(Fig. 14). Such blow-
outs are common,
and they, of course,
set back an area
that had perhaps
arrived at the
black oak stage to
the fore-dune stage
of shifting sands in
which only the few
harrlv annuals ran FlG' I38'~ Ydl°W lady's-sliPPer' Cypripedium parm-

nardy annuals can flofum_ L Front view of flower. n, ill, side and front

grow.

view of stigma and pollinia. Drawing by L. N. Johnson.

142 A NATURALIST IN THE GREAT LAKES REGION

Moreover, such blow-outs uncover whatever the advancing
dune buried. Under such conditions cottonwoods show their
resiliency by sending out leafy shoots on old buried trunks that

FIGS. 139-144: Fig. 139. — Hepatica, Hepatica triloba; Fig. 140. — May apple,
Podophyllum pdtahim; Fig. 141. — Wild geranium, Geranium maculatum; Fig.
142. — Canada violet, Viola canadcnsis; Fig. 143.— Long-spur violet, V '. rostrata;
Fig. 144. — Rattlesnake root, Prenanthes alba.

bear numerous roots. The buried pines, killed completely by
their burial, stand out as giant skeletons, ghosts of their former
selves. Such resurrections are no uncommon sight in these
forest graveyards. .Sometimes the fall of a great tree on one

THE DUNES AND THEIR PLANTS

143

of the older dunes may expose enough of the loose sandy soil to
the wind to initiate a blow-out.

It is very evident, then, that any given area in the dune
region must be interpreted in the light of the complex of forces
operative upon it. Frequently one will get into a region that
is easily recognized as a cottonwood dune, a black oak associa-
tion, or an interdunal swamp area, but not infrequently a par-
ticular spot will be in transitional conditions, a swamp being
invaded by a moving dune perhaps, where within a rod one may
pass from abundant water to bone-dry sand, from sphagnum
and pitcher plants and a crowded vegetation to a barren sand
slope. Old dunes are invaded by new ones, oaks superseded by
cottonwoods. In fact, the zones as presented above, while often
regularly placed, are at times mixed in a thorough jumble as
blow-outs occur, moving dunes blow rapidly inland, or as the
succession is here or there retarded or accelerated by other local
conditions.

The following table presents a summary of the plant associa-
tions in the Dunes. It shows in which association each plant
listed is most likely to occur. It would be well for the student
to make a similar summary for each of the succeeding chapters
viii-xiii.

144 A NATURALIST IN THE GREAT LAKES REGION

Common Name of Plant

Scientific Name

<

I1

P

Pine Assoc.

Black Oak
Assoc.

Mixed Oak
Assoc.

Trees, deciduous
Balsam poplar

Populus balsamifera

*

*

' '*'

Pincherry

P. pennsylvanica

....

*

Elm, red or slippery .
Hop hornbeam
June berry
Oak, black
Oak, chestnut
Oak red

U.fulva
Ostrya virginiana
Amelanchier canadensis. . .
Quercus velutina
Q. Muhlenbergii
Q. rubra

t

Oak white

Q. alba

Sassafras
Shadbush (see June
berry)
Poplar (see Balsam
poplar)
Water beech

Sassafras variifolium
Carpinus caroliniana

Shrubs, deciduous
Bearberry

Arctostaphylos Uva-ursi. . .

*

Vaccinum pennsylvanicum

*

V. vacillans

*

Cherry, sand
Dogwood, flowering .

Prunus piimila
Cornus fiorida

*

*>

*
*

Dogwood, red-osier. .
Hackberry, dwarf . . .
Honeysuckle, bush . .
Hop tree
Huckleberry
New. Jersey, tea

C. stolonifera
Celtis occidentalis pumila .
Diervilla Lonicera
Plelea trifoliata
Gaylussacia baccala
Ceanothus americanus. . . .

*

*

R. blanda

*

*

R. humilis

*

*

Rhus canadensis

*

*

R. copallina

*

*

Sumac, staghorn. . . .
Viburnum, maple-
leaved

R. lyphina

Viburnum acerifolium ....

*

*

*

*

Willow, smooth

>S. glaucophylla . . .

*

*

*

Witchhazel

Hamamelis virgimana. . . .

*

THE DUNES AND THEIR PLANTS

Common Name of Plant

Scientific Name

1

Fore-Dune
Assoc.

$*

Pine Assoc.

Black Oak
Assoc.

-id

P

Evergreen trees and
shrubs
Arbor Vitae
Cedar, white (see Ar-
bor Vitae)
Cedar red

Thuja occidentalis
Juniperus iiirginiana

*

*

....

Juniper, common . . .

Juniperus communis
J . horizontals

Pinus Banksiana

Pine, white
Vines

P.strobus

Celastrus scandens

....

Grape, fox

Vitis iiulpina

Grape, wild
Ivy, poison

V. cordifolia
Rhus Toxicodendron^r. . . .

' '*'

• ' j'

Virginia creeper
Herbaceous plants —
flowering '
Arbutus
Aster
Aster
Anemone
Beach pea

Psedera quinquefolia

Epigaea repens
Aster linariifolius
A . sericeus
Anemone cylindrica
Lathyrus maritimus

,

'....

....

Bean, sand
Bearberry
Bedstraw
Bellwort
• Bergamot, wild
Blazing star
Blazing star
Bluebell

Strophostyles hehola
Arctostaphylos Uva-ursi . .
Galium Aparine
Uindaria grandiflora
M onarda fistulosa
Liatris cylindracea
L. scariosa
Campanula rotundifolia . . .

*

*-.
"*/

*

*

*
*
*
*
*

"*'

Broom rape '.

Orobanche fasciculata

*

*

Bugseed

Butterfly weed
Cactus (see Prickly
Pear)
Check erberry
Cherry
Cherry, ground
Cinquefoil, beach . . .

Corispermum
hyssopifolium
Asdepias tuber osa

Gaultheria procumbens. . . .
P. mrginiana
Physalis lanceolata
Potentilla canadensis
P fruticosa

*
*

*

*

*

* Cinquefoil, silver . . .
Clover, bush
Cocklebur
Columbine
Cranesbill (see Ge-
ranium)
Cress, rock

P. Anserina

Lespedeza capitata
Xanthium canadense
Aquilegia canadensis

A rabis lyrata

•;•

*

*

*

146 A NATURALIST IN THE GREAT LAKES REGION

Common Name of Plant

Scientific Name

1.

Fore-Dune
Assoc.

Cottonwood I
Assoc.

Pine Assoc.

Black Oak
1 Assoc.

Mixed Oak I
I Assoc.

Dandelion, dwarf. . .

Krigia amplexicaulis

*

Dandelion, dwarf . . .

K. mrginica

*

*

Daisy,, yellow

Rudbeckia hirta

*

Evening primrose .

Qenothera biennis

*

*

Evening primrose. . .

O. rhombipetala

*

Everlasting
Foxglove, false

Antennaria plantaginifolia
Gerardia pedicularia

*

Frostweed

II elianthemum canadense .

*

*

Geranium

Geranium carolinianum . . .

*

Geranium

G. maculatum

*

Ginseng, dwarf

Panax trifolium

*

Goldenrod

Solidago nemoralis

*

Goldenrod

S. racemosa

*

Goldenrod

S. rigida

*

*

Goldenrod

S. speciosa

*

Grass, blue stem ....

A ndropogon scoparius ....

*

Grass, marram

A mmophila arenaria

*

*

Grass, rye

Elymus canadensis

*

*

*

Grass, sand reed ....

Calamovilfa longifolia ....

*

*

Grass, switch

Panicum mrgatum

*

Grass, triple awned . .

A ristida tuberculosa

*

Grass

Festuca octoflora

*

Grass

Koelaria cristata

*

Grass

Sphenopholis obtusata.

*

Grass, goose

Potentilla Anserina

' '*'

' '*'

Grass, star

Hypoxis hirsute,

*

Hepatica

Hepatica triloba

*

Horsemint

Monarda punctata

*

*

*

Knot weed, small ....

Polygonella articulata

*

*

Lady's-slipper,

yellow

Cypripedium parviflorum. .

*

*

Lily-of-the-valley,

false

M aianlhemum canadense. .

*

Lousewort

Pedicidaris canadensis ....

*

Lupine

Lit pin us perennis

*

May apple
Milkweed, green ....

Podophyllum peltatum ....
Acerates viridiftora

' '*'

*

*

*

Pea, beach

Lathyrus maritimus

*

*

Pea, hoarv

Tephrosia mrginiana

*

Phlox, bifid

Phlox bifida

*

Phlox, blue

P. divaricata

*

Phlox, hairy

P. pilosa

*•

*

*

Pigweed, winged ....

Cydoloma alriplicifolium .

*

*

Prickly pear
Prince's pine
Puccoon

Opuntia Rafinesquii
Chimaphila umbcllala ....
Lithospcrmum canescens. . .

*

*

Rose, rock
Rattlesnake root ....

Hudsonia tomentosa
Prenanthes alba

*

Russian thistle

Salsola Kali tenuifolia ....

*

*

Sarsaparilla

Aralia nudicaulis

*

THE DUNES AND THEIR PLANTS

147

Common Name of Plant

Scientific Name

I

3

3 u

I1

ll

U

Pine Assoc.

Black Oak
Assoc.

Mixed Oak 1
Assoc.

Sea rocket

Cakile edentula

*

*

Sedge

Carex eburnea

*

Sedge ... v

C. Miihlenbergii

' '*'

Sedge

C. Pennsylvania

*

Sedge :

C. umbellata

*

Sedge

Cyperus filiculmis

*

Se'dge

C. Schweinitzii

*

Shinleaf

Pyrola elliptica

i

*

Shinleaf

P. secunda

*

Solomon's seal
"Solomon's seal, false .

Polygonatum commntatum .
Smilacina tellata

*
*

*

*

Solomon's seal, false .

5. racemosa

*

*

» Spiderwort

Tradescantia virginiana . . .

*

*

Spurge, seaside

Euphorbia polygonifolia. . .

•*

*

*

Spurge, flowering . . .

E. corollata

*

St. John's-wort

Hypericum Kalmianum . .

*

*

Star flower

Trientalis americana

*

Sunflower

Helianthus divaricatus ....

*

Sunflower

H . occidentalis

*

Thistle, sand

Cirsium Pitclieri

*

*

*

Toadflax

Linaria canadensis

*

Toadflax, bastard . . .

Comandra umbellata

*

Twinflower

Linnaea borealls

41

Violet, arrow-leaved .

Viola sagittala

' '*'

Violet, bird's-foot. . .

'V. pedata

*

Violet, blue

V. cucullata

*

*

Violet, Canada

V. canadensis

*

Violet, long-spurred .

V. rostrata

*

Wormwood

Artemisia canadensis . ....

*

*

*

*

Wormwood

A . caudata

*

*

*

*

Spore bearers

Rattlesnake fern ....

Botrychium. virginianum . .

*

Bracken fern

Pteris aquilina

*

Horsetail fern

Equisetum arvense

*

Scouring rush

E. hyemale

*

CHAPTER VIII
ANIMALS OF THE DUNES

ONATION of animal forms in the Dunes
is quite as evident as that of the plants.
This is to be expected since the location
of the animals is determined in large
measure by their food plants or by nest-
ing sites that in turn are determined by
the plants. Before calling attention to
some of the characteristic animals of
each zone we may give a striking example of the difference in
habitat of the several species of the tiger beetles (Fig. 145).
The white tiger (Cicindela lepida) and the copper tiger (C. cupras-
cens) are abundant in summer along the wet shore just out
of reach of the waves where they are busy feeding on small
insects washed up from the lake and on the maggots of common
flies that live in larger dead animals that are deposited by the
same agency. The white tiger flies back to the higher parts of
the fore-dune area and to the cottonwood zone to rear its young;
in the former area the openings of its burrows are character-
istic though not numerous, in the latter, abundant. Cicindela
hirticollis digs its straight, cylindrical, vertical burrows in which
the young are found in the moister parts of the fore-dune area.
This species is found foraging very commonly in the cottonwood
zone, especially on the landward side of the dunes that border
ponds or swales. In the transition belt between cottonwood and
pine associations occur the crooked holes of the young and the
adults of the large tiger, C. formosa generosa. The bronze tiger
(C. scutellaris lecontei) is characteristic of the pine association
itself where it rears its young, and is found also in the adjacent
black oak areas, especially in bare sandy spots. Finally, as one

ANIMALS OF THE DUNES

149

travels still farther back from the lake into the oak-hickory
association he encounters the green tiger (C. sexguttata) , though
it is much more common still farther back in the hickory -maple
and maple-beech forests. Yet other species are .confined to the
borders of the interdunal ponds (C. tranquebarica) to the margins
of sphagnum bogs (C. ancocisconensis} and to the shores of small
lakes (C. repanda). It is remarkable that species so closely
related should occupy such closely adjacent areas and each keep

FIG. 145. — Species of tiger beetles. At left, Cicindela formosa generosa.
a, Wing cover of C. lepida; b, C. cuprascens; c, C. hirticollis; d, C. scutellaris lecontei;
e, C. sexguttata; f, C. repanda; g, C. ancocisconensis; h, C. limbalis. All X2.

quite strictly to its own narrow belt. Yet such is found to be
the case the world over; closely related species are seldom found
living together, but if in the same region each occupies its own
restricted area.

These tiger beetles are all predatory, feeding on flies and
other insects which they often capture on the wing. They occur
usually on bare, sunny spots. Thus, the green tiger of the maple-
beech forest is found on the open paths. They are wary animals,
rising in quick flight as you approach and flying in straight lines
some distance ahead of you when they turn as they alight to

150 A NATURALIST IN THE GREAT LAKES REGION

face the intruder. The larva lives in a burrow in which it is
supported at the top by a spiny hump; the huge jaws fill the
orifice ready to seize any insect that unwarily steps on the living
trap. The jaws are approximately ground color so that you are
sometimes aware of the presence of the burrows when what was
at first solid ground becomes porous as the numerous larvae drop
back into their holes on your alarming approach.

That the dune area is prolific in animal life may be realized
from the result of an animal census taken in midsummer by
Miss Nell Saunders, whereby she found in a mixed area of swale,
cottonwoods, and oaks sixteen million animals to the acre. This
population was distributed as follows: three-quarters of a million
on the ground stratum, three million on the herbaceous plants,
ten million on the shrubs, and the remainder on the trees. It is
evident from this and from the descriptions to follow that there
is a vertical zonation of life as well as a horizontal one.

The succeeding societies of animals beginning with those near-
est the shore are, in the Dunes, as follows: (i) The predatory
ground beetle association corresponding to the beach association
of the plants. (2) The digger wasp association, corresponding to
the fore-dune and cottonwood zones. (3) The bronze tiger asso-
ciation corresponding to the transition zone between the cotton-
wood and pine areas and the pine association. (4) The ant-lion
association, equivalent to the black oak plant association. (5)
The hylodes association, corresponding to the mixed oak plant
zone.

While both the wet beach and the storm beach (Fig. 83) are
practically free from plants, they are inhabited by characteristic
animals. When a strong offshore wind is blowing, hundreds of
species of insects and many birds from the territory adjacent to
the lake blow out over the water during their incautious flights
and drop exhausted to its surface. When the wind shifts, asit does
almost daily, the onshore wind piles these animals, together with
dead fish, in long windrows on the beach. Some of the insects
survive their prolonged immersion and crawl under stones, chips,

ANIMALS OF THE DUNES 151

and bits of drift on the storm beach. After a storm one may pick
up hundreds of species along shore, some of them from regions
far inland.

Flesh flies and carrion beetles are to be found feeding on and
depositing their eggs in the carcasses of fish and other dead
animals. Digger wasps and robber flies are attracted here by
the numerous insects that are crawling half-dead from the water.
Crows and herring gulls are also drawn by the carrion, the latter
are present in great flocks in the fall, fishing offshore as well as
feeding along the beach. There are many long-legged shore
birds that feed on these insects and on the crustaceans, wading
out in the shallow water to hunt them or running along the
wet sand. The least and semipalmated sandpipers are fairly
common. In spring and fall, particularly the latter, the beach
is alive with knots, sanderlings, and turnstones; godwits, cur-
lews, and willets are also often to be noted, while the piping
plover is not only found frequently here but occasionally nests
in the same area. The Hudsonian curlew, the willet, and the
Hudsonian godwit, the latter, especially, becoming rare, are all
birds of good size (15 to 17 inches long) with slender bills over
2 inches long. That of the curlew turns down distinctly, a
distinguishing feature. The under parts of the willet are white;
those of the godwit, chestnut. Knot, sanderling, semipalmated
and least sandpipers also have long bills to use as probes. The
birds are smaller, however, 10^, 8, 6|, and 6 inches long
respectively. All are mottled black and gray or buff above.
The sanderling has three toes and wing bars; the others, four
toes and no wing bars. The small size of the last two serves to
make their recognition certain. The breast of the semipal-
mated is faintly streaked or spotted with black; that of the
least, heavily streaked or spotted with brown. The turnstone,
which is some 9^ inches long, has a back strikingly mottled in
black, brown, and white and a white patch at the base of the
tail. The piping plover is small (7 inches), very pale colored,
almost ghostlike in its invisibility. The upper parts are ashy;

152 A NATURALIST IN THE GREAT LAKES REGION

the under parts, white. There is a black bar on each side
of the breast, the two sometimes uniting to form a band across

the breast.

The killdee and
semipalmated plovers
are also found on the
beach, though more
characteristic of pas-
tures and marshy
uplands respectively.
The former is about
the size of a robin.
It has two black bands
crossing its front. It
repeatedly whistles
"killdee" when dis-
turbed. The latter is
smaller (6f inches) and
FIG. 146.— Termites or white ants, Termesflavipcs: has only One black
a, Female; b, Male; c, Worker; d, Soldier. FromSz^. band across its front.

Bureau of Entomology, U.S. Dept. of Agricult

Spotte(J sand-

piper is also common, though more characteristic of the shores
of streams and smaller inland lakes. It is 7^ inches long,
streaked, barred, and spotted all over, the
under parts strongly spotted with black
on a white ground. It bows and teeters
as it comes to a stand.

Under the driftwood of the storm beach
one will find hiding by day the common
toad, many predatory beetles, an occa-
sional mole or mouse, all-night prowlers
that come out in the dusk to feed. Here
too one finds the white ants or termites
(Fig. 146). The sand-colored spider, Trochosa cinerea (Fig. 147),
hunts over this territory to good purpose by day.

FIG. 147. — The sand-
colored spider, Trochosa
cinere a.

ANIMALS OF THE DUNES

153

It is difficult to pick out from such a miscellaneous assemblage
any particular form by which to name the association. Perhaps
it may be called the predatory ground beetle association quite
justly. Such beetles,
including the white
and copper tigers, the
searcher, a good-sized,
bright, bronze-green
beetle; the fiery
hunter, a black beetle
with coppery pits on
the elytra (Fig. 148) ;
the yellow-legs, Galer-
ites janus, a black

beetle with legs and FIG. 148. — The searcher, Calosoma scrutator, and

thorax reddish brown, the fiery hunter' c calidum-

and others are always present, though, in many cases, they are

likely blown here from their native haunts farther inland. At

FIG. 149.— Holes of digger wasp, Microbembex monodonta, at left; wasp at
entrance to hole at right.

any rate they are representative of the whole group of insect-
eating animals so characteristic of the zone.

The fore-dune zone is intensely hot in summer. The sknd
burns your bare feet so that it is quite unendurable. Here

154 A NATURALIST IN THE GREAT LAKES REGION

many inhabitants dig in to get down to the moist, cool sand a
few inches below the surface. The burrowing spider does this,
coming out at dusk to hunt. Its holes are one-eighth to one-half
inch in diameter and 5 or 6 to 20 inches deep. The hole is sur-
rounded in early morning by moist
dabs of sand thrown out in excava-
tion. The full-grown spider, legs
extended, nearly covers the palm of
your hand. It is colored like the
sand. Here also the black digger
wasp, Anoplius diver sus, makes its
FIG. 150— The bee fly, Exoprospa. holes in which to rear its young and

After Williston. stocks them ^^ spiders for f Qod

for the larvae. The holes are shallow and the heat serves to
incubate the eggs. Two other digger wasps of a smaller sort,
Microbembex monodonta (Fig. 149) and M. spinulosa (Fig. 67),
or Bembex spinolae, excavate holes that are so
abundant in spots the surface layer is per-
forated like a sieve. They are the most strik-
ingly characteristic features of this area and it
may properly be designated the digger wasp
association. Not that the digger wasps are
not elsewhere found. But they are nowhere
else so conspicuous and dominating a part of
the animal consocies. Bee flies (Fig. 150)
hover over the groups of wasp holes, dipping
down to the surface every once in a while to
deposit eggs at the entrance of some wasp hole Willow-leaf beetle,
so that when the latter drags in flies to stock Disonycha quinquevit-
her nest the bee fly egg may be carried in, too.
The bee fly larvae live parasitically on the larvae of the digger
wasps.

The low plants of the fore-dunes, sand reed, marram grass,
sarfd cherry, smooth and glandular willows, etc., are relatively
free from insect pests. Apparently the conditions under which

FIG. 151.— The

ANIMALS OF THE DUNES

155

they live are too severe for any but the hardiest of their enemies.
The willows are quite free from the willow cone gall. One leaf-
eating beetle, Disonycha quinquevittata (Fig. 151), is common on
them. It is about one- third inch
long, yellow with black stripes.
There are some aphids on the cher-
ries but the ladybird beetles and
syrphus flies keep them well in check.
Several snout beetles of the genus
Sphenophorus (Fig. 152) are very
common on the grasses. The larvae
feed on the roots of the bunch grass
and on the roots of sedges in nearby swales. Gnats and flies that
apparently breed down at the shore lodge on these grasses in large

FIG. 152. — A snout
Sphenophorus. X 2 .

beetle,

FIG. 153. — Nest holes of bank swallows

numbers. One of the flies has a vigorous bite. The tor-
mented camper in this region may derive some satisfaction
from watching the swift darting flight of several species of
dragon flies that hunt over and among the clumps of grass
and devour many of these flies and gnats. (See next
chapter.)

156 A NATURALIST IN THE GREAT LAKES REGION

In the plant associations there is a sharp demarcation between
the fore-dune and the cottonwood zone that comes next, for the
cottonwoods add a strikingly new feature. There is no such
separation in the animal associations, and both fore-dune and
cottonwood areas may be included in the one digger wasp
association. True, certain new
animals appear. The kingbird finds
the tops of the cottonwoods excellent
lookouts from which to spy the in-
FIG. 154.— Maritime locust, sects upon which he feeds. But he is
Trimerotropis maritima. more common and more character-

istic in other situations as, for instance, along the borders
of the woods. The tree swallow nests in the hollow stumps
of old pines and cottonwoods. Their backs are iridescent
blue green; their throats, breasts, and bellies, pure white.
Bank swallows nest in the steep sides of dunes, especially
where blow-outs make sand cliffs
(Fig. 1 53) . The cottonwood is rela-
tively free from the insect pests that
usually accompany it. The cock's
comb gall is not frequent on it here.
Such a characteristic woodborer of

, T-,, , 7 7 FIG. 155. — Mottled sand locust,

the cottonwood as Plectrodera seal- Sparagjo5n wyomingianum.

ator is rare. In the spring when the

tree is in blossom certain flies and beetles are attracted by its
abundant pollen, but these are also common on the willows of
the fore-dune. The white or maritime and long-horned locusts
are frequently found in the digger wasp zone, though they are
also found in the bronze tiger zone.

The female of the maritime locust (Fig. 154) is about 1.2
inches long; the male, about . 8 of an inch. The animal is light
gray to reddish brown in color, the under side almost white. It
is so near the color of the sand as to be nearly invisible until it
flies. The inner wings have a dark band along the margin but
a transparent tip. The inner face of the hind femur bears three

ANIMALS OF THE DUNES

157

black bands. The long-horned locust (Fig. 156) is small, the
male two-thirds of an inch long, the female seven-eighths inch.
The antennae are half as long as the body, or more. The inner
wing has the basal third red, orange, or rarely yellow. The
middle third of the wing is covered by a curved black band, the
outer third is clear, except for a dusky tip.

Back of the digger wasp association comes the transition
stage and the pine association in the plant zonation. Both of

FIGS. 156-159: Fig. 156. — Long-horned locust, Psinidia fenestralis. After
Lugger; Fig. 157. — Lesser migratory locust, Mclanoplus atlanis. After Lugger;
Fig. 158. — End of abdomen of male of narrow- winged locust, Melanoplus angusli-
pennis; Fig. 159. — Sand locust, Ageneotettix arenosus.

these support nearly the same animal population, and it is a
very characteristic one. Nowhere else in the Chicago area,
unless it be in the sphagnum-tamarack swamps, does one seem
to be so far removed from the expected environment. The
coniferous trees, the evergreen shrubs, and the herbaceous
flowering plants, many of which are quite boreal, are more
striking but no more peculiar than the animals encountered.

158 A NATURALIST IN THE GREAT LAKES REGION

As already noted, the bronze tiger beetle (Fig. 145) is here as

well as the burrows of its young. Shelford names the whole

association from this form, although the adult animal is found

quite as commonly back in the next association. Here, too,
particularly in the transition area, is the
large tiger beetle (Fig. 145). The white ant
is abundant under the logs. Digger wasps
are still in evidence, though of species
different from those of the preceding zone.
The black ant, Lasius niger americanus,
builds its nests in the sand. The mottled
sand locust, the migratory locust, the
narrow-winged locust, and the sand locust
are pretty well confined to this zone. The
FIG. 1 60.— Longhorn mottled sand locust (Fig. 155) is small, the

beetle, Monohammus female being about i inch long, the male
.8 of an inch. The inner wings are yellow

with a dark, curved median band. The antennae are as long

as the hind femur. The tibia is coral red with white rings. The

lesser migratory locust (Fig. 157) is also small, about the same

size as the preceding. The femur of the hind

leg is reddish yellow and bears two oblique

dark bars across the upper outer face. The

knees are black. The lower part of the face is

usually pink. The inner wings are thin and

colorless. The narrow- winged locust (Fig. 1 58)

is also small, slightly under an inch. The

antennae are shorter than the femur of the

hind leg. The hind tibia is pale blue or bright

red. The inner wings are transparent and

colorless. The sand locust (Fig. 159) is

small, the male being .6 of an inch long, the

female .8 inch. The animal is dull brown, the hind tibia is bright

scarlet with a basal white ring. On the juniper several spiders

are found, Philodromus alaskensis, Xysticus formosus, Dendry-

FIG. 1 6 1. —Metallic
wood-boring beetle,
Chalcophora liberta.

ANIMALS OF THE DUNES

159

phantes octavus, Theridium spirale, all small and fairly widely
distributed, except the first.

The tree stratum is the one on which the largest number of
conspicuous and characteristic forms are found. The pitch
moth feeds on the new pine shoots, covering itself in a case of
pitch and excreta. Longhorn and metallic wood borers are to
be encountered under
the bark, or in their
tunnels in the wood
of the partially dead
or wholly dead pines
(Figs. 1 60 and 161).
Here, too, one finds
certain birds and
mammals that are
more or less confined
to the pines. Downy
and hairy wood-
peckers nest here.
The golden-crowned
and ruby-crowned
kinglets, the black-
throated green war-
bler, and the pine
warbler are abundant
during migration.
The black-capped chickadee is nearly always present, repeatedly
calling his own name. The ruffed grouse is fairly frequent and
nests here occasionally or in the adjacent black oaks. The red
squirrel that is so constant a feature of the coniferous forests
farther north is frequently encountered, as is also the chip-
munk (Fig. 162).

When the stage is set with the plants of the black oak associa-
tion the animal dramatis personae change with the changing
scenery. This has been designated the ant-lion association.

FIG. 162. — Chipmunk, Tamias striatus griseus

160 A NATURALIST IN THE GREAT LAKES REGION

The conical holes of the young are conspicuous in spots (Fig.
163), though you may travel over these black oak dunes for a
long time without encountering them. Still they are confined
to the black oak region. The pit is 2 inches or so in diameter
and is a crater-like depression in the loose sand. At the bottom

under the sand lies the larva, an

^~~VO • uSty little duckling. When an ant

^^^llj^L or other small insect goes on a jour-

\^d^B\ ^sj ney ft may step °ver tne edge of

m& |8nk sucn a depression, slide down with

^P the caving sand in spite of its best

efforts to escape, and be seized by

/ the jaws of the waiting larva. A

/ , grass blade stuck down into the

: •; -4 sand at the bottom of the pit will

sometimes bring up
the larva that fastens
its jaws into it and
will not let go even
when pulled out of its
lair. One may go fish-
ing for the tiger beetle
larvae in the same
way with occasional
success. The ant-lion
itself is a gauzy
winged creature with
long body that re-
minds you somewhat of a very lazy damsel fly. Digger wasps are
again present, particularly a big black and orange one (Ammophila
procera) . A curious assemblage of southwestern desert forms are
found here on the ground stratum. The cactus (Fig. 60) is a strik-
ing plant, particularly if you inadvertently sit down on a patch.
The six-lined lizard (Fig. 61) is common in the same locality,
and an occasional parokeet is seen on the trees or shrubs (rare).

FIG. 163. — Ant-lion, Myrmelion, above (after
Shelford) and holes of its larvae.

ANIMALS OF THE DUNES

161

Certain beetles go along with the cactus and are found beneath
its leaves, Lacon rectangularis (Fig. 164), Prasocuris phellandrus
(Fig. 165). All these forms
even invade the preceding
pine or bronze beetle asso-
ciation, and to find the
boreal evergreens and
attendant northern ani-
mals in close juxtaposition
to cactus and lizard makes
an unwonted contrast.
The six-lined lizard lays
its eggs in the bronze tiger
zone, as does also the blue FIGS. 164-165: Fig. 164.— A click beetle,

racer (Fig l66) but I have Lacon rectangularis, found beneath cactus;

found the animals them-
selves more common in the
ant-lion association. Another snake, the hognose or puff adder

FIG. 1 66. — Blue racer, Coluber constrictor

(Fig. 167), is fairly common in this ant-lion association. It is a
mottled animal, a foot or more in length, that spreads and
flattens its head into a broad triangle after the manner of the

162 A NATURALIST IN THE GREAT LAKES REGION

poisonous snakes when disturbed, though it is quite harmless.
If teased it " throws a fit" and lies semi-rigid, belly up, apparently
feigning death.

Half a dozen new orthoptera are found on the ground or
shrubs in this association: the rusty, leather-colored, sprinkled,
and coral-winged locusts, the straight-lance and sword-bearing
grasshoppers, the Texan and the forked-tail katydids. The
latter two, however, have a very wide distribution and are

not therefore at all
distinctive of this
region. The rusty
locust is from .2-.6
inches long. It is
russet brown in color
with a yellow stripe
down the back. It
has a bulky body.
Its face is vertical.
The inner wings are
transparent, the tip
being slightly red.
The leather-colored
locust, a closely allied
species, is often found
associated with it,

especially near the margins of the swales, where the latter is often
found on the coarse grasses. The rusty locust is stouter than the
leather-colored, and its antennae do not exceed .6 of an inch, while
in the leather-colored they do, slightly. The sprinkled locust
(Fig. 1 68) is light brown (male) or clay yellow to dark brown
(female) . The sides of the shieldlike covering of the front part of
the thorax bears a glistening black bar in the male, a sprinkling of
black spots in the female. The fore wings are sprinkled with dark
spots abundantly in the female, sparingly in the male. The coral-
winged locust (Fig. 169) is the same size as the preceding, the

FIG. 167. — Puff adder or hognosed snake, Heter-
odon platirhinos. At left animal is rigid in a "fit."

ANIMALS OF THE DUNES

163

base of the inner wing is bright coral red. The basal half of the
inner face of the hind femur is Prussian blue. The females of
the straight-lance and sword-bearing grasshoppers are provided
with long ovipositors. In the former (Fig. 170) the ovipositor
is longer than the hind femur, and the sides of the body are
green. In the latter (Fig. 171) the ovipositor about equals the
length of the hind femur, and also the length of the body.
Among the insects no group exhibits more sharply denned
zonal limitations than the orthoptera. • While some species are
cosmopolitan, the majority are found only in definite situations

FIGS. 168-171: Fig. 168. — Sprinkled locust, Chloealtis conspersa; Fig. 169. —
Coral-winged locust, Hippiscus tuberculatus; Fig. 170. — Straight-lance grass-
hopper, Xiphidium strictum; Fig. 171 . — Sword-bearing grasshopper, Conocephalus
ensiger,

with clearly marked borders that are rarely overstepped. One
might name many of the associations with the characteristically
present orthoptera. Thus, the digger wasp association might be
called the maritime locust association. The bronze tiger associa-
tion could be quite justly called the narrow-winged locust asso-
ciation, while the ant-lion association might be designated the
coral-winged locust association.

Both in this and the succeeding association the oaks are
attacked by gall flies and other gall-forming insects that rear
their young in the different sorts of galls induced by their ovi-
position. Such galls seem to be more abundant on the dunes
than elsewhere. Some thirty different sorts can be collected
on the oaks in this and the succeeding mixed oak association,

1 64 A NATURALIST IN THE GREAT LAKES REGION

FIG. 172. — Six typical oak galls (from Felt): a, Spongy oak apple, Amphi-
bolips confluentus; b, Hollow oak apple, A. inanis; c, Woolly leaf gall, Andricus
flocci; d, Oak fig gall, Biorhiza forticornls; e, Woolly stem gall, Callirhytis semi-
nator; f, Knot gall, C. punclaius.

ANIMALS OF THE DUNES

165

including the oak apple, the empty apple, the petiole gall, the
wool gall, the midrib gall, the bullet gall, the seed gall, etc.
(Fig. 172).

With the advent of the red and
white oaks in the mixed oak asso-
ciation conditions begin to approxi-
mate those of the mesophytic
climax forests, the oak-hickory and
the maple-beech. The soil is well
supplied with humus. The shade
is deep enough to prevent excessive
evaporation and to afford cover for
the pioneers of that whole group of
animals that belong to the cool,
dark, moist recesses of these FlG' I73-~Tree toad'
climax forests. Earth-worms begin to appear. The holes of the
woodchuck are common and the mole exca-
vates his subterranean passages. Such snails
as Zonitoides arboreus, Polygyra thyroides, and
P. profunda are found under the bark of de-
caying trees, under logs, or crawling on the
shrubs in moist weather. They are by no
means so common as they are in the later
association. Millipedes and centipedes are
found under the bark of old logs. The car-
penter ant makes its chambers in the decay-
ing logs and stumps, and the aphid housing
ants use such passages as stables for their
"cows," the plant lice; it carries these
FIG. 174.— Tree through the winter in such sheltered retreats
toad, Hyla pickeringii. so it can pasture them out in spring on the
tender vegetation. Herbaceous plants are now numerous, and
there is an abundant insect population on them. Bumblebees,
honeybees, and wasps are common. Butterflies are abundant—
the monarch, viceroy, spangled fritillary, wood satyr, wood

1 66 A NATURALIST IN THE GREAT LAKES REGION

nymph, anglewing, mourning cloak, red admiral, Edward's hair-
streak, the zebra swallowtail, and the spicebush swallowtail, etc.
The tree frogs, Hyla versicolor (Fig. 173) and H. pickeringii (Fig.
174), are common on the shrubs and tree trunks. They are so
striking an addition with their birdlike peeps that the black oak-
red oak association is known on its animal side as the Hylodes
association. The walking stick is frequently shaken from the
foliage of the oak in late summer. The tree cricket, Oecanthus
angustipennis, and stinkbug are also commonly found on the
red oak leaves. The former is a pale green insect with gauzy
wings and long antennae with black dots on the basal joints of
the antennae. The red-tailed and red-shouldered hawks sail
over this territory and nest in the big trees. The red-headed
woodpecker, wood pewee, crow, blue jay, bluebird, least fly-
catcher nest in the trees, and the black and white creeping war-
bler, the yellow warbler, the wood thrush nest in the shrubs.
The gray and fox squirrels are present.

All these animals of the hylodes association, while strikingly
new if this zone is entered from the lake side, are old familiars
if the area is approached from the other direction, for they are
all even more common in the mixed oak-hickory association.
The oak-hickory and the maple-beech forests are the climax
mesophytic forests and will be considered in a succeeding
chapter.

CHAPTER IX
INTERDUNAL PONDS AND TAMARACK SWAMPS

k£J

S THE dunes are a series of sand ridges,
A I more or less parallel to the lake shore, so

l\ j^ j between them there lies a corresponding
h ««*JiijJij| •SflBJjl series of valleys, often steep sided with
r^^pi { interdunal ponds, swales, or swamps

(Fig. 175) in their bottoms according
as these are low enough to reach or
nearly reach the water level. Since the
newer dunes are close to the lake, so also are the new interdunal
ponds, while those farther and farther back from the lake are
of greater and greater age.

Now it is the fate of the permanent pond among the hills
to fill up and disappear. Rains wash soils down into it, plants
grow in its waters and along its margins, and their accumulating
remains fill it with vegetable debris that does not have time to
decompose before the next season's luxuriant growth is piled
upon it. The black muck at the bottom of the pond rises ever
nearer the surface; its lower layers transform to peat. Plants
that grow on sandy bottoms are replaced by those that grow
on muddy bottoms. Deep-water plants give rise to shallow-
water forms. Those plants characteristic of the margins
advance toward the center. So the pond transforms to marsh
and the marsh to low prairie or wet woodland. (See chap, xi
also.) These stages gradually ensuing with the characteristic
accompanying plants and animals may each be studied in
these interdunal ponds, beginning with those near the shore
and working back to the later stages.

Ponds near the lake shore are in a condition similar to the
central portions of shallow lakes and ponds farther inland, which

167

1 68 A NATURALIST IN THE GREAT LAKES REGION

portions have not yet been invaded by plants. A little farther
back are interdunal ponds stocked with Chara; then come others
with such plants as Myriophyllum and its associates, all forms
with finely dissected leaves. These plant populations are similar
to the zones shoreward from the bare-bottomed area in shallow
lakes. So the successively older dune ponds are comparable
to the successive zones of plant and animal forms in the filling
inland lakes. The older ponds", if good-sized, will naturally

FIG. 175. — Interdunal swale of the first type

themselves contain several zones, though smaller ones may be
completely occupied by the bulrush stage, the cat-tail -stage or
by similar plants characteristic of some one zone of the larger
filling pond.

The very new pond in the dune region is but a recent cut-
off from the lake. Its bottom is sandy; no plants have as yet
secured a foothold. There are present a few fish that find its
quiet waters good places to lay their eggs ; these must find access
by some channel connecting with the lake. The fish commonly
found in such a pond include the pike, the red horse, the Cayuga

INTEKDUNAL PONDS AND TAMARACK SWAMPS 169

minnow, and the shiner. There are also present some clams,

notably Lampsilis luteola, Alasmodonta marginata and Anadonta

grandis, the first confined to the very new ponds, the other two

occurring also in those somewhat older. There are found, too,

such insects as the caddis worm (Go era)

(Fig. 176) nymphs of the damsel flies of the

genus Lestes and of the dragon flies Tramea

lacerta and Celethemis eponina, the water

boatman, and occasional diving beetles that

fly, frequently seeking new territory in which

to hunt. The caddis-fly, damsel-fly, and

dragon-fly nymphs are characteristic, the

others cosmopolitan.

The damsel-fly nymphs are long, slender,
and bear three diverging gill plates at the FIG. 176. —Caddis-fly
posterior end of the body. Nymphs of Lestes larva' Goera' Enkrsed-
(Fig. 177) are recognized by the form of the so-called accessory
jaws (Fig. 178), really labial palps, on the extensible mask
of the head, which is the much modified lower lip or labium.

FIG. 177. — Nymph of damsel fly, Lestes for 'cipatus. Enlarged. After Needham

Each "jaw" has two processes, "one of them resembling a
fork with the median tines broken off, the remaining process
consisting of a long non-bifurcate projection with a short, hairy
hook at the distal end and minute teeth along the mesal margin."
The nymph of Tramea lacerta is green with brown markings.
The legs are long and thin. The spines of the eighth and ninth
segments are very long. The nymphs of C. eponina (Fig. 179)

170

A NATURALIST IN THE GREAT LAKES REGION

FIG. 178 FIG. 179

FIGS. 178, 179: Fig. 178. — Jaws
of nymph of Lestes forcipatus, after
Needham; Fig. 179. — Nymph of
dragon fly, Celethemis eponina.

have very prominent eyes, a very large labium, and the abdomen

is scarcely narrowed at all until the ninth segment. There is a

black band between the eyes and a black band encircling each
femur. The adult Lestes is rather dull colored,
and when it rests, the wings are held as a rule
spread horizontally rather than folded over the
back, as other damsel flies hold
theirs. The full-grown dragon fly
of Tramea lacerta has a wing-
spread of nearly 4 inches. The
body is dark, almost black. The
upper surface of the abdomen
bears white or greenish spots. It
flies from June to September.
C. eponina (Fig. 180) has a wing-
spread of about 3 inches. The

thorax is red-brown with black stripes. The abdomen is black

with yellow spots. The triangle is covered with a spot, and

there are two bands,

sometimes reduced to

spots, on each wing.

It also flies from June

to September.

Lampsilis luteola

(Fig. 181) has a

smooth shell with

distinct narrow green

,rays. It is about

twice as long as high.

It is good sized,

usually 3-5 inches long and quite thick. The muscle scars and

cardinal teeth are plain on the inside of the shell.

Alasmodonta marginata (Fig. 182) is rayed with broad green

radiating lines. In outline it is quadrate, the posterior region

being truncate. The umbones are marked by three distinct

FIG.' 180. — Adult dragon fly, Celethemis eponina.
After Needham.

INTERDUNAL PONDS AND TAMARACK SWAMPS 171

and one feeble double-looped ridges directed forward. It is
usually not over 3 inches long. Anadonta grandis (Fig. 183) is a
large clam 3-7 inches long. The shell is generally thin; the
muscle scars are not clear. The- color is dark green to black.
There may be rays on the young shell. The umbones bear
double-looped ridges.

The common pike (Fig. 184) is a slender fish up to 36 inches
in length. The head has no scales on its upper portion. The

FIGS. 181-183: Fig. 181— Shell of clam, Lampsilis luteola;
Alasmodonta marginata; Fig. 183. — Anadonta grandis,

mouth is very large, one-half the length of the head. The red
horse is one of the suckers all good-sized fish recognize by the
snouty head and the ventral position of the mouth. The lips
in this species are strongly plicate. It is a very widely distrib-
uted form. The Cayuga minnow and the common shiner are
both minnows belonging to the genus Notropis. The minnows
are usually small, 3-4 inches long, have very large scales in

172 A NATURALIST IN THE GREAT LAKES REGION

proportion to their size so that there are less than 40 in any one
of the rows running the length of the body. The Cayuga minnow
is about 2.5 inches long, olivaceous in color. The scales of the
lateral line are each marked with a crescentic black area, thus

FIG. 184. — The common pike, Esox lucius, one-eighth natural size

breaking the lateral line into a series of crossbars. The common
shiner (Fig. 185) has more than eight rays in the ventral fins.
The dorsal fin is either directly over or slightly in front of the
ventrals. The color of the fish is olivace-
ous, silvery below; the males, however, in
spring have the sides a rich salmon pink,
and in summer the olivaceous has a steel-
blue luster.

The first plant to invade these ponds
is usually the chara, an alga with its

FIG. 185 FIG. 186

FIGS. 185, 186: FIG. 185.— The shiner, Notropis atherinoides, one-half natural
size; Fig. 186. — Chara, reduced one-half.

smaller branches whorled (Fig. 186). It fastens itself to the
bottom and grows up in a perfect tangle of green. This plant
thrives best in the undrained ponds, but still is found in
those with some connection with the lake. It contains in
its tissues much silica so that it feels harsh when crushed
in the hand, and when pulled out of the pond it has a rank

INTERDUNAL PONDS AND TAMARACK SWAMPS 173

odor. It grows with great rapidity, covering the bottom
and growing up in the water, although not to the top. While
the chara is getting a foothold and covers the bottom only

FIG. 187. — The bluegill, Lepomis pallidus, reduced one-half

FIG. 188. — Pumpkin seed, Eupomolis gibbosus. After Forbes

partially, leaving bare spots, the bluegill (Fig. 187) and pumpkin
seed (Fig. 188) are found hiding among its tangles and nesting
in the bare places. The clams and caddis flies before mentioned

174 A NATURALIST IN THE GREAT LAKES REGION

FIG.
Nymph of the
dragon fly, Gom-
phus spicatus.

persist under such conditions. The burrowing dragon-fly nymph

(Gomphus spicatus} finds the somewhat muddy bottom congenial.

As the chara takes complete possession its tangled growth fur-
nishes a safe hiding-place for a new lot of fish —
mud minnows, golden shiners, the chub sucker,
the bullhead, and the tadpole cat.

The nymph of G. spicatus (Fig. 189) when full
grown is over an inch long. The body is flat,
hairy on the margins, and the legs are hairy.
The abdomen tapers gradually to a point. The
color is green, the eyes black. The adult flies in
May and June.

The mud minnow (Fig. 190) is about 4 inches
long. The upper parts are brownish olive,

mottled with black. The sides are barred in dark with bluish

intervals, underside yellow, fins olive green. The golden shiner

(Fig. 191), also called

bream or roach, is 6-8

inches long when full

grown . The body is deep ,

compressed, and tapers

both toward head and

tail. The head is small.

The lateral line sags distinctly. The color is dark olive green.-

The sides are silvery with golden reflections.

In the chub sucker (Fig. 192) the dorsal fin is short and

contains from ten to eighteen .developed rays. The lateral line

is wanting. The adult is only some 10 inches long. The color

is brownish-olive, with coppery luster above, paler below. The

young are longitudinally striped, the most conspicuous color

band being one of purplish black running through the eye and

along the side to the caudal fin. Below this the sides shade off

to a white or silvery belly.

The bullheads and catfishes have fleshy projectors, "feelers"

or barbels about the mouth. The brown bullhead (Fig. 193) has

FIG. 190. — Mud minnow, Umbra limi, reduced
one-half.

INTERDUNAL PONDS AND TAMARACK SWAMPS 175

twenty-two or twenty-three rays in the anal fin, including rudi-
mentary ones. It reaches 18 inches in length, though it is usually
much smaller. The color is dark yellow-brown to black above,
usually mottled; below
it is gray, pink, or
white. The lower
barbels are similarly
colored. The black
bullhead is found in
the older ponds.

The tadpole cat

FIG. 191.— Golden shiner, Abramis crysoleucas,

reduced one-half.

(Fig. 194) is a small
fish, 3-5 inches long,
with a thick, fleshy head, so it does have something the shape
of a tadpole. It is dark olivaceous above, yellow below. The
dorsal fin has a spine at its forward edge, which is more than

half the height of the fin.

The chara in the un-
drained ponds, as well as
those in connection with the
lake, swarms with the blood-
red larvae of Chironomus, a
midge. These bloodworms
crawl upon the plant and
build tubes -in which they
conceal themselves in part.
A new caddis-fly larva (Lep-
tocera) that builds a long,
slender tube of tiny sand
grains, replaces the one that
was common in the more open chara beds. In the deeper parts
of the chara, red water mites, Limnochares aquaticus are abun-
dant. Some small snails (Amnicola limosa and A. cincinnatien-
sis) are found creeping upon the plants on which larger snails are
also frequently present, namely, Physa gyrina, known by the

FIG. 192. — Head of chub sucker, Erimy-
zon sucetta.

176 A NATURALIST IN THE GREAT LAKES REGION

left-handed coil of its shell and the fact that the aperture is less
than two-thirds the length of the shell, Lymnaea reflexa and
Planorbis bicarinatus (Fig. 324) the former more abundant in the
older ponds. Lymnaea humilis and L. desidiosa are pretty much
confined to the younger ponds. Planorbis parvus, P. campanu-
latus, P. hirsutus are occasionally found in all the relatively newer

FIG. 193. — Brown or spotted bullhead, Ameiurus nebulosus. After Forbes

ponds. Snails of the genus Amnicola have small (.3 inch or
less) conical shells, the mouth of which is closed when the animal
draws back into its shell by a horny close-fitting disk, the oper-
culum. The edge of the opening is not connected with the body

FIG. 194. — Tadpole cat, Schilbeodes gyrinus

of the shell. In A. cincinnatiensis the aperture of the shell is
nearly half as wide as the shell is long. In A . limosa the round
opening is pressed quite against the body of the shell which is
unusual in the genus. The Lymnaeas do not have an oper-
culum. The shell is long with six or so whorls. L. reflexa is
.8 to 1.6 inches long. The spire is longer than the aperture.
The edge of the aperture is strongly turned back. L. humilis and

INTERDUNAL PONDS AND TAMARACK SWAMPS 177

L. desidosa are small, .6 inch long or less. The former has a
short conic spire with an aperture produced below, the latter,
a long, tapering spire and the aperture not produced. As the
name indicates the whorls of Planorbis are in one plane, so the

\

FIG. 195. — Nymph of damsel fly, Ischnura verticalis. Enlarged. After Needham

shell is flat. The mouth of the shell flares bell-like in P. campanu-
latus. P. hirsutus and P. parvus are small, . 25 inch or less in diam-
eter. In hirsutus the shell is covered with short, bristly hairs.

FIG. 196. — Buttonbush, Cephalanthus occidentalis, pushing out into pond

In P. parvus both sides of the shell (really top and bottom)
are equally concave. A small crustacean, a bender (Hyalella
knickerbockeri} is abundant, especially in the spring. In general
appearance it is much like Gammarus fasciatus (Fig. 56), but
while Gammarus swims on its side constantly, Hyalella does

178 A NATURALIST IN THE GREAT LAKES REGION

so only about half the time, going ventral side up the other
half of the time. Eucrangonyx gracilis swims on its back all the
time. It is found in the old forest ponds. Another crustacean
inclosed in a bivalve shell like a small clam is found abundantly
on the bottom (Cypris, Fig. 56). The musk turtle is a frequent
and distinctive inhabitant of these chara ponds. Its odor is

quite enough to distinguish it.
Chara ponds do not, as a rule,
support a varied or abundant
animal population, for the
chara is not an attractive food
plant.

As the chara grows and
its lower layers decompose,
it forms peat rapidly, i or
2 inches a year, so that
ponds tend to fill up speedily.
Then flowering plants, with
submerged stems and leaves,
the latter much dissected,
replace the chara. Their
flowers are reared above the
surface. Such plants are mil-
foil, bladderwort, pond weed
(Fig. 64), and their associates,
to be described more in detail
in chapter xi.

The nymph of the damsel fly, Ischnura verticalis (Fig. 195),
is quite characteristic of these milfoil ponds in the Dunes,
though it is a very widely distributed species elsewhere. The
nymph may be recognized by the fact that its gill plates end
in a long, tapering point and bear one or two dark crescentic
crossbands.

The adult male of Ischnura verticalis is green with the top of
the abdomen black. The females may be either black or orange

FIG. 197. — Pennsylvania saxifrage, Saxi-
.fraga pcnnsylvanica.

INTERDUNAL PONDS AND TAMARACK SWAMPS 179

and they have black spots near the tips of both wings; the fully
matured males have the spots on the front wings only. Other
forms to be listed below are also found here in the Myriophyllum
ponds, though not as abundantly as a rule as in the later ponds.

The newer ponds of the dunes may then be described in
order, naming them both from the characteristic animals and
plants: (i)theLamp-
silis luteolus ponds or
bare-bottomed ponds;
(2) bloodworm ponds
or Char a ponds; (3)
Ischnura verticalis
ponds or bladderwort-
milfoil ponds.

The older ponds
are usually them-
selves distinctly zon-
ated and must be
described in terms of
zonally arranged
plant and animal soci-
eties rather than as a
single society. Yel-
low and white water
lilies appear shore-
ward from the sub-
merged plants, then

FIG. 198. — The sensitive fern, Onoclea sensibilis,
underground stem and all.

come rushes, cat-tails, sedges, and so the filling chara ponds
give rise to marshy or swampy areas that seem to evolve into
three different types of regions, the differences depending
primarily on drainage, namely, (i) the wet forest, (2) the prairie,
and (3) the tamarack swamp.

In the first type (Fig. 175) grasses and sedges grow along
the margins, and with them are such plants as the buttonbush,
the sensitive fern, marsh marigold, white violet, and the swamp

i8o A NATURALIST IN THE GREAT LAKES REGION

saxifrage. The buttonbush, or elbow bush (Fig. 196), is a low
shrub with abruptly bent branches which give it the name elbow
bush. It bears large, egg-shaped leaves, rather pointed at both
ends. The flowers which are small and white occur in spherical
clusters. The marsh marigold or cowslip is familiar to almost
everyone. Swamp saxifrage (Fig. 197) has long, slender, lance-
shaped leaves that are mostly
basal; their borders are
toothed. The clustered flow-
ers are yellowish green on long
slender stalks. Sensitive fern
is so unlike the other ferns
of the region that it may be
readily recognized from Fig.
198. The leaf is roughly
triangular and cut into large
lobes, not finely dissected as
are most of the fern leaves.
It is very sensitive to frost
and dies in the early fall.

Still farther out on the
margin will be found a group
of plants that is common at
the outer edge of all the
marshes — sour gum, the
small-toothed trembling pop-
lar, swamp holly, two species
of Spiraea, the wintergreen, the cinnamon fern, Clayton's fern,
and the royal fern.

Sour gum (Fig. 199) is a deciduous tree that has, as a rule, a
trunk that runs straight to the top, as does the trunk of a pine.
The lower branches droop so that the tree has quite the appear-
ance of a conifer. The small-toothed trembling poplar has the
characteristic yellowish-green bark of the poplars. Its leaves
are small, finely toothed, and are borne on leafstalks that are

FIG. 199. — Sour gum, Nyssa sylvatica

INTERDUNAL PONDS AND TAMARACK SWAMPS 181

vertically flattened. When not in leaf the tree may be recog-
nized by the rounded leaf buds that are smooth. Swamp holly
(Fig. 200) is a shrub with alternate simple leaves which are
coarsely toothed but not spiny, as is suggested by the name of
holly. The fruits are red berries, as in the familiar Christmas
holly, but they are not clustered. They grow thickly, however,
on the shrub and persist through the early part of the winter.
Spiraea latifolia (Fig. 201), commonly known as meadow-
sweet, is another low shrub with simple alternate leaves that are

FIGS. 200-202: Fig. 200. — Swamp holly, Ilex verticillata; Fig. 201. — Meadow-
sweet, Spiraea latifolia; Fig. 202. — Steeplebush, 5. tomentosa.

lance-shaped and sharply toothed. The flowers, which occur
hi pyramidal clusters, are pink or pinkish white. Spiraea
tomentosa (Fig. 202), or steeplebush, is a still more slender shrub,
usually unbranched, the stem being covered with silvery hairs.
Conical clusters of pink or purplish flowers make it a conspicuous
and attractive plant. Clayton's fern, also called the interrupted
fern, the cinnamon fern, and the royal fern are closely related
species of the genus Osmunda. The royal fern (Fig. 203) has
leaves that are two or three times compounded. The spore
cases are borne at the tips of the leaves. The interrupted fern

182 A NATURALIST IN THE GREAT LAKES REGION

(Fig. 204) has a long and rather narrow frond with long and
narrow leaflets. Certain leaflets in the middle of the frond are
altered to bear the spore cases.
The fronds of the cinnamon

FIG. 203 FIG. 204

FIGS. 203, 204: Fig, 203. — Royal fern, Osmunda regalis; Fig. 204. — Clayton's
fern, Osmunda Claytoniana.

fern (Fig. 205) are similar to those of the
interrupted fern, but have their stalks
covered in youth with cinnamon-colored
scales. The spore-bearing fronds and the
vegetative ones are separate, the former
being devoted entirely to the spore cases
and appearing quite unlike fern leaves.

In the second type of pond (Fig. 206)
bulrushes encroach upon the pond lilies,
then comes a zone of sedges and grasses
and a few willows, mostly the shiny-leaved
FIG. 205.— Cinnamon willow. Still farther shoreward come the
fern, Osmunda tinna- — the blue-eyed grass (Fig. 102), the

momea, spore-bearing ° .

frond at left. yellow-eyed grass, the arrow-leaved violet

INTERDUNAL PONDS AND TAMARACK SWAMPS 183

(Fig. 131), and the lance-leaved violet, grass-of -Parnassus, and
the painted cup. Round the margins in addition to the shiny-
leaved willow one finds the red-osier dogwood, the shrubby
cinquefoil, and St. John's-wort.

Grass-of -Parnassus has heart-shaped basal leaves 1-2 inches
Jong with five conspicuous veins that run from end to end of the
leaf. The flower stalk bears a single conspicuous white flower,
bearing several greenish veins. The flower is about an inch in

FIG. 206. — Interdunal pond of second type

diameter. Painted cup is rather tall and conspicuous because
of the bright scarlet bracts among the flowers, giving the plant
the appearance of a paintbrush dipped in red paint. Red-
osier dogwood is a shrub with bright red stems, quite slender,
and very pliable. Shrubby cinquefoil (Fig. 207) is a low,
tufted shrub with bark that shreds off readily. The leaves are
palmately compound, with five or sometimes seven leaflets.
The flowers are yellow, about an inch across.

The animals found in these two types of ponds are practically
identical. In the deeper waters are found small clams of the

1 84 A NATURALIST IN THE GREAT LAKES REGION

family Sphaeridae (Fig. 2q8) . One thinks on first sight that these
are the young of the larger clams,
but such disappear from the dune
ponds with the replacement of the
sandy bottom by the muddy bottom.
In the Sphaeridae the lateral teeth
of the shell are found on both sides
of the cardinal teeth, while in the
larger clams they occur on one side

Frc. 207 FIG. 208

FIGS. 207, 208: Fig. 207. — Shrubby cinquefoil, Potentilla fruticosa; Fig. 208.
A small clam, Sphaerium simile.

FIG. 209.— Molt skin, nymph of Anax

only. A few mud-loving fish are present, like the black bullhead,
similar to the spotted (Fig. 193) but dark brownish or greenish

INTERDUNAL PONDS AND TAMARACK SWAMPS 185

black, unspotted or nearly so. It is our commonest bullhead.
The mud minnow (Fig. 190) is also present. Many damsel- and
dragon-fly nymphs are present in the marginal zone, and the
adults are found hovering over the
sedges and grasses. Those of Libel-
lula pulchella, Gomphus spicatus (Fig.
189), Leucorhini intacta, and Anax
junius occur in the rush and cat-
tail area.

The nymph of Anax (Fig. 209)
has very large eyes that occupy two-
thirds of the side margin of the head.
The adult dragon fly appears early
in spring, and flies late (late March
to mid-October).

The eyes of the adult are very FIG. 210.— Nymph and adult of

large also, meeting dorsally for some dras°n fly> Leucorhinia intacta.

... After Shelf ord.
distance. The insect is good sized,

the abdomen some 2 inches long. The color is green, marked
with brown and blue (male). The front of the face bears a dark

spot surrounded by
yellow that in turn
is encircled with a
blue ring.

The nymph of
L. intacta (Fig. 210)
is mud-colored, flat,
and the abdomen
terminates abruptly.

FIG. 211. — Dragon fly, Libellula pulchella.
Needham.

After

This is a small spe-
cies, the adult hav-
ing a wing-spread of about 2 inches. The body is black. The
upper part of the face is ivory white, obscured with yellow in
the female. It is commonly known as the white-faced dragon
fly. It flies in May and June.

1 86 A NATURALIST IN THE GREAT LAKES REGION

FIG. 21 zA.— Some aquatic insects and nymphs. After P. S. Welch, a, stone-fly
nymph; b, May-fly nymph; c, whirligig beetle larva; d, black-fly larva; e, damsel-
fly nymph; /, water tiger; g, larva of water scavenger; h, the dobson; i, diving
beetle; j, giant waterbug; k, smaller waterbug; I, water-scavenger beetle.

1NTERDUNAL PONDS AND TAMARACK SWAMPS 187

. 2 1 26.— Aquatic insects and nymphs. After P. S. Welch, a, adult mos-
quito, b, its larva; c, its pupa; d, water skater; e, marsh strider; /, whirligig beetle;
g, water scorpion; h, water boatman; i, back swimmer.

i88

A NATURALIST IN THE GREAT LAKES REGION

In L. pulchella the mask covers the most of face in the
nymphs; there is but a single median tooth on its median lobe.
The adult is (Fig. 211) dark brown to black with two wide green
stripes on each side of the thorax and one on each side of the
abdomen. The triangle of both fore and hind wings is colored
dark; in the front wing its long axis is at right angles to the
long axis of wing (July- August).

Electric-light bugs or waterbugs, both
great and small, water boatmen, back
swimmers and diving beetles, all on
Fig. 212, A and B, are numerous. The
six-lined diving spider (Fig. 213) is com-
mon on the bulrushes. The common
pond snail (Lymnaea reflexa) is very
abundant, as are also two of the flat
snails, Planorbis campanulatus and Pla-
norbis parvus. In the waters of such
ponds one will frequently dredge out
many of the little efts, Diemictylus
mridescens (Fig. 214). In the bulrush
zone and farther back among the low
shrubs the large garden spider (Fig. 215)
builds its orb-shaped webs in the
summer.

In the late summer the margins of such ponds and swamps are
alive with grasshoppers and their kind, whose stridulations are
incessant in such a location. Earlier in the season the grouse
locusts have had their day. They are small animals, less than
. 5 inch long. Tettix granulatus (Fig. 216) is moderately slender,
while the others have heavy bodies. Tettigidea armata and
T. parvipennis were common; T. later alls rare. The figure
of T. later alis is given in Fig. 216. T. parvipennis is much
like it, but the middle joints of the antennae are less than
three times as long as wide, while in T. lateralis they are more.
T. armata has the front margin of the thorax (pronotum) extend-

FIG. 213.— The diving
spider, Dolomcdcs sexpunc-
tahis. After Shelford.

INTERDUNAL PONDS AND TAMARACK SWAMPS i!

ing in a point between the eyes nearly to their fronts, while in
the other two species mentioned it does not come out to the
mid-eye.

FIG. 214. — The eft, Diemictylus vlridescens

I go A NATURALIST IN THE GREAT LAKES REGION

Now the ascendant forms on the rushes, sedges, and shrubs
at the pond margins and in the swales are the short-horned

FIG. 215. — Garden spider, the orb builder, Argiope

locust; the short- winged green locust (Dichromorpha viridus) ; the
slender-bodied locust — rare — (Fig. 219); the Hoosier locust

(July); Scudder's par-
oxya (August); the
leather-colored locust;
the Nebraska locust;
a striped ground cricket
and the marsh conehead
(Fig. 225). The short-
horned locust (Fig. 217)
is fairly good-sized, the

FIG. 216. — The grouse locusts, Tettix granulatus
and Tettigidea lateralis. After Lugger.

male measuring .8 inch

INTERDUNAL PONDS AND TAMARACK SWAMPS 191

in length; the female, i . 3 inches. They are bright green mot-
lied with brown, the brown sometimes being greatly increased

FIGS. 217-221: Fig. 217. — The short-horned locust, Tryxalis brevicornis; Fig.
218. — The short-winged green locust, Dichromorpha viridus; Fig. 219. — The slender-
bodied locust, Lcptysma marginicollis; Fig. 220. — The Hoosier locust, Paroxya
hoosieri; Fig. 221.— Scudder's paroxya, P. scudderi, male (a), female (6). All
after Blatchley.

192 A NATURALIST IN THE GREAT LAKES REGION

so as to be the dominant color. The, antennae are strongly
flattened at the base. The mature insects are found from
August to late fall.

The short- winged green locust (Fig. 218) is also green
marked with brown, or brown with green markings. It is
smaller than the preceding, the male being about . 6 of an inch
long; the female, slightly over an inch. The adults are found
as early as mid- July.

FIGS. 222-225: Fig. 222. — Striped ground cricket, Nemobins fascialus; Fig.
223. — Leather-colored locust, Schistocerca alutacca; Fig. 224. — Nebraska locust,
Phaetaliotes nebrascensis ; Fig. 225. — Marsh conehead, Conocephalus palustris.

The male of the Hoosier locust (Fig. 220) is quite brightly
colored. The face is green, the mouth parts, yellow. The
antennae are reddish brown. The rest of the animal is green,
yellow, and black. The female is more dully colored. The
latter is 1.25 inches long, the 'male not quite an inch long.
The antennae are very long.

Scudder's paroxya (Fig. 221) is small. The female is less
than i inch in length; the male, .6 of an inch. The general
color is brown with green-yellow markings. An ivory-white line
extends back from the eye; above it a broad black band.

INTERDUNAL PONDS AND TAMARACK SWAMPS 193

The leather-colored locust (Fig. 223) is yellowish brown to
olive, and a narrow bright yellow line runs over the middle of

FIG. 226. — A sphagnum bog, tamaracks at margin

the head and down the back. The male
is 1.25 inches long; the female, nearly
2 inches.

The Nebraska locust (Fig. 224) has a
slender body, a large head. It is olive
green marked with reddish brown; a broad
black band extends back from each eye.
The male is slightly less than an inch;
the female, slightly more than an inch in
length.

The striped ground crickets (Fig. 222)
are only about .4 of an inch long, brown FM. 227 FIG. 228

in color, with dark stripes lengthwise on FIGS. 2 2 7, 2 28: Fig. 227-

, . . „, i . T i j The slender sedge, Car ex

the head. They are very plentiful and are filiformis. Fig> 228.__The

OUt feeding by day. shore sedge, C. riparia.

194

NATURALIST IN THE GREAT LAKES REGION

The third type of swamp found in the dune region is the
sphagnum bog with its associated border of tamaracks (Fig.
226). It is one of the most striking associa-
tions of plants and animals to be found in the

FIG. 229 FIG- 23°

FIGS. 229, 230: Fig. 229. — The orchis, Arethusa bulbosa; details of blossom at
right. Drawing by L. N. Johnson; Fig. 230.— The bearded orchis or grass pink,
Calapogon pulchellus. Drawing by L. N. Johnson.

1NTERDUNAL PONDS AND TAMARACK SWAMPS 195

Chicago area. It 'is, furthermore, a widely distributed associa-
tion found at its best in northern North America and Eurasia
covering very wide areas. The sphagnum bogs found as far

232

233

'234 235 236

FIGS. 231-236: Fig. 231. — The sundew, Drosera rotundifolia; Fig. 232. —
Tickseed, Coreopsis grandiflora; Fig. 233. — Cottony grass, Eriophornm gracile;
Fig. 234. — Swamp horsetail, Equisehim fliimatile, and section of stalk; Fig. 235. —
Swamp fern, Aspidium Thelyptcris, and under side of one pinnule; Fig. 236. —
Sphagnum moss.

south as the Chicago area are isolated areas — islands in the midst
of the more typical associations. As will be seen in a later chapter
they are probably remnants of the vegetation that was quite wide-
spread in this region immediately following the glacial period.

196 A ^ATURALIST IN THE GREAT LAKES REGION

In the center of such a sphagnum bog is frequently found
a small lake that is filling, and this may be occupied in part by
chara (Fig. 186). Quite commonly the lake,
if it is sufficiently deep, will have, shoreward
from the chara zone, a zone of water lilies,
first the white, then the yellow.
The water shield is commonly
found growing with the white
water lilies. Next comes a zone
of floating sedges, the rhizomes
of which mat together so densely
as to form quite substantial foot-

FIG. 237. — Ragged orchis, Habenaria lacera, details
of blossom in small figures. Drawing by L. N. Johnson.

ing. This zone of floating sedges pushes
farther and farther out into the lake as ice
might form at the margin of a pond. The
chief mat-forming sedge is Carex filiformis
(Fig. 227). The shore sedge, Carex riparia

INTERDUNAL PONDS AND TAMARACK SWAMPS 197

A

(Fig. 228), is often found associated with it. Beyond the outer
edge of the sedge mat one often finds bladderwort (Fig. 64)
growing in the water. As one walks over this sedge mat the
surface heaves up and down
as if one were walking on
rubber ice. In places where
the sedge mat is thin, cat-
tails are likely to be growing.
Farther back toward shore
where the sedge mat rests
on the peaty soil a number
of characteristic plants are
to be found. The orchids
are present, especially
Arethusa bulbosa (Fig. 229)
and the grass pink, Calapo-
gon pulchellus (Fig. 230).
The sun dew, Drosera ro-
tundifolia (Fig. 231) is a
small but striking plant.
The little round leaves are
covered with upright glan-
dular hairs, at the tip of
each of which is a drop of
sticky substance sparkling
like dew. This leaf is an
insect trap. When the insect
alights upon it, it sticks as
it would to fly paper. The
leaf then closes, the tips of the hairs are pressed against the
body, the animal is digested, and the plant feeds upon the
absorbed organic material. The other plants of this same associa-
tion are the swamp milkweed, known by its milky juice and
flowers like the other milkweeds, the marsh bellflower, tickseed,
Coreopsis grandiflora (Fig. 232), cottony grass (Fig. 233), swamp

FIG. 233.— Fragrant ladies'-tresses, Spi-
ranthes Romanzoffiana (details in small fig-
ures.) Drawing by L. N. Johnson.

198 A NATURALIST IN THE GREAT LAKES REGION

horsetail (Fig. 234) and on the drier parts of the sedge mat the
swamp fern, Aspidium Thelypteris (Fig. 235).

Shoreward from the sedge zone is a zone in which the ground
stratum is marked by an abundant growth of sphagnum moss
(Fig. 236) above which is a shrub stratum with a striking group of
xerophytes, the most conspicuous of which is the leatherleaf,
Chamaedaphne calyculata (Fig. 239). The zone is usually called
the cassandra zone. Sphagnum is a pale green moss whose
spongy tissue holds with tenacity an immense bulk of water.
It forms a soft carpet, often a foot deep. Below it the peaty
soil lies to a depth of several feet usually saturated with water
and very cold. The soil temperature will be in the neighbor-
hood of 50° F. in midsummer, even on days when the air tem-
perature is around 100° F.

Growing in the sphagnum one finds such orchids as Arethusa
(Fig. 229), the ragged orchis (Fig. 237), fragrant ladies'-tresses
(Fig. 238), together with cranberries, both large and small, cot-
tony grass, and, most striking of all, the pitcher plant. This
latter is another of the queer insectivorous plants found in this
bog region. Its vase-like" leaves which spring in clusters from
the central root are 8 or 10 inches long and are lined with slippery
hairs pointing down. The lip of the vase bears a ridge of succu-
lent tissue on which numerous insects feed with avidity. In their
eagerness they sometimes slip off into the pitcher which is partly
filled with water. To crawl back against the sharp pointed hairs
is not easy. So the bottom of the pitcher usually contains a
more or less concentrated "insect soup" that is absorbed by
the plant and serves as food (Fig. 240).

In the shrub zone besides the leatherleaf areiound Andromeda,
chokeberry, low birch, and other shrubs of similar character.
Andromeda (Fig. 241) is a low evergreen shrub with narrow
leaves that have their edges rolled back and the under sides of
the young leaves covered with a white varnish. The urn-shaped
corolla is pink, sometimes white. The flowers are in small clus-
ters (umbels).

INTERDUNAL PONDS AND TAMARACK SWAMPS 199

Chokeberry (Fig. 242) is a shrub a yard or so" high. The
leaves are shiny above, paler and covered with fine hairs below.

2:42

FIGS. 239-244: Fig. 239. — Leatherleaf, Chamacdaphne calyculata; Fig. 240. —
Pitcher plant, leaf and blossom, Sarracenia pur pur ea; Fig. 241. — Andromeda,
Andromeda Poli folia; Fig. 242. — Chokeberry, Pyrus arbutifolia; Fig. 243. — Rush
aster, Aster junceus; Fig. 244. — Crested shield fern, Aspidium cristatum, under
side of one pinnula and outline of sorus.

The flowers are like apple blossoms and grow in clusters.

The fruits, like small red apples, are .3 of an inch in diameter.

One familiar with the birches would recognize the swamp

birch by its bark. Its leaves are egg-shaped, rounded, or even

200 A NATURALIST IN THE GREAT LAKES REGION

kidney-shaped. The young leaves as well as the branches are
downy.

Leatherleaf shows well the characteristics of this group of
xerophytes. Its leaves are thick and glossy with the wax in
the epidermis; the under side of the leaf is scurfy — all devices
to prevent the loss of water. One wonders at such xerophytic
characters in shrubs growing in a swamp. But while water is
abundant it seems to be difficult for the root hairs to absorb
it. This is explained, in part at least, by the low soil tempera-
ture and the acidity of the soil. These conditions also prevent
the decomposition of the plant debris accumulating from season
to season, since they check the activity of the soil bacteria so
necessary for this process. This debris accumulates, therefore,
as peat instead of decomposing to help form humus as it would
in most soils.

Next to the cassandra zone comes the tamarack zone
(Fig. 226) with tamarack or larch trees as the most conspicuous
plants. These are deciduous conifers with the needles in clusters
of sixteen or more. Where these trees stand thickly, few plants
grow under them, except the sphagnum which usually covers the
ground. The soil is wet, peaty, and cold, for the sunlight does
not penetrate the dense tamaracks readily. Soil temperature
remains about 35° F. even in midsummer. In the more open
parts of the tamarack bog, in addition to the herbaceous plants
of the cassandra zone which invade it to some extent, there are
found the rush aster (Fig. 243), swamp rose, Rosa mrginiana
with its stout hooked prickles, red-osier dogwood, poison sumac,
(Fig. 107) and several ferns, the crested shield-fern (Fig. 244),
royal (Fig. 203), and cinnamon ferns (Fig. 205).

Shoreward from the tamarack zone there occurs a transition
zone that varies according to the environment. One may pass
from a typical black oak dune association to the tamarack bog
society in a dozen steps, or the bog may gradually change to an
interdunal swale of one of the preceding types. The transition
may be from an oak-hickory forest in moraine country through

INTERDUNAL PONDS AND TAMARACK SWAMPS 201

a willow marginal zone occupied by the typical plants of the
usual low, wet area.

One must expect to encounter many variations from the
typical arrangement outlined above. The pond may have
disappeared entirely as the floating sedges have overgrown it.
The sedge zone may have disappeared and the sphagnum bog
may occupy the whole depression, either with or without the
tamarack border. The association may be in a still later stage
in which the tamaracks only are present, the pond having filled,
the floating sedge zone having been displaced by the sphagnum-
cassandra association, and this in turn driven out by the advance
of the tamaracks. This tamarack association may be gradually
disappearing as plant debris accumulates, transforming the bog
into a drier area with abundant humus in which the plants of
the surrounding highland may establish themselves.

Most of the animals of the tamarack bog are not peculiar
to it but are found in other marshes or swamps. In the water
held by the leaves of the pitcher plant there breeds a species of
mosquito that is subarctic. Certain orthoptera are the most
characteristic animals of the sphagnum bog and its borders — the
short-winged brown locust, Stenobothrus curtipennis, the striped
locust, Mecostethus lineatus, the northern locust, Melanoplus
extremis, the marsh ground cricket, Nemobius palustris, and the
small brown cricket, Anoxipha exigua. The bog tiger beetle
(p. 145) is also distinctive.

CHAPTER X

THE CLIMAX FOREST AND ITS PREDECESSOR. THE
OAK-HICKORY TYPE

]HE succession of stages traced in the
preceding chapter lead on to the climax
forest. On the dunes cottonwoods and
their confreres are replaced by the pine
association. This is in turn invaded
and ultimately displaced by the black
oak society. After many generations
of accumulated forest debris, the soil
becomes sufficiently rich in vegetable mold under such trees to
support red oaks, then white oaks, and the mixed oak succession
follows with its associated shrubs and herbs. Then hickories
appear with the oak, and finally under most conditions maples
and beeches displace all other trees. The interdunal pond and
the filling lake, if they lead on to a forest at all, go through a
similar succession and end in the same climax forest, except
possibly in the case of the sphagnum bog.

Probably not one but many factors are involved in this suc-
cession. The increasing quantity of decomposing vegetable
matter in the soil not only supplies more and more plant food but
it also increases very greatly the power of the soil to retain mois-
ture. The numerous penetrating rootlets of the dense forest
growth, the burrows of earthworms and other animals not found
in the earlier stages increase the porosity of the soil. Increasing
shade prevents rapid evaporation, maintains a lower temperature
by shutting out the sun 's rays, reduces wind action, and lessens
very greatly the light intensity. In the beech-maple forest
the photographic exposure meter indicates a light intensity of
only one-tenth to one-twentieth that of the surrounding open

THE CLIMAX FOREST AND ITS PREDECESSOR

203

country. The plants and animals of the forest floor are there-
fore shade-loving and moisture-loving forms.

The maple-beech forest is the last in the succession because
in the dense shade under these trees few seedlings other than
beech and maple can survive; the young of the other trees
demand more light. This is probably only one of several factors
important in the elimination of other seedlings. As the pine
forest grows old and dense, black oak seedlings appear, and these
trees gradually overtop the pines, the latter dying in the struggle

FIGS. 245-247: Fig. 245. — Leaf and flower of tulip tree, Lirodendron Tnlipifera;
Fig. 246. — Leaf and nut of white walnut, Juglans cinerea; Fig. 247. — Leaf and nut
of black walnut, /. nigra.

for existence. So in the black oak forest seedlings of red and
white oak appear, and when mature they shut out the black oak,
but the beech-maple forest has only beech and maple seedlings
together with a few other trees that can stand the same con-
ditions. There will be an occasional tulip tree (Fig. 245), black
and white walnuts (Figs. 246, 247), black cherry (Fig. 248),
hackberry (Fig. 249), with some elms (Fig. 250), and sycamore
(Fig. 251) in the lower portions.

The tulip tree (Fig. 245) is recognized by its large leaf, shaped
something like a maple leaf with the tip cut square off. The

204

NATURALIST IN THE GREAT LAKES REGION

bark of the walnut has high
ridges inclosing diamond-
shaped areas. The pith of
the twig is divided into
numerous compartments by
cross-partitions. The bark of
the black cherry is broken
into irregular polygonal areas
by numerous cracks and so
has something of the appear-
ance of alligator-skin leather;
the buds and twigs are bitter,
tasting much like cherry pits.
The bark of the hackberry has
numerous high, corky, verti-
cal ridges on it, while the bark of the sycamore scales off in flakes,
showing light patches through the otherwise greenish brown bark.

FIG. 248.— Trunk of the black cherry
Primus scrolina.

FIG. 249. — Hackberry trunk, Celtis occidentalis, and trunk of beech (at right)

THE CLIMAX FOREST AND ITS PREDECESSOR 205

The climax forest is distinctly stratified (Fig. 252). Beeches
(Fig. 249) and hard maples (Fig. 253) rear their crowns in the
intense sunlight. In such
a superb example of the
climax forest as is found
in Warren's Woods near
Three Oaks, Michigan, a
forest preserved for all
time to nature-lovers by
the munificence of its
owner, the late E. K. War-
ren, the trees rear unrivaled
columns, 75 feet or more,
without a branch. The
Gothic aisles of this vast
temple are ornamented
with trees of less stature
such as pawpaw, hop horn-
beam, water beech, flower-
ing dogwood, re'dbud,
Juneberry, chokecherry
(Fig. 1 1 6) whose tops form

a second stratum.

FIG. 250. — American elm, Ulmus americana

FIG. 251. — Leaf and fruit
of sycamore, Platanus occi-
dentdis.

Then comes the tall
shrub stratum with witch-hazel, spice-
bush, high bush cranberry, maple-leaved
viburnum, nannyberry, wahoo, black
currants, gooseberry, leatherwood, elder-
berry. Beneath these is a lower stratum
of low shrubs, herbs, and ferns. Among
the low shrubs are strawberry bush,
pigeon berry (Fig. 265), shinleaf (Fig. 93),
wintergreen (Fig. 94).

The pawpaw (Fig. 256) has a trunk
from 5 to 10 inches in thickness with
dark brown smooth bark; the leaves are

206 A NATURALIST IN THE GREAT LAKES REGION

lance-shaped with the broad end toward the apex. The flower
is quite conspicuous, an inch or two across, dull purple, with

FIG. 252. — Climax beech-maple forest showing stratification

the parts in threes. The hop hornbeam and water beech have
leaves much like elm leaves in general form. The former
(Fig. 257) has fruits somewhat similar to
hops. The bark of the tree is narrowly
ridged and shreds off in narrow strips.
The latter (Fig. 137) has a smooth trunk
that is fluted like a Corinthian column.
Witchhazel (Fig. 255) can usually be recog-
nized by its fruits that remain on the shrub
nearly the year around. The dogwood
(Fig. 254) is a small tree conspicuous when
in bloom, for the blossom cluster is sub-
tended by four conspicuous white bracts.
The redbud (Fig. ,58) is also a low tree.
Clusters of red pea-shaped blossoms come charu

THE CLIMAX FOREST AND ITS PREDECESSOR 207

in spring before the leaves. These blossoms appear. on short

branches that come out from the main trunk and main branches.

Even when not in

blossom the tree may

be recognized by the

presence of these

short, stubby, flower-
ing branches.

The maple-leaved

viburnum is similar

to the high bush cran-
berry (Fig. 259) which

is also a viburnum.

It is a lower shrub,

3-5 feet high, with

maple-like leaves that

are downy below and

fruits that are at first

red, then purple.

The nannyberry

(Fig. 260), also a

viburnum, has upper

leaves that are taper-pointed and the leaf stems are winged.

The fruit is black. Spicebush (Fig. 298) is recognized readily

by the spicy odor of the crushed leaves and twigs. The high

bush cranberry is a fairly tall
shrub or low tree with oval,
finely toothed leaves. The
flower cluster of small white
blossoms is large, and the red
fruits conspicuous. The con-
tained seed is flat. The wahoo
(Fig. 261) is generally recog-

FIG. 255.-Twig of witch-hazel, Hama- ™ZQd by the f°Ur COrky ridgeS

melis virginiana. that run longitudinally on

FIG. 254.— Flowering dogwood, leaf and blossom,

Cornns florida.

FIGS. 256-264: Fig. 256. — Pawpaw, Asimina triloba; Fig. 257. — Hop horn-
beam, Ostrya virginiana; Fig. 258. — Redbud, Cercis canadensis; Fig. 250. — High
bush cranberry, Viburnum opulus; Fig. 260. — Nannyberry, V.lentago; Fig. 261. —
Wahoo or burning bush, Ewnymus atropurpureus; Fig. 262. — Elderberry, Sam-
bucus canadensis; Fig. 263. — Strawberry bush, Ewnymus americana; Fig. 264. —
Jack-in-the-pulpit, Arisaema triphyllum; the larger figure shows the top of the
"pulpit" thrown back.

THE CLIMAX FOREST AND ITS PREDECESSOR 209

each twig, giving the twig a square cross-section. Leatherwood
is low, not over 7 feet high, with very soft, white wood and very
tough, fibrous bark. The branchlets are jointed, and the leaves
are very short-petioled. Elderberry (Fig. 262) is readily recog-
nized by the very large amount of pith in the stems. The wood
layer is relatively thin. Strawberry bush (Fig. 263) is a low
shrub with more or less of a creeping habit. The leaves are
almost without stalks, lance-shaped, and finely toothed.

On the ground of such a forest there are a large number of
plants (Fig. 55) that spring up quickly in the spring before the
trees are in leaf, blos-
som, and mature their
fruit before they are
so densely shaded as
to preclude their in-
tense activity. The
spring beauty, spring
cress, toothwort, hepa-
tica (Fig. 139), blood-
root, red and white
trillium, dog-tooth

violet, jack-in-the- FIG. 265.— Pigeon berry or dwarf cornel, Cornus

pulpit (Fig. 264),green canadensis-

dragon (Fig. 266), Dutchman's breeches, wild ginger, all belong
to this group. This vernal flora consists of plants in whose
underground stems or succulent roots there is stored abundant
food for this burst of speed in the accomplishment of their life-
cycle. In many cases, too, their leaves and flower buds are
warmly clothed in hair, and not a few have leaves that cuddle
close to the warm earth in dense clusters.

Later the ground is pre-empted by plants that are better
able to endure the shade and that take more time to blossom
and mature their fruit. Such are the long-spur (Fig. 143) and
Canadian violets (Fig. 142), wood violet, the latter with a pal-
mately five- to nine-lobed hairy leaf, wood phlox, the columbine

2io A NATURALIST IN THE GREAT LAKES REGION

(Fig. 122), red and white baneberry, Solomon's seal, waterleaf,
sweet cicely, clearweed (Pilea pumila) , bedstraw, ginseng, touch-
me-not. Certain kinds of ferns are very characteristic of such
woods, and the many sorts that grow are here noted for their

270

271

FIGS. 266-271: Fig. 266. — Green dragon, A risaema dracontium; Fig. 267. —
Baneberry, Actaea alba; Fig. 268. — Waterleaf, Hydrophyttum virginianum; Fig.
269. — Sweet cicely, Osmorhiza Claytoni; Fig. 270. — Clearweed, Pilea pumila
Fig. 271. — Bedstraw, Galium aparine.

luxuriance. The beech fern (Fig. 274), maidenhair (Fig. 275),
wood spleenwort (Fig. 276), pale wood fern (Fig. 277), Christ-
mas fern (Fig. 278), lady fern (Fig. 279), margined fern (Fig. 280),
florists' fern (Fig. 281), and ostrich fern (Fig. 282) are among the

THE CLIMAX FOREST AND ITS PREDECESSOR 211

sorts to be found, some abundantly, others only in favorite spots.
In ravines and lower areas the cinnamon fern, Clayton's fern,
and sensitive fern are to be noted, while the brake (Fig. 283) is
common on borders and open spots. Many mosses grow on the

FIG. 272. — Ginseng, Panax trifolium

decaying logs and on the moist ground; lichens are plentiful
and fungi particularly abundant.

Baneberries (Fig. 267), both white and red, are low shrubs
with a leaf having a three-parted stalk, each division bearing
three to five leaflets. In water leaf (Fig. 268) the green leaves

212 A NATURALIST IN THE GREAT LAKES REGION

are mottled with pale areas looking as if the darker color had
been washed out by sprinkling water on the leaf. The leaves
are quite large, deeply lobed, and hairy. Sweet cicely (Fig. 269)
gives the odor or taste of licorice when the foliage is crushed.
Clearweed (Fig. 270) has a semi-transparent stem. The leaves
are egg shaped and bear large coarse teeth. The flower clusters
are in the axils of the leaves. The plant looks like a nettle, but
does not have stinging hairs. Bedstraw (Fig. 271) is a low

FIG. 273.— Touch-me-not or wild balsam, Impatiens pallida. Blossoms at
right, pod at left; inset, pods after discharge of seeds.

trailing herb whose foliage is harsh. The stems are covered
with points that make them very, rough. Ginseng (Fig. 272)
when in blossom is readily recognized by the small ball of white
flowers. Touch-me-not (Fig. 273) only occurs in the moist
places. The stem is translucent ; the flowers are yellow, mottled
with dark spots. The seed pod, when ripe, explodes on touch,
scattering seeds to some distance.

Animal life is as abundant and varied as the plant life.
Earthworms are abundant in the soil. Here, too, are some insect
nymphs like that of the cicada. Some rodents are present as

FIGS. 274-282: Fig. 274. — Beech fern, Phegoptcris poly podi aides; Fig. 275. —
Maiden-hair ieTn,Adiatitum pedatiim, portion of frond; Fig. 276. — Wood spleen-
wort, Asplenium acrostichoides; Fig. 277. — Pale wood fern, Aspidium novaboracense;
Fig. 278. — Christmas fern, Polystichium acrostichoides; Fig. 279. — Lady fern,
Asplenium Filix-femina; Fig. 280. — Margined fern, Aspidium marginale; Fig. 281 —
Florists' fern, A. spinidosum; Fig. 282. — Ostrich fern, Onoclea struthiopteris.

214 A NATURALIST IN THE GREAT LAKES REGION

characteristic inhabitants, such as the common mole (Fig. 286) ;
the common or long-tailed shrew, similar to the short-tailed
(Fig. 425), but the former is only 4 inches long, the tail making
1.5 inches of that length; the latter is 5 inches long and the tail
is only i inch or less; and the white-footed deer mouse (Fig. 287) .
Under and in the old logs in various stages of decay are found a
host of snails. Indeed, this moist forest is the favorite haunt
of the land snails and slugs, Polygyra albolabris, fraudulenta,

hirsuta, inflecta, mono-
don, oppressa, palliata,
are abundant as are also
Pyramidula alternata,
perspectiva, and solitaria,
Omphalina fuliginosa
and friabilis, Zonitoides
arboreus. Circinaria
concava is common, a
carnivorous form that
feeds on other land snails
(Figs. 284, 285). In
moist weather all these
kinds may be found
traveling over the leaves

upon the ground, old

FIG. 283.— Bracken, fern, Pteris aquilir.a , . ,

logs, shrubs, and tree

trunks. In drier weather they are in hiding under logs and
stumps. The Polygyras are all land snails distinguished by the
fact that the edge of the opening of the shell is reflected in a
broad lip. P. fraudulenta and P. inflecta have two projections
called "teeth" on the lip of the opening, one on the body wall
(parietal tooth). The former has an open umbilicus at the
base of the spire, the latter has none. P. monodon, P. hirsuta,
and P. fraterna are small, one-half inch or less in diameter. The
lip is notched in hirsuta, and the shell is covered with short dense
hair. P. fraterna is similarly hairy, but the lip is not notched.

THE CLIMAX FOREST AND ITS PREDECESSOR 215

Its shell is narrowly umbilicate. P. monodon is not hairy, the lip is
not notched, and it is widely umbilicate. The following are much

FIG. 284. — Various species of Poly gym, common land snails, life size:
a, Polygyra albolabris, the white-lipped snail (note covered umbilicus) ; b, P. hirsuta,
the hairy snail (note notch in lip); c, P. multilineata, the many-banded snail;
d, P. palliata; e, P. pennsyhanica; f, P. profunda (note wide open umbilicus);
g, P. thyroides; h, P. tridentata, the three-toothed snail.

216 A NATURALIST IN THE GREAT LAKES REGION

b

FIG. 285. — Land snails: a, Circinaria concava; b, Helicodiscus parallelus;
c, Omphalina fuliginosa; d, Polygyra tridentata; e, Zonitoides arbor etis; f, Polygyra
monodon; g, Pyramidula alternata; h, Philomycus carolinensis (a slug) ; i, Pyrami-
dula solitaria; j, P. perspeetiva; k, Succinea avara; I, S. ovalis; m, S. retusa;
n, Cochlicopa lubrica; o, Bifidaria armifera; p, Vertigo ovata; the last three much
enlarged,

THE CLIMAX FOREST AND ITS PREDECESSOR 217

larger shells. P. multilineata and P. profunda are marked with
revolving brown bands and are the only ones so marked: the
former has no' umbilicus; the latter, a very wide one. P. albo-
labris has the umbilicus completely covered, P. pennsyhanica,

FIG. 286 FIG. 287

FIGS. 286, 287: Fig. 286. — Under side of head end of common mole, Scalopus
aquations; Fig. 287. — White-footed deer mouse, Peromycus leucopus, and imprint
of fore and hind foot, reduced one-half.

nearly covered, P. thyroides about half-covered. The latter is
distinctly striate with fine ridges. P. clausa is similar but
unstriate, and the shell is high as compared with that of

P. thyroides.

The Pyramidulas do not
have the reflected lip.
Their shells are quite flat
and coarsely striate. P. per-
spectiva and striatella are
small. The former, .5 inch
in diameter, reddish in
color, has six and one-half
whorls. The latter, .25
inch in diameter, is brown
in color and has only four whorls. P. solitaria has three
spiral brown bands, while P. alternata is marked with alternate
patches of dark and light. The Omphalinas have paper-thin
polished shells. O.fuliginosa is mahogany brown with a pearly
aperture. O. friabilis is similar, but the shell is still thinner.
Zonitoides arboreus is small, only .12 inch in diameter. The shell

FIG. 288. — The common slug, Agriolimax
campestris.

218 A NATURALIST IN THE GREAT LAKES REGION

is amber if empty, dark brown when the animal is in it. Cir-
cinaria concava is .5 inch or more in diameter, green horn-color
outside and red-brown within the aperture.

The great slug, Philomycus carolinensis (Fig. 285), and the
smaller slugs, Agriolimax campestris (Fig. 288) and Pallifera
dorsalis, are found in similar situations. Not infrequently under
strips of bark one finds clusters of the eggs of slugs or snails like

FIG. 289. — The large millipede, Spirobolus marginatus

heaps of small pearls. Philomycus is yellow white, spotted with
brown or black. The other two are ashy in color. Pallifera has
a dark line down the back and is less than an inch long. Agrioli-
max is larger with no line down the back. Under the bark of
logs in midstages of decay one finds also several centipedes and
millipedes. The big round Spirobolus marginatus (Fig. 289) —
.5 inch in diameter and 5 or 6 inches long when full grown — is

FIG. 200

FIG. 291

FIG. 290,291: Fig. 290. — Yellow-margined centipede, Fontaria corrugate,
Fig. 291. — The red centipede, Geophilits rubens.

fairly common. Another, Fontaria corrugate (Fig. 290), is flat-
tened somewhat and is brown in color with yellow margins.
Lysiopetalum lactarium, a centipede, discharges a milky fluid
when handled, while Geophilus rubens (Fig. 291) is a large reddish
fellow. Sow bugs and roaches are abundant here, too. In logs
that are in earlier stages of decay one finds numerous boring
beetles. The click beetles and their larvae, the wire worms,

THE CLIMAX FOREST AND ITS PREDECESSOR 219

including the big eyed elater (Fig. 292), are common under

the bark, as are some ground beetles in hiding here. The

green-legged locust and Blatchley's locust (Fig. 293) are

characteristic. In the wood, in gal-

leries which they excavate, are the

larvae of wood borers; the flatheads,

larvae of metallic wood borers, and

the fleshy grubs of the horned Pas-

salus (Fig. 294). Carpenter ants and

carpenter bees, the latter small but

brilliantly colored in metallic blues

and greens, are to be found in the

same situation. Several species of

beetles (Fig. 295) are found in the

fungi on the forest floor and on old

logs. Two amphibians are charac-

teristic here, the red-backed sala-

mander found hiding in moist

recesses under old logs, and the wood .frog, Rana sylvatica

(Fig. 296). The latter is so common, hopping on the forest

floor, and so characteristic of the climax forest that Shelford

calls this beech-maple society the wood frog association. Tree

FlG- 292— The eyed elater,
, and its larva.

FIG. 293. — Blatchley's locust, Melanoplits blatchleyi

frogs, Hyla versicolor and H. pickeringii, are found here but are
also abundant in earlier forest stages (Figs. 173, 174).

In the shrub stratum are some characteristic insect larvae and
some spiders. The larva of Papilio ajax is found on the pawpaw,
and the butterfly wings its tantalizing flight through the forest
and about its margin (Fig. 297) . The green-clouded swallowtail,

220 A NATURALIST IN THE GREAT LAKES REGION

Papilio troilus (Fig. 298), rears its young on the spicebush.
Epeira gigas, Neocosoma arabesca (Figs. 304, 305) are character-
istic spiders hanging their webs on the taller shrubs, though

they are even more abundant
in the oak-hickory associa-
• tion.

This forest is the home of
many birds. The ovenbird
builds its overarched nest on
the ground. The wood pewee
calls plaintively from the
quiet deeps of the woods.
The evening song of the wood
thrush lends charm to the
quiet hour. Both these and
the red-eyed vireo, the scarlet
tanager, and the great crested
flycatcher nest in the shrubs and low trees. During migration
the tree tops are alive with warblers; the black and white creep-
ing and the yellow warblers remain to nest. The red-shouldered

FIG. 294. — The horned Passalus and
its larva, Passalus cornutus.

FIG. 295

FIG. 296

FIGS. 295, 296: Fig. 295. — Fungus beetles: a, Diaperis maculata; b, Pisemis
humeralis; c, Boletotherus bifurcus; Fig. 296.— The wood frog, Rana sylvatica.

hawk, together with some other hawks, nest early in the taller
trees. At dusk the call of the little screech owl, a wavering
minor whistle, and the hoot of the great horned owl are heard.
These nest in February in the hollows of the trees.

THE CLIMAX FOREST AND ITS PREDECESSOR 221

The oak-hickory forest, with scattered individuals of black
cherry, walnut, and linden, is the prevalent type on the moraines
about Chicago. It
also is stratified as is
the beech-maple
forest, though the
undergrowth is as a
rule not as tall nor
as abundant. Hazel,
dogwood, and the
wild rose are among
the common shrubs.
The spring herbace-
ous plants are simi-

, r i FIG. 297 FIG. 298

lar to those of the FiGg ^ 2Qg: Rg 297>_Pawpaw swaiiowtaii(

beech-maple forest. Papilio ajax, on pawpaw; Fig. 298. — Spicebush

Goldenrods, asters, swallowtail- p- lroilus> on spicebush.
and sunflowers are abundant in the fall. Ferns are at times
abundant, but only a few of the ferns found in the beech-maple

forest are present in
the oak-hickory
forest. The com-
mon ones are cin-
namon fern, the
interrupted fern, the
sensitive fern in the
moist areas, and the
brake in open spots.
There are char-
acteristic animals
in the soil, on the

FIG. 299— Cicada, Cicada linnei, and nymph of a ground, and in the
cicada, the one below.much enlarged. From Lugger. ,•,. r •,

leaves close to the ground. There are specific societies on the
fungi and in decaying logs, a society peculiar to the forest

222 A NATURALIST IN THE GREAT LAKES REGION

undergrowth of shrubs and herbaceous plants and a distinct
community of the forest crown.

The cicada or periodical locust (Fig. 299) sings its strident
drone in the tree tops, though most of its life, as a nymph, is
spent in the soil stratum of the forest. The katydid, Cyrtophil-
lus perspicillatus, lives its entire life from egg to adult in the
tree tops. The tree cricket (Fig. 300) is common, as also the
walking-stick. There are a number of butterfles and moths

FIG. 300. — Tree crickets of several species: a, male, b, female of Oecanthus
fasciatus; c, Basal joint of antennae of 0. fasciatus; d, 0. angustipennis; c,
0. quadripunctatus ; f, 0. latipennes; g, 0. nivens.

whose larvae feed upon the foliage. Among these are the tiger,
swallowtail (cherry), and the giant swallowtail (hop, tree) •, the
walnut sphinx, the lunar moth (hickory, walnut), the royal moth
(walnut), imperial moth (many trees), Polyphemus (many), Pro-
methea (cherry), yellow-gray underwing (hickory), the widow
(hickory), Cecropia (many).

Many beetles are peculiar to the forest crown such as the oak
twig pruner (Fig. 301), the hickory girdler, Oncideres cingulatus,
whose larvae develop in twigs that have fallen to the ground after
being girdled more or less completely by the adults up in the

THE CLIMAX FOREST AND ITS PREDECESSOR 223

trees. Several species of the June beetles are found feeding on
the leaves, as are many kinds of leaf beetles such as Tymnes
tricolor, T. matasternalis, Cha-
lepus nervosa, C. rubra (Fig.
302), Xanthonia xo-notata.
These are small beetles .25
inch or less in length. Most of
the leaf-eating beetles are
small. The elm-leaf beetle,
Galetucella luteola, is one of
the most familiar of the leaf
beetles attacking tree foliage.
Acorns and hickory nuts af-
ford homes and food for the
larvae of several species of nut
weevils belonging to the genus
Balaninus (Fig. 303) and later
to some moth larvae. These

tall tree tops afford good nest- YlG- 3°i.-Twig pruner of oak,

,, , , , , Elaphidion villosum. X3-

ing sites to the red-headed

woodpecker, the flicker, and the larger owls. The flying squirrel ,

which is largely nocturnal, spends its life in the trees.

In the undergrowth community the

spiders, Epeira gigas (Fig. 304) and Neoco-

soma arabesca (Fig. 305), are characteristic;

their webs are hung on the taller shrubs.

The jumping spider, Phidippus audax (Fig.

306), is prevalent in shrubs, on tree trunks,

FIG. 302 FIG. 303

FIGS. 302, 303: Fig. 302. — A leaf beetle, Chalepus rubra.
Fig. 303. — A nut borer, genus Balaninus. Both X6.

After Blatchley;

224 A NATURALIST IN THE GREAT LAKES REGION

and fallen logs. Harvest spiders or daddy longlegs are abun-
dant. Among butterflies the wood nymph and wood satyr are
conspicuous by their numbers. The forked-tail and round-
winged katydids are prevalent (Fig. 322).

The ground stratum is thickly populated. The most con-
spicuous denizen is perhaps the green tiger beetle, and Shelford
names the oak-hickory association, on its animal side, the green
tiger-beetle association. This brilliant tiger is only one of several
predatory ground beetles common on the forest floor. They
are about the same as found in the wood frog association. . The
commonest inhabitants of the leaf litter are the myriopods, of
which various species of "thousand legs" (millipedes) of the
genus Polydesmus and "hundred legs" (centipedes) of the genus
Lithobius are most prevalent. Thirty or forty to the square
yard may often be found when the leaf litter is carefully looked
over. They are an important factor in the transformation of
the dead leaves to leaf mold. Occasionally one finds the other
myriopods common in the wood frog association in the litter,
but they are more often under loose bark on old logs; they are
not as common as in the beech-maple forest. The same thing
may be said of the slugs and snails. The camel cricket (Fig. 307)
and the short-winged locust are fairly abundant. The nymphs
of cicadas are common, discovered on their way from the soil
stratum, where they live, to the trees where they emerge as
adults. In dry seasons the nymphs protect themselves from
excessive evaporation by building a closed clay chimney up
through the leaf mold, rising sometimes an inch or two above
the surface. In this they lie until they are ready to accomplish
their transformation on the nearby tree trunk.

There is a constantly changing association in the trunks of
the trees, beginning with the standing trunk still in its prime,
continuing through the dead standing timber, the fallen log, in
its various stages of decay. The rustic borer (Fig. 308) works
in the wood of the hickory, oak, and beech trunk even when
the tree is robust. The elm borer (Fig. 309) begins work on

THE CLIMAX FOREST AND ITS PREDECESSOR 225

FIGS. 304-312: Fig. 304. — Female of the spider, Epeira gigas; Fig. 305. —
Female of the spider, Neocosoma arabesca; Fig. 306. — The jumping spider, Phidip-
pus audax, Xs', Fig- 3°7- — Female of camel cricket, Ceuthophilus maculatus;
Fig. 308. — Rustic borer, Xylotrechus colonus; Fig. 309. — Elm borer, Saperda
tridentata, X2; Fig. 310 — Graphisurus fasciatus, X$; Fig. 311. — Calloides nobilis,
slightly enlarged; Fig. $-L2.—Molorchus bimaculatus.

226 A NATURALIST IN THE GREAT LAKES REGION

the trunk if the tree is at all weakened. An allied species,
Saperda lateralis, is also found on the hickory, and S. vestile is
very destructive. The larva of the goat moth also attacks lusty
trees and bores into their heartwood. It is good sized — some two
or more inches long when full grown. Such forms open the
trees ' defenses to a legion of other insect pests that are seldom
slow to follow up the advantage and that bore into the wood
or undermine the bark. Such are the flathead apple-tree borer
(Fig. 313). The adult beetle of the last-named species has been

known to emerge from wood
made into furniture several
years after the manufacture
of the article, the pupa hav-
ing lived during a long
period of imprisonment, so
it is claimed.

When the tree has suc-
cumbed and stands as a dead
or nearly dead tree, the oak
is attacked, in addition to
the foregoing, by such forms
as Graphisurus fasciatus (Fig. 310), Calloides nobilis (Fig. 311),
while the hickory supports even a larger beetle population,
common among which are Liophus alpha, Stenosphenius notatus,
Molorchus bimaculatus (Fig. 312). The decay of the log goes on
through many years, and the population changes as decomposi-
tion progresses. The trunk may still stand or it may be lying
on the ground when the bark loosens and the underlying sapwood
begins to rot. Under such conditions one finds a curious
assemblage of animals representative of many phyla. The slugs
already mentioned in the beech log are present, though not as
commonly as in the more mesophy tic wood frog association.
They are usually found near the base of the standing stump.
Snails are represented by Polygyra albolabris, P. thyroides, and
other species of Polygyra already listed in the beech-maple forest.

FIG. 313. — Flathead apple-tree boreri
Chrysobothris femorata; a, larva; b, adult;
c, face of larva; d, pupa. After Chittenden.

THE CLIMAX FOREST AND ITS PREDECESSOR 227

Pyramidula alternata is common as are also P. perspectives,
Omphalina fuliginosa, Zonitoides arboreus, and Circinaria concava.
Millipedes and centipedes are almost invariably present. The
carpenter ant is beginning to work, the female being found early
in the spring, starting the colonies in small hollows excavated
in the decaying wood. The paper wasp frequently winters
under such loose bark. Certain spiders, such as the wolf spider
and the grass spider,
winter in such locali-
ties and deposit their
egg sacks here.

When the bark
becomes quite loose
on standing timber,
the brown bat hangs
up under its protec-
tion by day. But
the .predatory and
wood-boring beetles
make up the bulk of
the population. The

FIG. 314. — Heartwood borer, Par andra brunca, and
a, its larva; b, side view of head end (Bulletin United
States Department of Entomology).

heartwood borer,
Parandra brunea
(Fig. 314), is fre-
quently present, working where decay is just beginning. This is
a shiny, chestnut brown beetle about .75 of an inch long and a
third as wide. The nearly cylindrical larva is i inch long, and is
recognized by the sharply sloping thorax and the 'small head.
Eupsalis minuta is quite common under bark of oaks, even in early
stages of decay (Fig. 315). The horned passalus, a good-sized
black beetle with a horn on the thorax, may be present, though it
is more common in the fallen logs when decay has progressed
somewhat more. Its very large white four-legged larva is not
likely to be mistaken for anything else (Fig. 294). Click beetles
are almost always present. Xylopinus saperdioides, Nytrobates

228 A NATURALIST IN THE GREAT LAKES REGION

Pennsylvania (Fig. 316), Tenebrio tenebrioides (Fig. 317), Uloma
impressa, Meracintha contracta are all beetles more than half an
inch long that are common in such situations. All belong to
the family of darkling beetles, and the list might be much
extended.

Then as decay becomes more complete other forms largely
replace those listed above, although some of these, as for instance
Passalus cornutus, remain even in well-decayed wood. The
rotten-log caterpillar, Scolesocampa, also is found from early to
late stages.

FIG. 315 FIG. 316 FIG. 317

FIGS. 315-317: Fig. 315 — Oak borer, Eupsalis minuta. After Felt; Fig. 316. —
Beetle, Nyctobates pennsyhanica; Fig. 317. — Beetle, Tenebrio lenebrioidcs. All X2.

The transition from the upland forest to the surrounding
prairie is accomplished through a characteristic forest margin
association. For the oak-hickory forest that is so commonly
the climax on the morainal hills in the immediate vicinity of
Chicago this consists of the wild crab often draped with the wild
grape, the trembling asp, the hawthorns, an occasional wild
plum, the smooth and staghorn sumacs, hazelnut, nannyberry,
and other viburnums, and not uncommonly some of the dog-
woods. The spring and summer herbaceous plants are not
materially different from those of the adjacent forest. The May
apple may make a goodly showing, the Canada and spear

THE CLIMAX FOREST AND ITS PREDECESSOR 229

thistles and ground-cherry may be particularly abundant, or the
milkweed toss its balls of blossoms in profusion, while in the
autumn goldenrods, wild sunflower, and asters seem to run
riot here.

The cottontail rabbit,
gray gopher (Fig. 319),
common shrew, jumping
mouse (Fig. 318), chip-
munk, and woodchuck
(Fig. 320) are the common-
est mammals of this forest
margin association. Birds FlG-. 3i8.-The jumping mouse, Zapus
are particularly abundant,

for the almost impenetrable growths of wild crab and hawthorn
make safe nesting sites, while the cover is good for ground birds.
Bob white, chewink, mourning dove, song sparrow, chipping
sparrow, goldfinch, indigo bunting, catbird, brown thrasher,
and shrike are all common in such haunts. Crabs and haws

FIG. 319. — Gray gopher, Citellus franklini ...*-«•' ,

are blossoming in the spring in mid-May, at which time
the warblers and vireos are passing over the Chicago region
in great waves of migration. They are then attracted to the
blossoming trees by the many insects that feed upon the
blossoms.

Insect life is at all times abundant in this marginal association.
The herbaceous plants of spring and midsummer mentioned
above each attract a goodly number of characteristic guests,

230 A NATURALIST IN THE GREAT LAKES REGION

especially the thistles and the milkweed. The larva of the
monarch butterfly is often found on the latter, and the red

FIG. 320. — Woodchuck, Marmota monax, and footprints

FIG. 321. — The painted
Pyrameis cardui.

lady,

beetle, Tetraopes tetraophthal-
mus, is almost always present.
Monarch, viceroy, anglewings,
fritillaries, wood nymphs, the
cosmopolitan (Pyrameis hun-
tera), and painted lady (P. car-
dui} (Fig. 321) are common
butterflies, the larvae of the two
last mentioned feeding on the
thistle. Hosts of flies, wasps,

and bees feed on the blossoms, especially in the autumn when
goldenrods and asters are the chief floral restaurants still open
to hungry insects. Several orthoptera are characteristic, among

THE CLIMAX FOREST AND ITS PREDECESSOR 231

FIG. 322. — Round-winged katydid,
Amblycorypha rotundifolia; b, tip of ovi-
positor. After Blatchley.

which may be mentioned the tree crickets, Oecanthus angustipen-
nis, O.fasciatus, and O. nivens (Fig. 300), and the round- winged
and oblong-winged katydids (Figs. 322, 323); the short-winged
locust, Melanoplus scudderi, the sprinkled locust, Chloealtis con-
spersa (Fig. 383), the sworded
grasshopper, Xiphidium ensi-
ferum, the woodland grass-
hopper, Xiphidium nemorale.

The tree crickets are gauzy-
winged, pale green insects,
whose stridulations make much
of the insect music of late-
summer nights. The oft-repeated buzzing notes, sounding in
unison, with regularity, give a rhythmic pulsing volume of
sound that keeps up from dusk to long past midnight. The short-
winged locust is nearly
an inch, long. The color
is reddish brown; the
hind tibiae are bright
red. The wing covers
are short, about as long
as the pronotum, the
wings still shorter.
Grasshoppers of the

FIG. 323. — Oblong-winged Katydid, Ambly-
corypha oblongifolia. After Blatchley.

genus Xiphidium are
small, but have a long
ovipositor. The top of the head projects forward as a rounded
prominence. The two species mentioned have bodies about
one-half inch long and are greenish brown in color. The
ovipositor of the sworded grasshopper is as long as the body;
that of the woodland grasshopper is shorter and curved.

CHAPTER XI
LAKE TO FOREST OR PRAIRIE

S WAS noted in discussing the inter-
dunal ponds the ultimate fate of pond
or lake is to be filled with the outwash
of soil from the surrounding hills and
the accumulations of vegetable debris.
Such a filling lake may give rise either
to (i) a forest, as shrubs and trees es-
tablish themselves in the firm soils of
its rising margin and push their way farther and farther out as
filling proceeds, or (2) to prairie. Indeed, these two associations,
the wet forest a/id the low prairie, may develop at different
parts of the same filling lake as is seen, for instance, at Wolf
Lake near Chicago.

Beginning with the open water and running shoreward, the
zones in the filling pond that lead to the forests might be named
as follows: (i) open water area, or from the animals predomi-
nating, the Pleurocera area; (2) zone of submerged plants or
the aquatic insect zone; (3) water lily zone or painted turtle
zone; (4) the rush zone — the marsh wren zone; (5) the cat- tail
zone — red-winged blackbird zone; (6) the shrub zone, the katy-
did zone; (7) the ash-elm zone, the green heron zone.

Out in the open water where the bottom is sandy, the water
shallow and largely free from invading plants, caddis-fly nymphs
are abundant, crawling over the bottom, as are also such snails
as Pleurocera and Goniobasis, while Vivipara contectoides is occa-
sionally found (Fig. 324). All three of these are operculate. In
Pleurocera the aperture is produced into a canal. P. elevatum
has nine to ten whorls, P. subulare twelve. Goniobasis livescens
is broadly conical and the aperture is rounded in front. Vivipara

232

LAKE TO FOREST OR PRAIRIE

233

FIG. 324. — Water snails showing generic characters: a, Lymnaea reflexa; b,
L.stagnalis; c, L.woodruffi; d, Physa heterostropha; f, Ancylus • fuscus, side view;
g, Amnicola cincinnatiensis ; i, A. emarginata; j, Valvata tricarinata; k, Planorbis
triwlms, from above; /, P. trivolvis, side view; m, P. campanulatus, from below;
n, P. campanulatus, side view; o, P. bicarinatus, from below; p, P. bicarinatus,
side view; q, Vivipera contectoides; r, operculum of V. contectoides; s, V. snbpur-
purea; t, Campeloma ponderosum; u, C. integrum; v, C. subsolidum; w, Pleurocera
elevatum; x,P.subulare; y, Goniobasis livescens; z, Sphaerium transfer sum (a clam).

234 A. NATURALIST IN THE GREAT LAKES REGION

contectoides is a large thin shell, banded or otherwise brightly
colored. Here too are such clams as Alasmodonta marginata
(Fig. 181) and Lampsilis luteola (Fig. 180). Some fairly good-
sized fish come into the shallow area to lay their eggs in the sand
of the bottom, such as the black bass, pumpkin seed (Fig. 188),
bluegill (Fig. 187), perch, crappie (Fig. 438). The fish may
often be seen, on careful approach, swimming in the neighbor-
hood of the nest, especially the male that does guard duty until
the young are hatched. In the very shallow water the blob or
miller's thumb, one of the sculpins (Fig. 325); the blunt-nosed
minnow (Fig. 429), straw-colored minnow (Fig. 436), and the

FIG. 325. — Blob, miller's thumb, or sculpin, Cottus ictalops. After Forbes

Johnny darter (Fig. 429) are found and probably breed here.
The crayfish, Cambarus virilis, is common, hiding under stones
and logs.

The waters of the lake are the habitat of many algae that
grow in profusion, Cladophora, Spirogyra, Oedigonium, Hydrodic-
ton, etc. They usually go under the common names of pond
scums or water silk. Nearer shore there is an abundant floating
vegetation consisting of such Hepaticae as Riccia, Ricciocarpus
and flowering plants like the duckweeds. Riccia appears like a
thick green leaf (really a thallus) about as large as your finger
nail. There are short rootlike structures (rhizoids) given off
from its under side. It floats on the shallow water or lies on the
soft mud. Duckweed is also a floating plant with one or two
tiny leaves and, for a short time in spring, a tiny blossom.

LAKE TO FOREST OR PRAIRIE

235

328

329

\

333

FIGS. 326-334: Fig. 326.— One of the pond weeds, Potamogeton natans;
Fig. 327. — A club rush, Scirpus atrovit us; Fig. 328. — S. Torreyi; Fig. 329. —
S.validus; Fig. 330. — A bog rush, Juncus ^altictis; Fig. 331. — J. tennis; Fig. 33 2. —
/. canadensis ; Fig. 333. — J. effusus; Fi^ . 334. — Spike rush, Eleocharis acicularis.

236 A NATURALIST IN THE GREAT LAKES REGION

It bears a few, short, threadlike roots. The surface of the pond
is often completely covered with this duckweed.

Many plants root in the soft bottom and grow more or less
submerged ; such are pondweed, Potamogeton of several species,
as P. natans, P. crispus, P. pectinatus, P. lucens, P. zosteri-
folius; water milfoil, Myriophyllum; hornwort, Ceratophyllum;
water weed, Elodea; tape grass, Vallisneria; bladderwort, Utri-
cularia; water buttercup, Ranunculus aquatilis (Fig. 64).

FIG. 335. — The bulrush zone, Galien River, New Buffalo, Michigan

Pondweed (Fig. 326) roots at the bottom of the pond and
sends up its leafy stalk to the surface. Some of the leaves may
lie on the surface of the water. Such are usually fairly firm
and broad, while the submerged leaves are commonly narrow,
translucent, and fragile. Potamogeton natans has egg-shaped
floating leaves i inch or more long and very narrow, submerged
ones less than .1 of an inch wide. P. crispus has only submerged
leaves which are lance-shaped and are borne on short stems.
The margins of the leaves are finely saw-toothed and crinkly.

LAKE TO FOREST OR PRAIRIE

237

P. pectinatus is entirely below water. Its leaves are long and
narrow and are provided at the base with stipules which unite
with the base of the leafstalk to ensheath the stem. Tape grass
or eel grass has long, ribbon-like, narrow leaves, entirely below
water or at times with the tips floating. The blossom is borne
on a string-like stalk that is coiled at first to hold the bud below
the surface and that uncoils and lets the blossom to the surface
only while it opens long enough to permit of fertilization.

338

FIGS. 336-338: Fig. 336. — Bur reed, Sparganium eurycarpum; Fig. 337. —
Arrowhead, Sagittaria latifolia; Fig. 338. — Wild rice, Zizania aqualica.

Then comes the water lily zone with water shield, Brassenia
purpurea; lotus, Nelumbo; yellow and white water lilies.

Shoreward still farther comes the bulrush zone (Fig. 335),
with Scirpus lacustris, S. validus, S. atrocinctus, S. americanus,
S. Torreyi, S. atrovirens (Fig. 327), and other species; rushes of
the genus Juncus like /. balticus littoralis; spike rushes like
Eleocharis acicularis, E. palustris, etc. The bulrushes have, as a
rule, long, tapering, solid round leaves sheathed at the base.
The inconspicuous perfect flowers are borne in spikelets that are
in some species solitary, in others clustered near the end of the
leaf. Torrey's rush (Fig. 328) and the American rush are the only
common ones in our neighborhood that have sharply triangular

238 A NATURALIST IN THE GREAT LAKES REGION

FIG. 339.— The reed

Phragmites communis.

stems. The scales of the flower cluster in the former are reddish
brown; in the latter, yellow brown. Scirpus validus (Fig. 329),
the great bulrush, may be 8 feet high and proportionally lusty.
The sheaths at the bases of the soft,
light green leaves are soft and rather
transparent. In Scirpus atrocinctus the
bases of the bracts that are below the
flower cluster are black.

In the bog rushes (Juncus) the flowers
and fruits are not inclosed in husklike
scales as they are in the bulrushes. The
leaves are pithy or in some species
hollow. The small flowers are clustered
but not in spikes. The flower cluster
appears to be on the side of the stem
rather than on the end in /. balticus
(Fig. 330). The plants appear in the
latter species in rows arising from the un-
derground stem. There are many other species such as J. tennis
(Fig. 331), /. canadensis (Fig. 332), /. e/usus (Fig. 333).

Every stalk of the spike rushes ends in a
spike of blossoms. The stalks are spongy
inside. Those of Eleocharis acicularis (Fig.
334) are not over 4 inches in height (unless
the plant is growing submerged) , and hairlike,
they are so fine. Eleocharis palustris is similar
but stouter. Its stalks are cylindrical; its
fruits, lenticular. The stalks of E. acicularis
are more or less four-angled, and the fruits are
triangular in cross-section.

Cat-tails come in next, the common, Typha FIG. 340.— Sweet
latifolia, and the narrow-leaved, T. angustifolia. flas> Acorus Calamus.
Then more or less mixed with the preceding plants come a num-
ber of marginal plants: bur reed (Fig. 336); arrowheads, Sagit-
taria -variabilis (Fig. 337), and S. heterophyla; pickerel weed; wild

LAKE TO FOREST OR PRAIRIE

239

rice (Fig. 338); water-reed, Phragmites communis (Fig. 339);
sweet flag (Fig. 340).

Along the margin of the open water soft-shell, musk and
geographic turtles are to be expected. The first is easily known
by its leathery rather
than bony shell; the
second, by its musky
odor; the third, by
the fine lines on each
bony plate of the
shell that give an
appearance some-
thing like a map.
Farther in shore in
the zone of submerged
plants, especially in
the bays, are many
adult and larval in-
sects that may be
dredged up with the
plants. The top min-
now, Fundulus dispar,
is common (Fig. 434).
Among the insects are
the water scorpion,
giant water bug,
water boatman, many

FIG. 341. — The painted turtle

diving beetles of the
families Dytiscidae
and Hydrophylidae, and May-fly nymphs. Dragon and damsel-
fly nymphs are common, and the molt skins of the latter are
commonly found on the rushes and cat-tails. A few of the
more frequent dragon flies are Anax junius, Gomphus spica-
tus, and Libullula pulchella. These insect larvae are already
familiar from the study of the interdunal ponds, as are also the

240 A NATURALIST IN THE GREAT LAKES REGION

FIG. 342.— The snapping turtle

snails, clams, and small crustaceans found abundantly here. In
the zone of submerged plants the shrimp Palaemonetes paludo-
sus (Fig. 56) is common, especially in the cooler waters. Here

also one finds the large
gelatinous masses in-
closing colonies of the
polyzoan Pectinella
magnified. .Here, too,
and in the zone of the
water lilies, the painted
turtle (Fig. 341) and
the snapper (Fig. 342)
are usually prevalent,
and such frogs as the
leopard, pickerel, green,
and bull.

The bullfrog is known by his immense eardrums, much
larger than his eyes (Fig. 343). The leopard frog is yellow
below; above he is mottled with black blotches on a yellow
ground. The pickerel frog (Fig. 344) is light brown, marked
above with three rows of
squarish blotches. The
green frog is pale green
above, marked with black
blotches and is also pale
green below.

The bulrushes afford
nesting sites for the marsh
wren, both long- and short- FIG. 343. — Common bullfrog, Rana cates-
billed, that attach their beiana, male. Bulletin United States Fish

globular nests to the rushes Commission-

(Fig. 345), the black tern, the pied-billed grebe that build
floating nests sometimes also in the cat-tail zone. In the cat-
tail zone will be found nesting the red- winged and yellow-headed
blackbirds, the American (Fig. 346) and least bitterns. The

LAKE TO FOREST OR PRAIRIE 241

first two attach their nests to the cat- tails which are fastened
together in a loose cluster for the purpose. In these two zones
one finds also Virginia, king, and sora rails, Florida gallinules,
coots, herons, and sandpipers. The muskrat builds his dome-
shaped house of the cat-tails, together with vegetable debris
raked up from the bottom.

Pushing out from shore into the rush and cat-tail zone is
the shrub zone. The buttonbush or elbowbush is the pioneer.
Back of it comes such shrubs as prickly ash, an aromatic plant
with odd pinnately compound leaves and prickers on the
stems; maple-leaved viburnum, red-osier and silky dogwoods;

FIG. 344. — The pickerel frog

and still farther back comes the white ash-elm forest association
with the ash the predominant tree. Neither the ash-elm forest
nor the shrub zone at its margin is marked by many strikingly
distinctive animals. The black-sided grasshopper, Xiphidium
nigropleura, is common on the shrubs and below them. The
striped shrub crickets, the Texan katydid (Fig. 348), the oblong-
winged katydid, and the forked-tail katydid (Fig. 347) are so
prevalent that the shrub zone may justly be called the katydid
zone. At times the larva of Papilio cresphontes is found freely
on the prickly ash, as in the summer of 1921, but usually the
giant swallowtail is rare about Chicago. When the shrubs are
in blossom many gnats and flies are hovering about them, and

242 A NATURALIST IN THE GREAT LAKES REGION

then the dragon flies that breed in the adjacent waters are busy
hunting, flying with quick, darting movements along the open
pathways.

The ash-elm swamp forest is inhabited by many animals, few
of which are, however, peculiar to it. Most of them are equally
or even more prevalent in the elm-maple forest of the flood plain.

The green heron often
nests in the ash trees
along the swamp mar-
gin and may be taken
as the typical animal
of this zone.

Not always does
the filling of a low area
in the Chicago region
ultimately lead to a
forest area. There is
another association of
plant and animal
forms that seems to
be the end result
of such a process,
namely, the prairie as-
sociation. Extensive
prairie areas have de-
veloped from the
marshes that formerly
occupied, and in part
still occupy, the beds of the old lakes that formed back of the
terminal moraines, such as the Morris Basin and the Kankakee
Basin. They have developed also on extensive areas of sand
that outwashed from the glacier and on upland regions in the
moraines. Possibly the prairie finally transforms to forest,
but if so the prairie stage in the development is a protracted
one. It is difficult to decide just what it is that determines

FIG. 345. — Nest of marsh wren, woven of marsh
grass.

LAKE TO FOREST OR PRAIRIE

243

that one lake as it fills shall first give rise to marsh, then to
swampy forest, later to the succession of oak and hickory forest,
and finally to the climax
forest, while another,
after the marsh condi-
tion, proceeds through
wet meadow to prairie.
Possibly differences in
depth of the original
lake undergoing filling
and consequent differ-
ences in the depth of
humus, differences in
drainage, in soil char-
acter, as well as other
factors, enter into the
production of unlike
end results.

Once the differences
between prairie and
forest are established,
it is easy to see enough

FIG. 346, — American bittern, Botaurus lenti-
ginosus.

contrasts in atmospheric and soil temperatures, in water content

of the soil, in relative percentage or saturation of the atmos-
phere, to account in part, perhaps
entirely, for the very different
plants and animals in the two
regions. The temperatures in the
soil and among the vegetation of
the forest are not subject to such
extremes, either seasonal or di-
urnal, as on the prairie. The
temperature in the forest and in

its soil is lower in summer and at midday than on the prairie.

The cool air protected in summer by the forest trees is a much

FIGS. 347, 348: Fig. 347 (top).—
Forked-tail katydid, Scudderia
furcata; Fig. 348 (bottom) —Texas
katydid, 5. texensis.

NATURALIST IN THE GREAT LAKES REGION

956 * 357

FIGS. 349-357: Fig. 349. — Carex conjuncta; Fig. 350. — C. cristala; Fig. 351. —
C. lupuliformis; Fig. 352. — C. stricta; Fig. 353. — Slough grass, Spartina Michanx-
iana; Fig. 354. — Blue-joint grass, Calamagrostis canadensis; Fig. 355. — Fow
meadow grass, Glyceria nenata; Fig. 356. — Switch grass, Panicum virgatum;
Fig. 357. — Thin grass, Agrostis perennans.

LAKE TO FOREST OR PRAIRIE

245

deeper layer in the forest than in the corresponding layer in the
relatively short vegetation of the prairie. The forest atmosphere
is more humid than that of the prairie.
Evaporation is relatively greater on the
prairie.

Most of the original prairie has passed
under cultivation, and the prairie flora and
fauna have largely been obliterated. Scat-
tered remnants of it persist, a few plants
and the associated animals surviving in
this locality, a few others elsewhere. But
in few if any localities is the old wealth of
prairie forms to be encountered in any-
thing like its early luxuriance. Probably
along the rights of way of the railroads the FlG 358._Andropogon
prairie forms are found more abundantly furcatus.

FIG. 359. — Luxuriant grasses of wet prairie

246 A NATURALIST IN THE GREAT LAKES REGION

than anywhere else. There are stretches where the traveler
catches glimpses of the carpet of brilliant and varied blossoms
that once spread far and wide and of the teeming animal life
that accompanied the prairie plants. It well repays the effort
to trace the evolution of the prairie and to become acquainted
with the typical plants and animals of this prairie association

in as favorable localities as
are at present available.

Shoreward from the rush
zone in those lakes or por-
tions of lakes that are devel-
oping into prairie there comes
a broad zone occupied by
sedges and grasses. The cat-
tail zone* is omitted. This
sedge zone is more or less
completely inundated in the
high-water stages of early
spring, but in the summer
may be reasonably dry. Here
such sedges as Carex aquati-
lis, C. conjuncta (Fig. 349),
C. cristata (Fig. 350), C, lupu-
liformis (Fig. 351), C. riparia,
and C. stricta (Fig. 352),
FIG. 360 — Smartweed, Polygonum together with some of the

lapathifoliu

rushes of the preceding zone,

are found. The Carexes are grass-like plants usually with
triangular stems. There are very many species, a few of
which may be recognized by the figures. Gray's Botany will
be needed to determine the many others. Such grasses as
the following are distinctive. They are named in the order
of their appearance from the outer edge of the zone shore-
ward: slough grass (Fig. 353), blue-joint grass (Fig. 354),
fowl meadow grass (Fig. 355), switch grass (Fig. 356), thin

LAKE TO FOREST OR PRAIRIE

247

grass (Fig. 357), Poa triflora, etc. Sampson thinks the first five
are the typical and most characteristic ones in the succession
that leads to the occupation of the prairie by the Andropogon
furcatus (Fig. 358),
which marks the climax.
In summer these swamp
grasses may be luxuri-
ant enough to pay for
cutting to secure the
coarse marsh hay (Fig.
359).

Among the grasses
and sedges occur many
other plants, not in
masses so as to give
character to a whole
zone as do the grasses
and sedges, but still
frequently. The fern,
Aspidium cristatum, is a
common one in such
marshlands. Equisetum

FIG. 361. — Chick weed, Cerastium vulgatum

362

FIGS. 362-364: Fig. 362. — Three species of Cardamine: C. Douglassii at left;
leaf of C. bulbosa, above at right; C. Pennsylvania, right below; Fig. 363. — Mer-
maid weed, Proserpinaca palustris; Fig. 364. — Skull cap, Scutellaria galerictdala.

248 A NATURALIST IN THE GREAT LAKES REGION

fluviatilb is prevalent.
Other forms are smart-
weeds, Polygonum lapath-
ifolium (Fig. 360) and
P. persicaria, chickweed
(Fig. 361), bitter cress (Fig.
362), Viola blanda, mermaid
weed (Fig. 363), skull cap
(Fig. 364), cardinal flower
(Fig. 365).

The grass an4-sedge
formation described above
may give place-to the
prairie, at first to :the wet
prairie and finally to the
typical upland prairie. Both
of these areas manifest
marked seasonal changes as
indeed do most areas. One
set of plants comes on to
maturity, blossoms, fruits,
and gives way to a later set,
which in turn becomes in-
conspicuous as some other
assumes for the time being
the conspicuous role. Thus
Viola blanda and V. peda-
tifida blossom early on
the prairie, shooting star
(Fig. 366) comes then, wild
hyacinth (Fig. 367) by June,
then wild onions (Fig. 368),
Culver's root (Fig. 369) and

,. ,. golden old man (Fig. 370)
FIG. 365.— Cardinal flower, Lobelia cardi- 6

fa. follow. Brown-eyed Susans

LAKE TO FOREST OR PRAIRIE

249

(Fig. 371) are pre-empting attention by July, as are also the cone-
flowers (Fig. 372); the purple ones are notably brilliant. Then
in late summer come blazing
stars (Fig. 133), rosin weed
(Fig. 373), asters, goldenrods,
and beggar-ticks, whose fruits
you carry away as souvenirs
nolens wlens. The above-
mentioned plants, because
they are conspicuous when in
blossom, give a constantly
changing character to the
prairie, yet, after all, the
dominant things are the
prairie grasses such as blue-

FIG. 366. — Shooting star, Dodeca-
theon meadia.

stem, Andropogon furcatus,
and dropseed, Sporobolus
cryptandrus (Fig. 374), that
by their very abundance and
uniformity fail to strike
attention.

As the prairie with domi-
nating clay soil becomes
pretty dry such plants as the
rose pink prairie phlox (Fig.
375), prickly lettuce (Fig. 62),
butterfly weed, prairie thistle,
everlasting, rattlesnake master
(Fig. 376) become more

FIG. 367. — Wild hyacinth, Camassia
esculenta.

250 A NATURALIST IN THE GREAT LAKES REGION

conspicuous, replacing in part the above-mentioned forms.
On thin-soiled prairie, or prairie with sandy soil, the pink and

FIG. 368. — Wild onion in blossom, Allium cernuum

white prairie clover, Petalo sternum (Fig. 377), and lead plant

(Fig. 378) are apt to predominate, while such typical plants of

the clay-soil prairie

as Silphium terebin-

thinaceum, S.lacinia-

tum, and Eryngium

yuccifolium are

rare.

Naturally in any
region with as dis-
tinctive a group of
plants as exists in
the prairie there will

. . FIG. 369 FIG. 370

FIGS. 369, 370: Fig. 369.-Culver's root, Veronica
Assemblage of mrginica; Fig. 370. — Golden old man, Zizia aurea.

LAKE TO FOREST OR PRAIRIE

animals. Indeed, the transition, as one goes from the oak-
hickory or the maple-beech forest to the adjoining prairie.

Fig. 371. — Brown-eyed Susans, Rudbeckia hirta

is so abrupt, the new animals and plants
so strikingly dissimilar to those of. the
forest, that even the casual observer must
be struck by the change. The contrast is
even enhanced by going through the
border of wild shrubs, hawthorn, trembling
asps, and sumacs, so characteristic at the
edge of the oak-hickory association with
the distinctive animal and plant life that
belongs to such a border.

FIG 172 — Coneflower ^ne °^ ^ne most characteristic features
Brauneria purpurea. of the wet prairie or even of the upland

252 A NATURALIST IN THE GREAT LAKES REGION

prairie, if its subsoil is clay, is
the abundance of chimneys of
the burrowing crayfish, Cam-
barus gracilis (green) (Fig. 379)
and C. diogenes (red). These
animals dig wells to insure
moist retreats in the dry sum-
mertime and safe ones at all
times. The excavated mate-
rial is often piled as a chim-
ney about the hole. The
crayfish lives near the top of
the burrow but drops back
when frightened. He wanders
out from his castle turret to
seek food, hunting largely at
dusk. Earthworms are com-
mon in the rich prairie soils,
particularly the big night

crawler. Larvae of the Tune
FIG. 373-— Rosinweed, Silphium . j x • j.i.

terebinthinaceum. beetle ar« abundant in the

subterranean layer of the
upland prairie. The ant,
Formosa subpolitavar neo-
gagates, builds large hills,
burrowing into the ground
beneath them. The star-
nosed mole, similar to the
common mole, but easily
recognized by its large
front feet with heavy claws
and the fringed disk on its
nose, burrows beneath the FIG. 3?4 FIG. 37s

sod for worms and larvae. c ^5.374,375: Fig. 374.-Dn>pseed [grass,

Sporobolus cryptandrus; Fig. 375.— Prairie

The familiar striped gopher phlox, Phlox pttosa.

LAKE TO FOREST OR PRAIRIE

253

(Fig. 380), ground squirrel, or thirteen-lined spermophile, and
Franklin's spermophile or gray gopher (Fig. 319), dig their
retreats here and scurry to them from their foraging trips.
The pocket gopher (Fig. 381) is also a resident of the high

FIG. 376. — Rattlesnake master, Eryngium yuccifolium

prairie. The bulging cheek pockets stored with food character-
ize this little rodent.

The field mouse, Microtus ochrogaster, builds its nest of grass,
sometimes hiding it under a log in the adjacent forest. It lives
by hunting for provender among the grasses. It is similar to
the Pennsylvania meadow mouse (Fig. 382) but has a gray-
brown back, while the Pennsylvania meadow mouse has a
dark brown back. The prairie deer mouse, 5.25 inches long,

254

NATURALIST IN THE GREAT LAKES REGION

gray-brown above, white below, with gray feet and white
toes, is fairly common. It is quite like the white-footed deer

mouse (Fig. 287) but
this has pure white
feet. The Pennsyl-
vania meadow mouse
is more prevalent in
the wet prairie.
Certain birds nest on
the ground of the
open prairie; the
most characteristic
are the bobolink, the
meadow lark, its nest

at the end °f a

FIG. 377 FIG. 378

FIGS. 377, 378: Fig. 377.-Prairie clover, Peta-
lostemum purpureum; Fig. 378.— Lead plant, Amor- tunnel, the dickcissel,
pha canesccns. the vesper sparrow,

the grasshopper sparrow, the prairie horned lark, the lark
bunting, and the prairie chicken. The first three mentioned

FIG. 379.— Chimney of burrowing crayfish, Cambarus diogencs

LAKE TO FOREST OR PRAIRIE

255

are found most often in the wet prairie; the others belong to
the dry prairie association. Prairie horned lark and lark bunt-
ing are not very common residents of the Chicago region.

The common toad is preva-
lent, as would be expected, in
a region where insects are so
common. The green snake,
Leiopellis vernalis, green above,
greenish white below, is the
characteristic snake, especially
in the moist prairie, while the
prairie garter snake is more
common on the dry prairie,
though becoming rare.

The short wing and the
long-winged grouse locusts, Tettigidea parvipennis, T. pennata,
live on the ground of the wet prairie. They are small, obscure
because of their ground color, and appear in the spring. Later

FIG. 380.— Striped gopher, Citellus

FIG. 381. — Pocket gopher, Geomys bursarius

these small forms give place to the more familiar locusts and
grasshoppers of the summertime. The characteristic ones of
the wet prairie are Xiphidium fasciatum, the red-legged locust
(Fig. 383), the two-lined locust (Fig. 383), and the short- winged

256 A NATURALIST IN THE GREAT LAKES REGION

locust (Fig. 383). Those of the dry prairie are the field grass-
hopper, the glade grasshopper, the straight-lance and the
meadow grasshopper (Fig. 383).

FIG. 382. — Pennsylvania meadow mouse, Microtus pennsylvanicus, and foot-
prints.

FIG. 383. — Different species of grasshoppers: a, the two-lined locust, Melano-
plus bivittatus; b, the red-legged locust, M. femur-rubntm; c, the short-winged
meadow grasshopper, Xiphidium brevipenne; d, the common meadow grasshopper,
Orchelmium vulgare; e, the sprinkled grasshopper, Chlocaltis conspersa; /, the
green-legged locust, Melanoplus viridipes.

Many larvae are found feeding on the grasses and associated
plants, particularly on the low prairie where such plants remain

FIGS. 384-387: Fig. 384. — Grass sawfly (a), larvae on grass; (Z>), larva
enlarged; (c), adult female. After Marlatt; Fig. 385. — Dingy cutworm (b) and
moth (a), Feltia subgothica. After Felt; Fig. 386. — Salt-marsh caterpillar and moth,
Esligmena acraca. After Forbes; Fig. 387. — The "yellow bear" (a) and moth (b),
Diacrisia virginica. After Forbes.

258 A NATURALIST IN THE GREAT LAKES REGION

succulent for a long time. Sawfly larvae (Fig. 384) appear late
in the spring. Moth and butterfly larvae are common, as are
also the adults. The cutworm moth (Fig. 385) flies out of the
short grass in the early spring and remains abundant all
summer. Its larvae feed on the wild strawberry plant. The
salt-marsh caterpillar (Fig. 386) and the " ghost moth" that

FIG. 388. — The Isabella tiger moth, Isia Isabella, and its larva, the "woolly
bear" caterpillar, from Cornell Nature Leaflet.

comes from it, the "yellow bear" (Fig. 387), and the hedge-
hog caterpillars and their moths, including the Isabella moth
the caterpillar of which is known as the "woolly bear'
(Fig. 388), are common in all seasons, the caterpillars espe-
cially so in the fall.

Then every plant of the prairie has its associated animals,
so a succession of animal forms appears as the spring plants
give place to the summer ones and these in turn to the autumn
types.

CHAPTER XII

LAKE BLUFF, RAVINE, AND RIVER VALLEY

RAIRIE and climax forest, once estab-
lished, are not assured of permanency.
Indeed, the forces that operate to des-
troy them are often at work contem-
poraneously with those that complete
their formation.

Along the lake shore wave action is
in many places undercutting the bluffs
so that adjacent forest or prairie is sliced off gradually to
disappear in the insatiable maw of the lake. The plant
and animal life of this unstable bluff side is quite different
from that of the prairie or forest it replaces. Again, a runnel
starts in the spring freshets, courses through the prairie or
the forest, excavating a slight depression. Year after year this
deepens and widens so that the prairie or woodland is invaded
by a growing ravine that produces extensive changes in the flora
and fauna. In time the ravine widens to a miniature river
valley. It is interesting to trace these changes produced as
bluff and ravine and river valley develop.

The annual winter storms cut away the underpinning of such
bluffs, the upper portions slide down, carrying trees and shrubs
from the higher level to destruction in the wave-washed base
(Fig. i). Naturally, few plants and animals can maintain exist-
ence in such an unstable environment. The surface of such a
bluff is often largely free from vegetation or scantily covered at
best with such forms as can maintain a temporary footing on the
insecure soil.

Moreover, such nearly naked bluffs have a high rate of
evaporation. The upper portions especially are dry because the

259

260 A NATURALIST IN THE GREAT LAKES REGION

soil water drains out so readily. They are exposed, too, to the
cold winds from the lake. It is to be expected, therefore, that
the plants, especially of the crest, will be xerophytic and hardy
(Fig. 389). White pines, jack pines, cotton wood, large- and
small-toothed aspens, red cedar, white birch, spreading juniper,
leatherleaf, red-osier dogwood, glaucous willow, and staghorn
sumac are the characteristic shrubs and trees on those bluffs
that are somewhat stabilized. Sweet clover and many other
common weeds that can stand severe exposure are found, such

FIG. 389.— Lake shore bluff with xerophytic vegetation

as mullein, Canada thistle, dock, Russian thistle, the horsetails,
Equisetum hyemale (Fig. 390), and E. arvensis.

The animal life is scant but is as distinctive as the plant. As
in the Dunes we found a tiger beetle, characteristic of nearly
every zone, so here we find Cicindela purpurea limbalis (Fig. 145)
confined to this particular habitat, chiefly on the wet clay bluffs.
The holes of the larvae are common on bare spots, and the
adults are abundant in midsummer, hunting over the sparse
vegetation for insect prey, particularly the sweet clover. The
clay-bank spider, a large black one, Pardosa lapidicina (Fig. 391),

LAKE BLUFF, RAVINE, AND RIVER VALLEY

261

FIG. 390. — Common
scouring rush, Equi-
setum hyemale,

shares this hunting ground. Some clay-bank wasps hunt here,
and the Carolina locust is common. Wherever the cliff is stable
enough to develop shrubs and tree thickets the plants
and animals of the mesophytic forest margins appear
(see p. 230).

The ravine in clay soil attains at its mouth much
the same appearance as does the lake shore clay bluff
(Fig. 392), and the animals and plants found are similar.
It is evident, however, that the ravine will vary in
character according to the sort of material in which it
is forming. In loose and friable soil it will develop
rapidly, its sides will wear by erosive action
with celerity, and it will in a relatively short
time be broad in comparison with its depth,
so its sides will have gradual slopes. In
clay soil, however, the stream cuts into the
more resistant material more rapidly than
the less vigorous agents of erosion, atmospheric disintegration,
rain, and wind affect the sides. The ravine, therefore, will be
deep in comparison with its width
and will have steep slopes (Fig. 6).
In rock only the stream is powerful
enough to erode rapidly. The sides
wear away very slowly, so the rock
ravine has very steep, often verti-
cal, sides. Ravines of the first type,
hardly ravines at all, but miniature
valleys, are wide open to the sun,
so that light, heat, and the rate of
evaporation is much as it is else-
where in the vicinity. The slopes
are dry, however, since water runs
off them well and seeps out into the
lower stream bed. But in ravines in clay soil the sun has
access only at certain times of the day; they are, therefore, cool

FIG. 391. — Clay-bank spider, Par-
dosa lapidicina. After Shelford.

262 A NATURALIST IN THE GREAT LAKES REGION

and moist. Evaporation goes on very slowly. These same
conditions prevail even in a more emphatic manner in the
rock ravine. In the latter type especially, springs emanating
through rock cracks and crevices often keep the sides drip-
ping wet.

The ravine is naturally most completely developed at or
near its mouth, for it was at this end that it began cutting back
into the highland. At its head it is still a young ravine, pushing

FIG. 392. — Mouth of ravine at the lake shore

back gradually into the prairie or forest. As one follows down
the ravine older and older stages are encountered. At first it
is a mere gully with a tiny trickle in it, except during spring
freshets. Then it deepens and widens into a young V-shaped
ravine with a growing stream as tributary gullies add their
contributions. In clay and rock the sides are very steep — so
steep that the rock or clay slides down in landslides into the
bottom, often producing bare areas so unstable that plants can-
not get a foothold. Still farther down the growing brook begins
to cut into one side, then the other, as it assumes a tortuous
course due to varying obstructions. So the stream meanders

LAKE BLUFF, RAVINE, AND RIVER VALLEY

263

back and forth, depositing in some spots what it wears away in
others. The bottom of the ravine widens into a miniature flood
plain. The sides become less steep. Possibly in the lower
reaches the stream has cut down nearly to the level of the lake or
larger stream into which it flows and so runs sluggishly. It is
no longer a brawling brook, but a placid little creek. The
ravine has broadened into a miniature valley. All these stages

FIG. 393. — Rock ravine with vegetation on the sides, near the "Sag"

are admirably seen along the north shore of the lake where the
clay bluffs abut upon the shore (Figs. 5 and 6).

Since it is only the stream that is capable of rapid erosion in
rock, the rock ravine is prone to end at its upper end in a water
fall (Fig. 9). This fall gradually retreats as the stream eats its
way through the rock. In relatively soft rock the fall is likely
to be quite a high one, and the ravine ends abruptly. If the
rock is hard, a series of rapids may replace the fall, and the
ravine gradually becomes more and more shallow to its head.

264 A NATURALIST IN THE GREAT LAKES REGION

FIG. 394. — Sarsaparilla,
Aralia nudicaulis.

It is evident that the edges of the ravine slope must be dry
areas, for the soil moisture will readily drain out into the ravine.
The deeper the ravine, the farther back from its edge the dry
area will run. As you approach the rock
ravine through the forest in the Starved
Rock region there is a marked change
in the vegetation, the mesophytic forms
giving way to xerophytic sorts. Black
oaks replace the red and white. Such
shrubs as panicled dogwood, sumac,
chokecherry, and ninebark, are charac-
teristic. Patches of hairycap moss and
horsetails, indicative of xerophytic con-
ditions, appear along the edges of the
ravine openings. Junipers are growing
and such deciduous shrubs as the blue-
berry and huckleberry. These and such flowering plants as the
false lily-of-the-valley and bastard toadflax found growing here
are characteristic of the pine region in
the Dunes.

The sides of the ravines support an
abundant vegetation if they are sloping
and have some soil. Cinnamon and
interrupted ferns may grow on the banks.
Where the sides are steeper still and
rocky, red cedar, balsam, ninebark,
gooseberry, and other plants gain pre-
carious footings (Fig. 393); columbine,
bluebells, Prenanthes, sarsaparilla (Fig.
394), shooting star occasionally, and such FlG- 39S-— Fragile fern,
ferns as the fragile fern (Fig. 395) and Cystopterisfragilis.
bladder ferns (Fig. 396) are to be found growing in the cracks
and crevices. In all of the ravines it is noticeable that vegeta-
tion is much more abundant on the shady side than on the side
exposed to the sun. Farther down in 'the bottom of the ravine

LAKE BLUFF, RAVINE, AND RIVER VALLEY

265

the walls are found plastered with liverworts, Conocephalus
being the prevalent one — Marchantia (Fig. 397) less common.
Mosses are abundant. The purple-
stemmed cliff brake (Pellaea atropurpurea),
recognized readily by the location and
its slender purple stem, is noticeable.
Selaginella grows in beautiful masses
(Fig. 398); wild hydrangea is present as
an interesting shrub in the ravine bottom
(Fig. 399) ; touch-me-not, early saxifrage,
river horsetail, and other plants demand-
ing much shade and moisture, are preva-
lent in the bottoms of the ravines. Bank

Swallows and occasionally rough- winged right, under side of frond;
Swallows nest On shelves of the rocks, upper center, one sorus.

The mourning dove, the wood peewee and ruby-throated hum-
mingbird build on the overhanging shrubs. Snails crawl about

397

FIGS. 397-398: Fig. 397. — A liverwort, Marchantia polymorpha, bearing
archegonial branches. Upper right, portion of thallus with gemmae cups. After
Atkinson; Fig. 398. — Selaginella. After Andrews.

266 A NATURALIST IN THE GREAT LAKES REGION

FIGS. 399-407: Fig. 399. — Meadow rue, Thalictrum dasycarpum; Fig. 400.—
Boneset, Eupatorium perfoliatum; Fig. 401. — Queen Anne's lace, Daucus carota;
Fig. 402. — Wild parsnip, Pastinaca saliva; Fig. 403. — Angelica, Angelica atro-
purpurea; Fig. 404. — Alumroot, Heuchera amcricana; Fig. 405. — Whitlow grass,
Draba caroliniana; Fig. 406. — Rattlebox, Crotalaria sagittalis; Fig. 407. — Walking
fern, Camptosorus rhizophyllus.

LAKE BLUFF, RAVINE, AND RIVER VALLEY

267

the moist sides of the ravines. Polygyra clausa and P. thyroides
are the most common in the ravines.

The clay ravine presents a slope on which the most char-
acteristic trees are the water beech and hop hornbeam, while

FIG. 408. — Wild hydrangea, Hydrangea arborescens, in French Canyon,
Starved Rock.

witch-hazel is likely to be the dominant shrub. Hepatica,
bloodroot, meadow rue (Fig. 399), wood betony, Prenanthes,
and maidenhair ferns are likely to be common on the lower por-
tions of the slopes. More xerophytic forms, such, as wild sar-
saparilla and false Solomon 's seal, are found on the upper slopes,
while on the bottom, especially if a flood plain is developing,

268 A NATURALIST IN THE GREAT LAKES REGION

basswood, the elms, ash, soft maple, elderberry, maple-leaf vibur-
num, boneset (Fig. 400), Queen Anne's lace (Fig. 401), wild

FIG. 409. — Rock polypody, Poly podium vulgar e, on cliff at Starved Rock

parsnip (Fig. 402), and Angelica (Fig. 403) are likely to be
present.

Among the birds Phoebe, wood peewee, chewink, bob white,
and whippoorwill are perhaps the commonest forms. The lance-
head dragon fly, whose nymph is found in the pools of the stream,

LAKE BLUFF, RAVINE, AND RIVER VALLEY 269

is very conspicuous. It is a large dragon fly with lance-shaped
yellow spots along the back of the abdomen, and two con-
spicuous yellow bars on each side of the thorax. Snails are
fairly abundant also in the lower portion of
the clay ravine; the white-lipped snail,
Polygyra thyroides, Pyramidula alterndta,
Pyramidula solitaria, and Circinaria concava
are the most common ones. • The green tiger
beetle so characteristic of the climax forest
is also abundant here.

The broad, open ravine, which develops as
erosion proceeds and the sides of the steep FlG 4IO_Toad
clay ravine wear away, is so like the margin bug, Gelastocoris
of the customary river valley that no special oculatus-
mention need be made of it; the description below will fit it
fairly well.

The valley of the river that is cutting through rock as is the
Illinois at Starved Rock, the Rock River at Oregon and Grand
Detour, the Wisconsin in the neighborhood
of the Dalles, is bordered by steep rock bluffs.
The vegetation and animal life on these differ
quite decidedly from that of the steep sides
of the ravines, for the river valley is wide
open to the sun's rays. Such rocky river
bluffs are dry and hot. The top of the bluff
(Fig. 7) has a tree and shrub population
much like that of the crest of the ravine,
FIG "41 /—Hooded namely> white pine, red cedar, white cedar,
grouse locust, Para- June berry, spreading jumper, blueberry,
tettixciicullatus. After huckleberry, ninebark, red elderberry, etc.
In the rock crevices near the top of the bluff
the rock polypody fern is common (Fig. 409). The sides of such
bluffs support columbine, bluebell, alumroot (Fig. 404), whitlow
grass (Fig. 405), rattlebox (Fig. 406), sarsaparilla, spiderwort,
Prenanthes, and occasionally walking fern (Fig. 407).

270 A NATURALIST IN THE GREAT LAKES REGION

The steep soil slopes that lie at the base of the rocky cliffs
bear a forest of black, red, and white oaks, with chokecherry,hop
tree, water beech, hop hornbeam — forms which are characteristic

of such slopes. Witch-
hazel is the predominant
shrub. The ground is
covered with large areas of
the cinnamon fern and,
lower down, the inter-
rupted fern.

There is an abundant
bird population in these
wooded slopes. Wood
thrush, hermit thrush, Wil-
son's thrush, the ovenbird,
indigo bunting, cardinal,

FIG. 412. — The spotted sandpiper.
Forbush.

After

black-billed cuckoo, crested
flycatcher, and Baltimore

oriole are among the commonest inhabitants. Chickadees nest

in the old woodpecker holes.

On these moist slopes snails are particularly abundant.

Practically all the Polygyras of the Chicago area are found here.

P. dlbolabris and clausa, fra-

terna, fraudulenta, hirsuta,

inftecta, monodon, multilineata,

oppressa, palliata, pennsylvanica,

thyroides, Pyramidula alternata,

solitaria, perspectives; Omphalina

fuliginosa, friabilis; Circinaria T FlG' 4i 3 -Long-bodied spider,

1 etragnatlia laborwsa.

concava; Zonitoides arboreus —

these are all present. In the early morning after a shower or
after a heavy dew the ground and the low vegetation is fairly
alive with tHese numerous species. They are common in the
river bottom also, and are found crawling on the paths and
roadways (Figs. 284, 285).

LAKE BLUFF, RAVINE, AND RIVER VALLEY 271

The river bottom or the
flood plain association is a very
constant one. It is bordered
by a succession of zones on its
river side. First there is a
zone of bare sand or gravel
which is so often inundated
that no plants — unless it be
an occasional hardy annual
weed — grow upon it. Here
the toad bug (Fig. 410) is often
found, the hooded grouse
locust (Fig. 411), some of the
same predatory ground beetles
found along the lake shore,
and the spotted (Fig. 412) and
solitary sandpipers. All these
feed on small animals washed
ashore by the current. This
zone, without plant life, may be
designated, on its animal side,
the spotted sandpiper zone.

Next comes a zone of low
rich soil, inundated in the
spring but which later dries
out enough so it is populated
by such weeds as ragweed and
wild sunflower. The granu-
lated grouse locust (Fig. 216)
is found here .early. Later
the meadow grasshopper,
Xiphidium brevipenne, ap-
pears. The long-bodied
spider, Tetragnatha laboriosa
(Fig. 413), finds this a

FIG. 414.— Kentucky coffee tree

272 A NATURALIST IN THE GREAT LAKES REGION

favorable hunting ground. Succinea avara and S. retusa are
found crawling over the wet ground or on the plants. These
snails are very widely distributed in wet and marshy situations.
This zone may be called the giant ragweed zone from the plant
standpoint, and the Succinea zone on its animal side.

Then comes a zone of willows, chiefly Salix nigra and S. longi-
folia. The trees nearest the stream are usually small ones, the

FIG. 415. — Flood plain of river with vines draped on trees

larger ones standing farther back. With these larger willows
are the young white ash, elms, and soft maples that characterize
the beginning of the flood plain forest proper. When these willows
are in blossom in the spring there are present many flies, bees,
and pollen-loving beetles like the bumble beetle. Later the
conspicuous animal life is the large number of moth and butterfly
larvae that feed on the willow. Mourning cloak and viceroy
larvae are often found in swarms, while the larvae of Cecropia
are usually abundant and conspicuous on account of their large
size during the fall. Those of the Sweetheart and Bride are less

FIGS. 416-424: Fig. 416. — Bladdernut, Staphylea trifolia; Fig. 417. — 4 prickly
ash, Zanthoxylum americanum; Fig. 418. — Moonseed, Mcnispermum canadense;
Fig. 419. — Smilax, Smilax hispida; Fig. 420. — Skunk cabbage, Symplocarpus
foetidus; Fig. 421. — Cheveril, Chaerophyllum procumbens; Fig. 422.— Fringed loose-
strife, Steironema ciliatum; Fig. 423. — Honewort, Cryptotaenia canadensis; Fig.
424. — Cow parsnip, Hieracleum lanatum.

274 A NATURALIST IN THE GREAT LAKES REGION

conspicuous. This zone is very evidently the willow zone on its
plant side and may be designated the cecropia larva zone on its
animal side.

Farther back from the stream is the flood-plain forest proper.
Red and white elms, white and black and blue ash, basswood,
soft maple, hackberry, black cherry, black walnut, sycamore, and
black willow are the common trees, with white elm, white ash, and
soft maple dominant members of the association. In addition,
the Kentucky coffee tree, Gymnocladus dioica (Fig. 414), is com-
mon a little farther south, and when one gets away from the lake
in the Chicago area, the tulip tree, pawpaw, flowering dogwood,
and redbud are often found in the river-bottom association.

FIG. 425. — Short-tailed shrew, Blarina brevicaudata, and footprints

Of the smaller trees the hawthorn, American crab, chokecherry,
and the hop tree are conspicuous. The shrubs that are character-
istic are buttonbush, burning bush, or wahoo, elderberry, bladder
nut (Fig. 416), nannyberry, prickly ash (Fig. 417), and in some
places the strawberry bush covers large areas of the ground.

The river bottom association is characterized by many woody
vines, some of which climb up the low trees and drape them with
dense festoons (Fig. 415). Such are the Virginia creeper,' poison
ivy, bittersweet, honeysuckle, moonseed (Fig. 418), and the
wolf grape. Several species of smilax are also common (Fig. 419).

As'in the climax forest there is present here an abundance of
spring herbs that bear blossoms and set their fruit before the
dense shade of summer is produced by the thick foliage of the
trees and shrubs. Skunk cabbage (Fig. 420) and marsh mari-

LAKE BLUFF, RAVINE, AND RIVER VALLEY 275

gold come early in the wet areas. Spring beauty often covers
the ground completely, and later the phlox (Phlox divaricata)
may cover acres with its bloom. Bloodroot, bedstraw, cheveril
(Fig. 421), blue cohosh, dogtooth violet, fringed loosestrife (Fig.
422), geranium, wild ginger, honewort (Fig. 423), leeks and
onions, false mermaid weed, cow parsnip (Fig. 424), Solomon's
seal, both true and false, sweet cicely, spring cress of several
species (Fig. 362), trillium, . toothwort (Fig. 55), violets, and
waterleaf are the common members.

It is interesting to note the arrangement of these flood-plain
zones on an island in midstream. Some shift of current or some
obstruction causes the sediment held by the river to deposit, and
so a mud barrier forms in midstream, a patch of flood plain dis-
connected from the shore. Such an island grows on its down-
stream side because the current is checked by the obstruction
and the deposit is in the quiet waters below it. Vegetation,
therefore, appears on its upper end as soon as this portion dries
out sufficiently to permit plant growth. For the same reason,
the flood plain forest develops here, and successive zones extend
toward the lower end. Islands in a lake or pond have their
zones arranged more or less in concentric rings in contrast to
the longitudinal zones of the river island.

There is usually a marked contrast between the vegetation of
the river valley and that of the bordering hills. We have
already noted above the vegetation of the rock hills. Customa-
rily the hills that border the flood plain bear the usual white oak,
red oak-hickory forest, which has been considered in chapter x.

In most respects the animal life of the flood-plain forest is
very like that of the climax beech-maple forest, though the
forms are not as numerous, as the annual inundation prevents
the permanent residence of many animals. The short-tailed
shrew (Fig. 425), white-footed deer mouse (Fig. 287), and com-
mon mole (Fig. 286) are usually present. The same beetles are
present on the ground and in the rotting logs. The mollusks
are similar though not as numerous.

CHAPTER XIII
BROOK, CREEK, AND RIVER

HERE are a number of factors influen-
cing the character of the animal and plant
life of the stream, though most of them
act as indirect determiners affecting the
quantity and character of the gases con-
tained in the water, its acidity or alka-
linity, the temperature or rate of flow
of the stream, which are the principal
immediate causes of variation in the stream fauna and flora.

If the sources of the water supply are such that the stream
flows intermittently, drying up to form a succession of stagnant
pools when the rains cease — usually in midsummer — but running
as a brook or creek during the spring freshets or the fall rains,
the life it contains will be quite different from that of the steadily
flowing streams. A spring-fed brook, because of its low temper-
ature, will support a population quite unlike that of the stream
that emanates from pond or swamp. A stream whose waters
are distinctly acid from abundant decomposing organic matter
or from factory waste will have quite a different fauna and flora
from the usual alkaline stream of this area. The population
of the Illinois River has suffered very marked change in recent
years because of the increase in decomposing organic matter
brought to it by the Chicago Drainage Canal. Thorn Creek
has largely lost its normal inhabitants on account of factory
waste, and a new set of organisms have come in.

The stream from source to mouth shows a succession of
species, those of the small brook giving place to others that appear
as the stream widens and deepens. So we may speak of the
headwaters or brook society, the midcourse or creek society,

276

BROOK, CREEK, AND RIVER 277

the lower stream or river society, and finally the estuary society,
found in the sluggish, backed-up waters near the mouths of
some streams. The inflowing streams, tributaries to the main
river, are likely to display quite unlike inhabitants, those
entering well down toward the mouth showing marked contrasts
to those entering up toward the source, for the animals and
plants present in the main stream, whence they migrate into the
tributaries, are so different in the various parts of the course.

Even in the same region of the stream the species present
will vary according to varying depth and rapidity of the current.
Along shore the water is shallow and so relatively well aerated,
while in the deeper portions of the stream the volume below a
given area of surface is much greater and the concentration of
carbon dioxide and other gases of decomposition is higher, other
things being equal. So a zonation of plants and animals from
shore outward may be expected. For the same reason there is a
zonation from the surface downward since the oxygen content
of the surface layers is high as compared with the bottom
layers. This evidently will be most marked in the quiet
stretches. In the rapids where the water is constantly stirred
from top to bottom there will be no such marked difference.
So in the sluggish stretches of the river the oxygen content
will be low, that of carbon dioxide high,- while in the rapids
where the water is well aerated by its turmoil the reverse will
be true. Active forms demanding much oxygen can live in the
latter situations but not in the former.

The character of the bottom affects the animal and plant
population. As a rule the stream has its bottom covered with
rocks or coarse gravel in its most rapid stretches, a sandy bottom
where it is less rapid but still flowing quite vigorously, and a mud
bottom in its quiet stretches. In part, the differences in plant and
animal life on these different bottoms are due to the varying rates
of the current, but in part they are directly connected with the
character of the bottom itself. Some plants and animals, for
instance, are adapted by holdfasts to attach themselves to a rock

278 A NATURALIST IN THE GREAT LAKES REGION

substratum, others burrow only in sand, and still others require
the soft mud in which to lie concealed.

It is evident., then, that streams present a great variety of
habitats and, therefore, a number of animal and plant societies,
which may be tabulated somewhat as follows:

A. Communities of the intermittent stream

1. Intermittent rapids society or the Simulium (black
fly) association

2. Intermittent pool society or the Cambarus dio genes
association

3. Permanent pool society or the horned dace association

B. Communities of permanent streams

4. The spring-fed brook or planarian association
a] Of the usual alkaline stream

5. The very rapid water (lotic) society or the Hydro-
psyche association

This is a rock-bottom society and may be subdivided
into

a) Rapids of the brook, Johnny darter association

b) Rapids of the creek, fan-tail darter association

c) Rapids of the river, banded darter association

6. The moderately rapid, sand-bottom society

a) Of the brook

b) Of the creek

c) Of the river

'both divisible

7. The sluggish water surface association

8. The sluggish water bottom association

9. The estuary associations
10. The acid stream society

as the forego-
ing into a), b),
c)

It would require a volume rather than a chapter to discuss in
detail the stream societies and subsocieties with anything like

BROOK, CREEK, AND RIVER 279

thoroughness. We must be content, therefore, to indicate
briefly changes in animal and plant population as the stream
grows in size from brook to creek and to river. Then attention
may be called to the societies of rapid water as contrasted with
those of sluggish water, and finally we may take up very briefly
the societies of intermittent streams, of spring-fed streams, and
of acid streams.

Take first the distribution of some of the river clams in the
Illinois River and its branches. The data are taken largely
from Baker's "Catalogue of the Mollusca of Illinois," Bulletin
of the Illinois State Laboratory of Natural History, Volume VII,
Article VI, and his " Mollusca of the Chicago Area, " Part I, "The
Pelecypoda, " Publication of the Chicago Academy of Sciences.
The larger branches of the Illinois from its mouth toward its
source are in order, (i) the Sangamon, (2) the Spoon, (3) the
Mackinaw, (4) the Vermillion, (5) the Fox, (6) the Kankakee,
(7) the Desplaines. It is the union of the last two that makes
the Illinois. The more important branches of the Desplaines
are (8) the DuPage, (9) Hickory Creek, (10) Salt Creek. The
smaller creeks or runs are mere brooks and do not support a
clam population. Of the genus Lampsilis only two get up into
Salt Creek, namely, L. luteolus and L. ellipsiformis . Four more
are found in Hickory Creek, L. ventricosa, L. fallaciosa, L. iris,
and L. parva. All of the foregoing except one, L. fallaciosa, are
reported from DuPage River, and in addition four others, L. liga-
mentina, L. anadontoides , L. recta, and L. alata. All of the fore-
going are found in the Illinois and its larger branches, and in
addition six other species that do not get up into the Desplaines.

Anadonta marginata is found in Hickory Creek but not in
Salt Creek. A. grandis and A. grandis footiana are in the
DuPage but not farther north. A . imbecilis is in the Desplaines
but not in its branches. The Quadrulas are almost entirely
confined to the larger streams. Q. rubiginosa is reported from
Salt Creek and Q. coccinea from the DuPage. There are eighteen
other species in the Illinois and its larger branches named above.

280 A NATURALIST IN THE GREAT LAKES REGION

Consider next the dragon-fly nymphs. I quote from Need-
ham's "Dragon-Flies of Illinois," Bulletin of the Illinois State
Laboratory of Natural History, Volume VI, Article I. This
indicates not only that the distribution depends on the size of
the stream but also that forms vary according to the rapidity
of the current and the character of the bottom.

In the larger rivers*, down to the size of the Mackinaw, in places where
the water flows with considerable current over a rocky bottom, Diastatomma
may be looked for; where mud or sand bottom and quieter waters prevail,
Epicordulia and some species of Gomphus may be found. Other species
of Gomphus occur in the bare muddy or sandy bottoms of the sloughs and
bottom-land lakes. In tree shaded waters, where driftwood and branches
have gathered, or along muddy margins, especially among exposed roots,
the lower Aeschnidae may be looked for. In bottom-land lakes where
vegetation is abundant, one may find Anax, Agrionidae, Mesothemis, Celelhe-
mis, Tramea and Pantala amongst the vegetation, the latter two especially
on more exposed shores; and Tetragoneuria, Libellula, Epicordulia and
Leucorhinia on the bottom underneath. If the situation is inclined to
be marshy, Pachydiplax, Perithemis and Celithemis will be scattered over
the bottom; and the shallowest and most temporary waters or wet lands are
the especial home of Sympetrum.

In the smaller and quicker flowing streams, like the upper Mackinaw
and Sangamon, quite a different series occurs: Hagenius clinging to stones
and driftwood and amongst dead leaves; Boyeria and other dark Aeschnidae
on submerged branches, roots and sticks; Cordulcgaster and the long-legged
Macromia hidden at the bottom in sheltered eddies; Somatochlora; and
finally Progomphus, Dromogomphus and certain species of Gomphtis bur-
rowing in the sandy bottom. In the prairie ponds and slow streams and
ditches, Anax, Agrionidae, and Mesothemis and other Libellulidae occur
amongst vegetation, and Sympetrium in shallower parts, while Libellula
and Plathemis will be found where there is more mud and less vegetation,
as in ditches and tile ponds, resting at the lower ends of well defined tracks.
In streams of rapid flow but not especially rocky or shaded, the Calop-
terygidae are most likely to be found, the imagoes fluttering along the
banks.

Of the above-mentioned the Agrionidae and the Calopterygidae
are families of the damsel flies whose nymphs bear three leaflike
tracheal gills at the posterior end of the abdomen. The basal

BROOK, CREEK, AND RIVER

281

segment of the antennae is nearly round in the former, very
elongate in the latter. The rest are included in four families
of the dragon flies. The Aeschnidae and Gomphidae have a flat
mask that does not cover the face. The former have six- or
seven- join ted slender antennae; the latter, four- jointed stout

FIG. 426. — Nymphs of the dragon flies: a, Anax;
After Needham.

, Aeschna; c, Boyeria.

antennae. The Cordulegasteridae and the Libellulidae have a
mask that is spoon-shaped and that covers the face. The teeth
on its opposing edges in the former are large, acute, and inter-
locking; in the latter they are rounded. Family Aeschnidae
includes of those mentioned above,
Anax, Aeschna, and Boyeria, the
nymphs of which have respectively
three, four, and five pairs of lateral
spines on the sides of the abdomen
(Fig. 426). Family Gomphidae includes
Progomphus, Diastatomma, Hagenius,
Dromogomphus, and Gomphus. In Progomphus the middle pair
of legs are set closer to each other than are the forelegs, in the
others at least as far apart as the forelegs, in Hagenius farther
apart. Hagenius also has more than four pair of lateral spines,
the others not over four pair. The tenth or last abdominal
segment of Diastatomma narrows posteriorly, while that of

FIG. 427. — Head of horned
da,ce,Semotilns atromaculatus.

282 A NATURALIST IN THE GREAT LAKES REGION

Dromogomphus and Gomphus has its sides parallel. Of the two
latter the first has acute, spiny-tipped dorsal hooks on the
abdominal segments, while in Gomphus such hooks are usually

FIG. 428. — Red-bellied dace, Chrosomus erythrogaster

absent and are always dull. Family Cordulegasteridae includes
only the genus Cordulegaster. The rest are therefore included

FIG. 429. — Blunt-nosed minnow, Pimephales notatus

in family Libellulidae, the nymphs of some of which are not
sufficiently well known to make accurate determination possible.
If there is a pyramidal
horn on the front of
the head and a small
dorsal hook on seg-
ment ten, the nymph
is of the genus Ma-
cromia. If the head

FIG. 430. — Johnny 'darter, Boleosoma nignim

bears a tubercle on each side and segments three to nine bear
dorsal hooks, the nymph is that of Epicordulia. If the lateral

BROOK, CREEK, AND RIVER

283

spines of segment nine are sharp, divergent, and longer than
the appendages of segment ten, it is a nymph of Tetragoneuria;
while if the spines of nine are
incurved and not longer than
the appendages of ten, the
nymph is thztolSomatochlora.
If the fish of the streams

are Studied, again we find FIG. 431— Rainbow darter, Etheostoma
Certain Species in the head- coeruleum, two-thirds natural size.

waters, others coming in ^c^HT

down in the mid-course, still

others not appearing until the

river stage is reached, and

finally some largely confined

to the estuary. Streams that

are mere brooks, short and

small, will have the same sort

of fish that are found near

the headwaters of the larger

rivers. The horned dace

(Fig. 427) is apparently the fish that works its way farthest

upstream, often living in the pools of brooks that otherwise

FIG. 432. — Head of common sucker,
Catostomus commersonii, one-third natural
size.

FIG. 433. — Stone roller, Campostoma anomalum

have dried up. The red-bellied dace (Fig. 428) and the black-
nosed dace are not far behind it. The blunt-nosed minnow
(Fig. 429), Johnny darter (Fig. 430), and the rainbow darter

284 A NATURALIST IN THE GREAT LAKES REGION

FIG. 434. — Top minnow, Fundulus dispar, male
and female.

(Fig. 431) are also inhabitants of the smaller brooks, while the
golden shiner, the common sucker (Fig. 432), and the chub sucker
(Fig. 192) also get well up stream.

The following may be considered primarily creek fish: the
black bullhead, red horse, stone roller (Fig. 433), common shiner,

river chub, common
top minnow, Fundu-
lus dispar (Fig. 434),
fantailed darter (Fig.
440). While those
that are found in the
rivers are the mud cat,
the stone cat, banded
darter, hog-nosed
sucker (Fig. 435),
straw-colored min-
now (Fig. 436),redfin,
red-faced minnow, gizzard shad, mud minnow, brook silver-
sides, rock bass (Fig. 437),
small-mouthed black bass,
black and white crappies (Fig.
438), the last four especially
in the gravel-bottomed pools.
In the estuary are to be
found those fish that are
ordinarily lake-inhabiting
forms such as the dogfish, tad-
pole cat, buffalo, grass pike,
bluegill, pumpkin-seed, large-
mouthed black bass, pike

perch, and yellow perch. This is, of course, not to be inter-
preted as meaning that the brook fish, the creek fish, or the
others are confined to one particular habitat, but merely that
if one makes systematic collections they will be captured most
frequently in the situations indicated.

FIG. 435. — Head of hog sucker, Catos-
tomus nigricans, one-half natural size.

BROOK, CREEK, AND RIVER

285

That portion of the stream where rapid water hurries over
stony bottom is the habitat of the darters, the sucker-mouthed

FIG. 436. — Straw-colored minnow, Notropis blennius

FIG. 437. — Rock bass, Ambloplites rupestris, one-half natural size

TOM

FIG. 438. — Black crappie, Pomoxis sparoides, one-third natural size

minnow (Fig. 439), the stone roller, the hammerhead sucker.
The rainbow darter, the fantail, black-sided (Fig. 441), sharp-

286 A NATURALIST IN THE GREAT LAKES REGION

headed (Fig. 442), banded, and Johnny darter are all able by
their large pectoral and anal fins to hold themselves among the
stones in the swift current and search under them with their
pointed heads for insect larvae. The sucker-mouthed minnow

FIG. 439.— Sucker-mouthed minnow, Phenacobius mirabilis

has similar feeding habits. The stone roller, as the name

indicates, moves the smaller stones in his efforts to nibble off

the slime, while the hammer-
head sucker can dislodge
quite good-sized stones in
his effort to locate hiding
FIG. 440— Fan-tailed darter, Etheostoma animals. On the Other

hand, there are certain fish

found in the sluggish waters over mud bottom. Such are the

black bullhead, hog sucker, and golden shiner.

FIG. 441.— Black-sided darter, Hadropterus aspro

No association contains more remarkably adapted animals
than this lotic or Hydropsyche association. The net building
caddis fly (Hydropsyche) (Fig. 443) forms a cornucopia-shaped
tube open at both ends with the large flaring end upstream.

BROOK, CREEK, AND RIVER 287

This is attached to the rocks on the bottom. The large end of
the tube is covered with a cup-shaped net spun of silken strands.
The larva lies at one side of the net and picks off the small
animals and plants the current brings down. Not infrequently
the entire upper surface of the stones on the bottom will be
covered with these net tubes of this larva. Another caddis-
fly larva, Helicopsyche, has a coiled tube built of sand grains
(Fig. 444) that appears like a small snail shell. This lives in mod-
erately rapid water of the large creeks where the bottom is pebbly.
It attaches to the rocks. The larva of the black fly, Simulium,
is universally present in the rapid water running over stones
from the merest trickle in the tiny runnel way down stream as

FIG. 442. — Sharp-headed darter, Hadropterus phoxocephalus

long as rocks on the bottom afford attachment. The larvae
appear like black, squirming, short worms with brushes of bristles
at the free end, by means of which they catch the tiny animals
and plants floating in the current. They are so numerous as to
make great patches on the rocks. Each larva is attached at
one end by a sucker but can let go at will when it spins a silken
strand, at the end of which it dangles in the water, seeking new
feeding ground. The adults are the pestiferous tiny flies that
swarm about the head of the fishermen or the udder of browsing
cattle and take bloody toll. Under the stones one finds blood-
worms, larvae of midges of genus Chironomus, stone-fly nymphs
(Perla}, damsel-fly nymphs (Argiaputridd), May-fly nymphs
(Siphlurus alternatus) , the larva of a water beetle (Fig. 446) so
flattened and rounded it is called the water penny (Psephenus
lecontei}. These nymphs in the rapidly running water have
head, body, and limbs all flattened to offer the least possible

288 A NATURALIST IN THE GREAT LAKES REGION

resistance to the water, and many of them have specially devel-
oped suckers, by means of which they attach to the rock. The
water penny (Fig. 445) is so altered by its adaptation to its
environment that one would never take it at first sight for a
beetle larva.

The snail, Goniobasis livescens, lives in the rocky rapids,
dozens of them often on a single bowlder, clinging on by their
strong muscular foot, feeding on the microscopic plants that

FIGS. 443-447: Fig. 443. — Net-building caddis-fly larva, Hydropsychc, in its
tube (above); front view of tube (below), enlarged; Fig. 444. — Coiled tube of
larva of caddis-fly, Hclicopsyche, enlarged; Fig. 445. — Water penny, larva of 446;
Fig. 446.— Brook beetle, Psephenus lecontei; Fig. 447. — A common rotifer,
much enlarged.

form the slimy layer of green scum on the rocks. The liberty
cap snail, Ancylus, whose coiled shell has been reduced to a
broad, low cone, is fairly abundant in the stony rapids of the
brooks.

Pleurocera elevatum is found where the current is not so very
strong. It often prefers the gravelly margins of the stream.
The crayfish, Cambarus virilis, is found hiding under the stones,
very commonly.

BROOK, CREEK, AND RIVER 289

In the moderately rapid waters with sandy or gravelly
bottom will be found Campeloma subsolidum and C. integrum,
good-sized snails. These spots are the habitat of the clams
already mentioned. It is in the larger rivers that the good-sized
specie occur abundantly, forming mussel beds on the sand bars.
The clam lies buried in the sand or silt with only the posterior
portion of the shell protruding. Out of this end stick the
siphon tubes which take in the water containing the tiny
animals and plants (plancton) on which the clam feeds. It is
from the thick shells of the larger species that the pearl buttons
are stamped.

In the quieter stretches of the stream, where the bottom is
muddy, will be found the burrowing May-fly nymphs of genus
Hexagenia, the fish and dragon-fly nymphs already noted, and
a number of forms identical with those of ponds. Just at the
margin of the quiet waters, where the current goes swiftly by,
will be found the May-fly nymph, Chirotenetes siccus.

The plant life along the shore and in the bed of the stream
is in general appearance very like that in similar situations in
the ponds and lakes, though the constituent species may be
quite different. Attached to the rocks and logs in the stream
bed are numerous filamentous algae and some water mosses.
Stones and logs are found, slippery with the mucus secreted by
diatoms or other algae that coat their surfaces with a dense
layer of plant life, and the stream is often choked in its quieter
stretches with submerged plants similar to those of the ponds,
Myriophylum, Utricularia, Elodea, Vallisneria, Ceratophyllum, etc.
In quiet stretches pond lilies are common. The shores are lined
with zones of plants, rushes, cat-tails, arrow root, sedges, and
grasses.

These relatively quiet marginal areas are the breeding-places
for an abundant plant and animal life, largely minute forms, the
overflow of which is carried downstream in the current as the
plancton. This consists largely of microscopic plants, diatoms,
desmids, and other single-celled forms, of some filamentous types,

29o A NATURALIST IN THE GREAT LAKES REGION

of many animals like the protozoa, rotifers (Fig. 447) , and small
crustaceans. The waters of midstream are teeming with this
floating population, of which one is not aware until he strains
it out with a fine net. Kofoid found in the Illinois River at
Urbana almost five million organisms to the quart, a million of
which were animals. He estimates the total plancton carried
down by the river per year at more than two and one

FIG. 448. — Valley of lower Galien River, New Buffalo, Michigan. Note plant
zonation in foreground.

quarter million cubic feet of solid organisms. Certain flagellates,
ciliated forms like Vorticella, and the shell-bearing rhizopods,
Difflugia and Arcella, are among the commoner protozoa.
Daphne, Bosmina, Acroperus, Leptobora, are common cladoceran
crustaceans, while Cyclops, Diapotamus, and Canthocampus are
the customary copepods. A very transparent midge larva,
Corethra, is sometimes very abundant. It is nearly an inch
long and so transparent that the internal organs are plainly
visible as if it were made of glass. The crustaceans of the
plancton are the staple article of diet for all of the small

BROOK, CREEK, AND RIVER 291

carnivorous fish of the stream. The crustaceans, in turn, feed
upon the smaller organisms of the plancton, both plant and
animal.

The first animal to appear in intermittent streams, even when
it is a mere trickle, is the larva of the black fly. Along with this
are to be found larvae of May flies, under the stones, and caddis
worms in their irregular tubes formed of bits of stone (Rhynco-
philidae).

In the pools of such intermittent streams are found in the
spring crayfish (Cambarus diogenes) that dig in and live in their
burrows as the temporary pools dry out. They come out at
night to secure their food. As the pools become larger and
more permanent, Cambarus mrilis and C. propinquus replace the
burrowing crayfish. Gammarus fasci atus and Asellus are added
to the crustacean population. Water striders, back-swimmers,
and water boatmen appear. The diving beetles, Hydroporus and
Agabus, are found. Burrowing dragon-fly nymphs inhabit the
pools, and the adults fly over their surfaces (Aeschna constricta
and Cordulegaster obliquus).

The first fish to appear is the horned dace (Semotilus atroma-
culatus). It swims away upstream to deposit its eggs, so the
young are common in these temporary pools and often die in
large numbers as they dry out. The red-bellied dace (Chrosomus
erythrogaster) is likely to get almost as far upstream, but breeds
only in pebbly and sandy bottom. It, too, is found in the tem-
porary pools.

In the spring-fed brooks the characteristic vegetation is the
water cress. Black-fly larvae are present, as also the same
benders, crayfishes and beetles mentioned above. In addition,
the net-building caddis fly (Hydropsyche) is found. The brook
beetle, Elmis fastiditus, is very characteristic. The spring-fed
brooks in our locality are very short, usually joining some larger
stream quite promptly. In these springs and brooks such
planarians as Dendrocoelum and Planaria dorotocephala are
abundant.

292 A NATURALIST IN THE GREAT LAKES REGION

As one proceeds downstream to a point where the river
has cut down nearly to the level of the body of water into
which it flows it is prone to become sluggish, choke its own
mouth with sand or mud bars, back up and spread out over a wide
area of its lower flood plain, and so develop an estuary. A very
good example of this is seen above the mouth of the Galien River
at New Buffalo, Michigan (Fig. 448). Conditions are practically
those of the filling lake or pond. The zones of plants and animals
are well developed and occur in the same order as already
discussed in the chapter on the filling pond.

CHAPTER XIV

SOME SOURCES OF OUR FAUNA AND FLORA

| HE preceding chapters, if they have
accomplished their purpose, have given
the attentive reader the conception,
based on a good deal of detailed evi-
dence, that plants and animals are not
jumbled together in the outdoors in
chance assortments, but are grouped in
very definite associations, quite as clear
cut as are human societies. Indeed, sociology may be regarded
as the science of human ecology. This notion gives added zest
to one's excursions afield. You learn not only to recognize the
common-place forms but to study their groupings and to give
attention to those structural and functional adaptations by which
organisms are fitted to a specific environment. We have found
structurally very unlike forms, both plant and animal, closely
associated, and very like forms completely separated. The
rapids society of the stream is made up of fish, insect larvae of
many orders, crustaceans, leeches, and mollusks, a strangely
assorted family. On the dunes the closely related tiger beetles,
all predatory forms very similar in habit, were found each in its
particular zone. Ecological groupings of plants and animals
will often or usually cut across taxonomic groupings.

Thus far, however, we have considered the matter from the
static point of view. We have considered the associations of
plants and animals as they are. There is a dynamic side. We
need to consider how they have come to be. The present
is the outcome of an eventful past and is to be explained as
l:he resultant of many forces operating through long periods
of time.

293

294 A NATURALIST IN THE GREAT LAKES REGION

Without going back unduly into the past, it is very evident
that when the last glacial advance slowly came on and buried
the Great Lakes region almost in its entirety under thousands of
feet of ice, the plant and animal life existent here before the
advance began must have been obliterated, except in so far as
it could retreat southward into congenial territory. Moreover,
there must have been a complete change in the fauna and flora
even before the glacier arrived. For as it progressed there
preceded it a change in climate. The rigors of the winters
increased, the summers became brief and cool. Many of the
plants and animals flourishing here before the ice sheet began its
southward movement must have been driven out and replaced
with forms more characteristic of the north. Evergreens took
the place of the deciduous forests, and the animals changed
accordingly. As the glacier approached still nearer, the conifer-
ous forests extended farther south, while here trees were becoming
dwarfed. Then this region became treeless, and tundras covered
with hardy grasses, mosses, and lichens occupied it, similar to those
existent in the far north on the border of the regions of perpetual
snow. Finally this tundra region moved south, and the glacier
itself came on. Probably neither the tundra zone bordering the
glacier nor the coniferous forest zone beyond it were very wide
when the glacier reached its maximum extension, for it was melt-
ing along its front, so the climate there could not have been very
rigorous. The deciduous forest probably covered much of the
southeastern portion of the continent and the arid plains and
short grass regions much of the southwestern portions as now.

When the last glacial period was passing off and the great
ice sheet was beating a slow retreat, the land, with topography
much changed, was open to plant and animal occupation. The
great tundras, the areas of stnnted trees, and the coniferous
forests largely followed the glacier northward, leaving a few
scattered remnants here and there. The climate of our region
again became congenial to the deciduous forests, the prairie
plants, and their accompanying animals.

.,,.

SOME SOURCES OF OUR FAUNA AND FLORA 295

Whence then came the plant and animal immigrants that
replenished our barren region? Briefly stated, the facts are
these. Certain elements of our present fauna and flora are
relics of the tundras and the coniferous forests. In addition, the
sterile land uncovered by the retreating glacier was gradually
repopulated by immigrants from at least three centers, one an
arid region in the southwest with whose fauna and flora ours has
many affinities. A second center was in the southeast; from it,
for example, have come most of our deciduous forest trees and our
river clams. ' The third region from which ours has received con-
tributions is the Atlantic Coast plain. Many animals and plants
of the shores of the Great Lakes are identical with those of the
eastern seacoast. And finally there is a very perplexing factor in
that the only close relatives of certain of our plants and animals to
be found anywhere in the world are along the eastern coast of Asia.

There are no remnants of the tundra formation in the immedi-
ate vicinity of Chicago, for such exist in eastern North America
only in isolated patches on the mountain tops. Such are found
in the Great Lakes region on the high hills of northern Wisconsin
and Michigan. As examples of such forms may be mentioned
the dwarf grass, Agropyron biflorum, the herbaceous willow, Salix
herbacea, a very low form with an underground stem that lies in
the wet mosses, Rhododendron lapponicum, Arctostaphylos alpina,
some dwarf blueberries, Vaccinum oliginosum and V. caespitosum,
mosses and lichens such as the Cladonia rangiferina.

There are, in the pine association of the Dunes, as already
noted, extensive areas with a distinct boreal character. Here
flourish Pinus strobus, P. Banksiana, together with the arbor
vita, low and spreading junipers, such boreal shrubs as prince's
pine, shinleaf, arbutus, northern herbs like star flower, false
lily-of-the-valley, etc. There are scattered remnants of this
coniferous society on rocky hills elsewhere, particularly on their
dry crests and cold northern slopes. Associated at times with
these p'ants in the Dunes, but elsewhere in our region quite
isolated, is another subarctic formation, the sphagnum- tamarack

296 A NATURALIST IN THE GREAT LAKES REGION

bog society. This and the pine association, found in our region
as more or less isolated islands in the midst of the prevalent
oak-hickory society, are, farther north, the prevalent thing.
The sphagnum bogs cover wide areas and have their maximum
development in a region extending from north of the Gulf of
St. Lawrence to northern New England in the East, thence
west, spreading from mid-Lake Michigan shores to Hudson
Bay and then northwest into Saskatchewan. There can be no
doubt that this bog society like the pine association invaded
our region in advance of the glacier and followed it back in its
retreat, leaving the isolated patches in favorable localities to
continue to the present, defying the encroachments of the plants
and animals that later came to occupy most of the region. There
is therefore no gradual transition from the sphagnum-tamarack
bog society to the surrounding societies, but an abrupt break
between the two, for this northern invader is surrounded by
still later arrivals with which it has no genetic continuity. In
the north it leads to the coniferous forest, but here the conif-
erous forest itself is at best struggling to maintain a none too
secure footing. The coniferous forest farther north leads on to
the hardwood climax forest, so that the transition from the pine
association here to the black oak association is a relationship
that is not strained. There seems to be some evidence, as at
Cedar Lake, that the tamarack bog does still develop in this
region. Young tamaracks are appearing in the sphagnum bog
there and are pushing farther out into it.

How these northern elements came into our fauna and flora
is quite evident. The glacier forced them south and the rising
temperature in the south as the glacier retreated forced them to
migrate north again or suffer extinction, except as relics survive
in limited favorable localities. But what has forced the invasion
into our region, since the glacier left it largely bare, of forms
from the deciduous forest center in the southeastern part of the
continent, the prairie and desert regions of the Southwest, or
the Atlantic Seaboard ?

SOME SOURCES OF OUR FAUNA AND FLORA 297

The driving power back of these movements is the urge of
rapidly multiplying life. Each species tends to fill its habitat
full to overflowing. So prolific are living things that the pressure
to move out into adjacent territory is only checked by impassable
barriers that raise the swelling tide until some outlet is found or
multiplication is offset by the high mortality of keen competi-
tion. So quiet and unobtrusive is the life of the ordinary plant
and animal that we humans find it difficult to realize how keen
is the struggle for existence or with what celerity any new
territory is occupied. There is no roar of hostile guns along the
battle-line of opposing animal and plant interests, no press
dispatches tell of starving thousands, no blare of trumpets or
floating banners mark the progress of quiet invasion. But there
is, nevertheless, tremendous activity. Reproduction is at a
geometrical rate; that is, a pair does not give rise to another
pair merely, but to a litter, a swarm, a horde. A single female
codfish lays five million eggs at one spawning. A pair of potato
beetles would produce in one season a progeny of sixty million,
if all their offspring and their offspring, too, lived unmolested.
"The descendants of a common housefly would in the same
time — six generations of about three weeks each — occupy a space
of something like a quarter of a million cubic feet, allowing two
hundred thousand flies to a cubic foot. An oyster may have
sixty million eggs and the average American yield is sixteen
millions. If all the progeny of one oyster survived and multi-
plied, and so on until there were great-great-grandchildren, these
would number sixty-six with thirty-three noughts after it, and
the heap of shells would be eight times the size of the earth!
Of course none of these things happen because of the checks
imposed by the struggle for existence. Yet, every now and
then, as man knows to his cost, a removal or diminution of the
natural checks allows the potential productivity to assert itself
for a short time or within a limited area. The river of life some-
times does overflow its banks, as it always tends to do, and the
resulting flood is called a plague" (Thomson, The Wonder of Life).

298 A NATURALIST IN THE GREAT LAKES REGION

Begin with a single dandelion plant bearing a single blossom
cluster in the year — a slander on the enterprising dandelion —
that gives rise to a hundred seeds. Let these find lodgment
and next year produce plants that each grow a single blossom
cluster that produces one hundred seeds, and so on. It will be
a matter of less than ten years before there are enough dande-
lion plants to cover every foot of land upon the face of the earth.
Or consider the coyote that brings into being a litter of eight
or nine pups at a time. Suppose these are half male and half
female and require two years to reach sufficient maturity to
breed. Let the breeding life be only five years, and if nothing
interfered with the multiplication of a single pair and that of
their offspring inside of half a century there would be a coyote
for every square foot of earth. The rancher who has tried to
exterminate his coyote neighbors, or the householder who tries
to keep his lawn free from dandelions, knows that the possibili-
ties are not overdrawn.

As a result of such astounding fertility, usually more or less
held in check by enemies that prey upon the offspring, there is
every now and then an overflow of a species from its habitat
into the surrounding territory, where if conditions are favorable
it permanently establishes itself. The Rocky Mountain locusts
have repeatedly appeared in great hordes in the plains states
near the mountains, a devastating army that comes in clouds,
darkening the sun, that leaves cornfields as barren wastes within
a few hours after alighting upon them, plagues of locusts that
have inflicted millions of dollars of damage on crops covering
wide areas. The Lapland leming is a small rodent which every
ten or fifteen years moves out from its home through surrounding
regions in vast numbers, devouring every green thing and usually
being devoured by hawks, owls, foxes, and other species of preda-
tory animals that follow in its wake in numbers. In the
Farmers' Bulletin No. 352, United States Department of Agri-
culture, is described a plague of mice in the Humboldt Valley,
Nevada, from which a few sentences are quoted.

SOME SOURCES OF OUR FAUNA AND FLORA

299

Extensive ravages first occurred above and about Lovelocks. In
May, 1907, fields on the Rogers ranch, 5 miles below Lovelocks, were invaded
from lands farther up the valley, the progress of the mice being plainly
marked, as the fields above the Rogers ranch suffered first. The move-
ment of this great body of mice, it should be noted, was a gradual, scattering
progression, first by a few and later by increasing numbers, until the greater

part had moved to fresh fields By October, 1907, a large part of

the cultivated lands in this district had been overrun by vast numbers of
mice The height of the abundance was reached in November, when

FIG. 449. — Map of potato beetle invasion, with dates of arrival at some
localities. After Tower.

it was estimated that on many large ranches there were 8,000 to 12,000
mice to each acre. The fields were riddled by their holes, which were
scarcely a step apart, and over large areas averaged 150 to 175 to the square
rod. Ditch embankments were honeycombed, and the scene was one of

desolation By November they had destroyed so large a percentage

of the plants that many fields were plowed up as hopelessly ruined

By January, 1908, in fields where the mice had existed by thousands the
previous summer and fall, comparatively few, possibly 200 to 500 to each
acre, remained. The border of the destroyed district was about 6 miles
below Lovelocks, and the mice were gradually moving down the valley.

The exact data regarding such invasions of adjacent territory
by animals and plants are, as a rule, only available when the

300 A NATURALIST IN THE GREAT LAKES REGION

invading forms affect man's crops or his domestic animals.
When about the middle of the last century settlers pushing west-
ward brought the fields of cultivated potatoes to the edge of the
habitat of the Colorado potato beetle, there feeding on wild
species of the potato family, the eastward movement of this
animal began. The progress of its invasion and the routes
followed can be seen on the accompanying map (Fig. 449).
Similarly the cotton-boll weevil, which came out of Mexico to
invade the United States, is rapidly spreading all over the South
where cotton is a crop. Its advance is shown in the accompany-
ing map (Fig. 450). Jimson weed (a shortening of the original
name, Jamestown weed) was introduced from the Old World into
this country at Jamestown in colonial days, from whence it has
spread all over the Eastern United States. Russian thistle,
introduced into this country by immigrants in wheat seed planted
in North Dakota in 1873, has since then spread pretty much
all over this country and much of Canada east of the Rockies.
This insurgency of living things, impelling them to seek new
fields to conquer, soon repopulated, from the three centers named,
the territory laid waste by the glacier. Southeastern United
'States seems to be the distribution center from which have come
most of our deciduous forest trees, the river clams, such snails
as the Pleuroceridae and Viviparidae, most crayfish, and a large
share of our fish. Undoubtedly many other forms have also
come from this same center concerning whose movements we
have little or no data. This southeastern center is particularly
rich in species and varieties of the forms mentioned. They there
attain their maximum size. From this center the connecting
rivers and their valleys afford easy highways of invasion. All
of which are good criteria for determining centers of immigra-
tion. A map of North America on which there is drawn in
outline the present range of a number of our important trees
shows at a glance that this southeastern area is a center for all
(Fig. 451). There are omitted from this the evergreens and
such deciduous trees as evidently belong to the northern forest.

SOME SOURCES OF OUR FAUNA AND FLORA 301

302 A NATURALIST IN THE GREAT LAKES REGION

There are more species of fresh-water clams in this south-
eastern area, with Chattanooga as its approximate center, than
in all the rest of the world. The number of species decrease as
you go farther and farther away from this center. Thus, while
Maine has only 10 species of Unionidae, Michigan, much nearer

FIG. 451. — Distribution of certain typical deciduous trees

along the migration route, has 61, Illinois 88, and Alabama 256.
Of the Pleuroceridae Maine has none, Michigan 10, Illinois 28,
while Alabama has 302. Bryant Walker (Distribution of the
Unionidae in Michigan,, Michigan Academy of Science, 1898)
considers that the Michigan Unionidae are almost entirely
Mississippian, only two species, Anadonta fragilis and Unio
complanatus having come from the east. These clams must

SOME SOURCES OF OUR FAUNA AND FLORA 303

have reached Michigan while Lake Chicago and its successors
drained by way of the Illinois and the Wabash, since now all
the streams of Michigan are part of the St. Lawrence drainage
system. That some of the more hardy of the clams did follow
the glacial retreat closely is evidenced by the fact that their
shells are found in undisturbed beaches of the post-glacial lakes.

Of the 150 species of fresh -water fishes found in Illinois that
are native to the state " there are 58 species of the east Gulf and
Florida district" (Forbes and Richardson, The Fishes of Illinois,
" Natural History Survey of Illinois "). From the west Gulf and
Rio Grande region there are forty-seven species of fish (same
authority).' From this same southwestern center come such
animals as our pocket gopher, rattlesnake, six-lined lizard; and
such plants as the dune cactus, Andropogon scoparius, A.fur-
catus, Panicum praecocius, Schedonnardus paniculatus, Cyperus
aristatus, C. acuminatus, Eleocharis tenuis, Carex tribuloides,
Asclepias tuberosa, Silphium terebinthinaceum, Rudbeckia hirta,
all plants that find congenial habitat in the dry sandy areas or
the dry prairies.

From the Atlantic coastal plain region our fauna and flora
have received many contributions. It will be recalled that
during the retreat of the glacier our Great Lakes region was in
much more direct communication with the Atlantic seaboard
than it is at present (Fig. 52). There are fifty- three of the fish
of Illinois that have come from Quebec and the New England
region. As already noted, some of our clams come from this
eastern center, possibly originally emanating from the south-
eastern center, but if so migrating to our region by way of the
coastal plain. A large number of the plants found along the
shores of the Great Lakes seem to have come from this source.
A few may be mentioned, such as Panicum verrucosum, P. oligo-
santhes, Aristida tuber culosa, Ammopkila arenaria (marram
grass), Eleocharis melanocarpa, Psilocarya scirpoides, Fuirena
squarrosa, Cakile edentulata (sea rocket), Euphorbia polygonifolia
(seaside spurge), Xanthium echinatum (cocklebur).

304 A NATURALIST IN THE GREAT LAKES REGION

Finally a great many of our plants and animals are common
to Northern Eurasia and Northern North America, while some
of ours have their nearest relatives along the eastern edge of
Asia. Our common bluebird (Sialia sialis) has an isolated close
relative (Sialia coelicolor) in Eastern Asia. Our spoonbill and
carp sucker, the former a peculiar mud-eating fish, have each
a near relative in China. Our crayfishes are more nearly related
to those of Eastern Asia than to the species of our own Pacific
Coast or of Eastern Europe. Our dragon flies, Hagenius and
Boyeria, have close relatives in Eastern Asia. The tulip tree,
sweet gum, and sour gum all belong to genera found nowhere
else in the world except Eastern North America and Eastern Asia.

Confining our attention to the ferns, horsetails, and club
mosses, the following are common to Europe and North America,
including our Great Lakes region: Poly podium vulgar e, Aspidium
cristatum, A. spinulosum, Osmunda regalis, Equisetum fluviatile,
and E. hyemale. In Asia and our region are found Cryptogramma
Stellar i, Asplenium acrostichoides, Onoclea sensibilis, Osmunda
Claytoniana. While common to Eurasia and North America and
found in our region are such forms as Phegopteris polypodioides,
P. Dryopteris, Onoclea Struthiopteris, Osmunda cinnamomea,
Ophioglossum vulgatum, Botrychium ternatum, Equisetum pratense,
E. sylvaticum, E. variegatum, Lycopodium annotinum, and
L. complanalum.

It must be evident, then, that much of the fauna and flora
in the northern part of the world before the glacial advance
began was common to Eurasia and North America, and that
this life common to the two continents included many forms now
found pretty well south. Possibly, too, since the glacier
retreated there has been land continuity between Asia and
North America, and an invasion route has- led from Eastern
North America through the Northwest to Asia with movements
of plants and animals proceeding in both directions. Much
additional evidence must be accumulated before this last point
can be satisfactorily settled.

AN OUTLINE OF SOME OF THE IMPORTANT PLANT
AND ANIMAL ASSOCIATIONS

ASSOCIATIONS CHANGING SUCCESSIVELY AS LAND CONSTRUCTION GOES ON
The Filling Lake in the Dune Area

1 . The beach association Predatory beetle association

2. Fore-dune association

3. Cottonwood association Digger-wasp association

Transition zone Large tiger beetle association

4. Pine association Cicindela hirticollis association

5. Black oak association Ant-lion association

6. Mixed oak association Tree frog association

Oak-hickory association Green tiger association

Beech-maple association Wood frog association

(For the last two see p. 306)
The filling pond or small lake leads on to

a) the wet prairie and finally to the dry prairie

b) the swamp with white ash-elm association, and finally to the cli-
max forest .

c) the sphagnum bog and tamarack swamp. The early stages of
these are practically identical, namely (7 is usually wanting in c)

7. Bare bottom association Lampsilis luteolus association

8. Chara association Bloodworm association

9. Utricularia Myriophyllum association Ischnura verticalis association

They then differentiate as follows:

(a)

10. Water lily association Painted turtle association

11. Bulrush association Marsh wren association

1 2. Carex-Scirpus association Green flatworm association

13. Swamp grass association Bobolink association

Andropogon furcatus , meadow lark association (see p. 306)

(*)

10. Water lily association Painted turtle association

11. Bulrush association Marsh wren association

14. Cat-tail association Redwing association

15. Buttonbush-prickly ash association Succinea association

3°5

306 A NATURALIST IN THE GREAT LAKES REGION

1 6. Ash-elm association Green heron association

In steep-sided ponds this last may be replaced by the
17. Swamp white oak association, which gives place to the oak forest

1 8. Floating sedge association

19. Sphagnum-Cassandra association ^ Northern locust association

20. Tamarack association

21. The flood-plain or elm-soft maple association

This is subdivided into

22. The bare river margin Spotted sandpiper association

23. Ragweed-sunflower association Plant bug association

24. Willow association Cecropia association

25. Young ash-elm-maple association Yellow warbler association

26. Mature elm-maple association Tanager association

The flood-plain association is stratified like the climax forest (which
see) and the several strata may be named as in the climax forest though
the constituent plants and animals will be somewhat dissimilar.

ASSOCIATIONS THAT ARE RELATIVELY PERMANENT, THE CLIMAX
OF CONSTRUCTIVE PROCESSES, KNOWN AS CLIMAX

ASSOCIATIONS
They are:

27. The prairie or Andropogon furcatus Meadow lark association
association

28. The oak-hickory association Green tiger association

29. The beech-maple association Wood frog association

Each of these is subdivided. In addition to the prairie grasses
other plants are conspicuous, and several types of prairie may be
distinguished in addition to the wet prairie (bobolink) and the Andro-
pogon furcatus (meadow lark) prairie.

30. High prairie or Silphium association Jumping spider association

31. Very dry or Eryngium association Leaf hopper association

32. Thin soil, rock bottom, prairie clover
association

The oak-hickory and beech-maple forests each have a

33. Forest margin or Crategus association Brown thrasher association

Each is divisible into successive strata, much alike in the two except
for variations in the abundance of the constituent forms.

34. The forest crown association Tree cricket association

OUTLINE OF PLANT AND ANIMAL ASSOCIATIONS 307

35. The tall shrub association Epeira association

36. The low shrub association Wood nymph association

37. The ground association Snail association

This in turn may be subdivided into

38. Litter association . Thousand leg association

39. Rotting log association Horned Passalus association

40. Fungus association Fungus beetle association

41. Subterranean association Cicada nymph association

ASSOCIATIONS CHANGING SUCCESSIVELY AS LAND DESTRUCTION
OCCURS

42. The shore clay bluff association Cicindela limbalis association

43. River bluff association Kingfisher association

44. Clay ravine association . Spearhead dragon-fly association

45. Rock ravine association Phoebe association

46. The rock hill association

THE RIVER ASSOCIATIONS
Communities of the Intermittent Streams

47. Intermittent rapids association Black fly association

48. Intermittent pool association Cambarus association

49. Permanent pool association Horned dace association

Communities of Permanent Streams

50. a) The spring-fed brook water cress Planarian association

association
b) The usual alkaline streams associations as follows:

5 1 . The very rapid water (lotic) society Hydropsyche association

This is subdivided into

52. The brook rapids or Rainbow darter association

53. The creek rapids or Fantail darter association

54. The river rapids or Banded darter association

55. The moderately rapid, sandy bottom Campeloma association
association

Which may be divided as above

56. The sluggish water (Limnetic) sur- Daphnia-Cypris association
face society

57. The sluggish water (Limnetic) bot- The clam association
torn society

58. The estuary association subdivided much as is the pond society

59. (c) The acid stream association

BOOK LIST

The following list of books includes some of the most useful
in determining animals and plants in the area studied, together
with a few titles that will serve to introduce the reader to a
more extended study of the subject. Additional bibliographies
will be found in these latter.

Salisbury and Alden, Geography of Chicago and Its Environs. The Geo-
graphic Society of Chicago, Bulletin No. i. Chicago: The University
of Chicago Press.

Cowles, H. C., The Plant Societies of Chicago and Vicinity. The Geographic
Society of Chicago, Bulletin No. 2. Chicago: The University of
Chicago Press.

— , "The Physiographic Ecology of Chicago and Vicinity," Botanical
Gazelle, Vol. XXXI, pp. 73-108, 145-182.

Goldthwaite, J. W., Physical Features of the Des Plaines River Valley. Illi-
nois State Geological Survey, Bulletin No. u. Urbana, 111., 1909.

Sauer, C. O., Geography of the Upper Illinois Valley. Illinois State Geo-
logical Survey, Bulletin No. 27. Urbana, 111., 1916.

Gray's New Manual of Botany. New York: American Book Co. 7th ed.

Brown and Brittain, Illustrated Flora of the Northern States and Canada.
New York: Charles Scribner's Sons. 3 vols.

Hough, Romyn B., Trees of the Northern States and Canada. Lowville,
N.Y. : published by the author.

Blakeslee and Jarvis, Trees in Their Winter Condition. New York: The
Macmillan Co.

Parsons, F. T., How to Know the Ferns. New York: Charles Scribner's Sons.

Underwood, L. M., Our Native Ferns. New York: Henry Holt & Co.

Grout, A. J., Mosses with a Hand-Lens. Published by the author, 360
Lenox Road, Brooklyn, N.Y.

Dunham, E. M., How to Know the Mosses. Boston: Houghton Mifflin Co.

Mcllvane, Chas., One Thousand American Fungi. Indianapolis: Bobbs-
Merrill Co.

Shelford, V. E., Animal Communities in Temperate America. Chicago:
University of Chicago Press.

Hancock, J. L., Nature Sketches in Temperate America. Chicago: A. C.
McClurg & Co.

308

BOOK LIST 309

Downing, E. R., Source Book of Biological Nature-Study. Chicago: Uni-
versity of Chicago Press.

Stone and Cram, American Animals. New York: Doubleday Page & Co.

Gary, Charles B., The Mammals of Illinois and Wisconsin. The Field
Museum of Natural History, Publication No. 153. Chicago.

Chapman, F. M., Hand Book of the Birds of Eastern North America. New
York: D. Appleton & Co.

Reed, C. K., Birds, Land and Water. New York: Doubleday Page & Co.

Ditmars, R. L., The Reptile Book. New York: Doubleday Page & Co.

Dickinson, Mary G., The Frog Book. New York: Doubleday Page & Co.

Forbes and Richardson, The Fishes of Illinois. Natural History Survey
of Illinois, Vol. III. Urbana, 111.

Adams, C. C., An Ecological Study of Prairie and Forest Invertebrates.
Bulletin of Illinois State Laboratory of Natural History, Vol. XI,
September, 1915.

Comstock, J. H., Spider Book. New York: Doubleday Page & Co.

-, Manual for the Study of Insects. Ithaca, N.Y.: The Comstock

Publishing Co.

Lutz, Frank E., Field Book of Insects. New York: G. P. Putnam's Sons.

Holland, W. J., The Moth Book. New York: Doubleday Page & Co.
— , The Butterfly Book. New York: Doubleday Page & Co.

Needham and Hunt, Dragonflies of Illinois.. Bulletin, Illinois State Labo-
ratory of Natural History, Vol. VI, September, 1901.

Williams, E. B., Dragonflies of Indiana. Twenty-fourth Annual Report of
the Indiana Department of Geology and Natural History, 1895.

Carman, Philip, The Damsel-flies of Illinois. Bulletin, Illinois State Labo-
ratory of Natural History, Vol. XII, June, 1917.

Blatchley, W. S., Coleoptera Known to Occur in Indiana, Published by the
author, Indianapolis, Ind.

•, Orthoptera of Indiana, Twenty-sixth Annual Report of the Indiana

State Department of Geology, 1901.

Baker, F. C., Mollusca of the Chicago Area, Part I, "Clams," Part II,
"Slugs and Snails," Chicago Academy of Science.

Needham and Lloyd, Life of Inland Waters. Ithaca, N.Y. : The Comstock
Publishing Co.

Ward and Whipple, Freshwater Biology. New York: John Wiley & Sons.

•Ht
OF THE

FIG. 452. — MAP OF REGION ABOUT SOUTH END OF LAKE MICHIGAN, AND \x

The Dune areas are dotted in. This territory really occupies a larger area about Lake Calumet an>
the purposes of this book. *This sign indicates the Tamarack bog. Electric lines are thus shown

A few of the main automobile roads out of Chicago are shown by a single line . Theyl

map correspond to the numbers on the inset map, which indicates how the city streets connect up with 1

SHOWING THE MAIN AUTOMOBILE ROUTES OUT OF THE CITY OF CHICAGO

south and east, but manufacturing plants and railroads have so altered it that it is nearly valueless for
ler signs are conventional.

drawn to show the route in detail, but merely the general direction. Numbers in triangles on the large
'mobile roads.

INDEX

Acadian period, 46, 47

Adaptations: to aquatic life, 101; to
light, 101

Adder's tongue, Erythronium ameri-
canum

Aftonian glacial period, 57

Alumroot, Heuchera americana

Amphibians, Frogs, Salamanders,
Toads:

—Bufo lentiginosus, toad, 102, 152, 255

• — Chorophilus nigritus, spring peeper, 94

—Diemictylus viridescens, the eft, 188,
189

— Hyla:

pickeringii, 165, 166, 219
versicolor, 165, 1 66, 219

— Plet&don cinereus, red-backed sala-
mander, 219

— Rana:

catesbeiana, bullfrog, 240
clamata, green frog, 240
palustris, pickerel frog, 240, 241
sylvatica, 219, 220
virescens, leopard frog, 240

Amphibole, 72

Amygdaloid, 73

Anacharis, see Flowering plants

Anemone, A ncmonella thallictroides

Angelica, see Flowering plants

Animal census, 150

Ant, carpenter, 165

Anticline, 18

Ant-lion: association, 150, 159, 163;
Myrmelion, 160

Aphids, 165

Aquatic insects, adaptations of, 104

Aquatic leaf form, 102, 103

Arachnida, Spiders, Mites:

— Argiope, the orb weaver, 188, 190

• — Dendryphantes octavus, 158

• — Dolomedes sexpunctatus, diving spi-
der, 104

— Epeira gigas, 220, 223, 225

— Hydrachna, red water mite, 94

— Limnochares aquations, water mite,

— Lycos a wrightii, burrowing spider, 99,

154

— Neocosoma arabesca, 220, 223, 225
— Pardosa lapidicina, 260, 261
— Phidippus audax, 223, 225
— Philodromus alaskensis, 158
— Tetragnatha laboriosa, long-bodied

spider, 270, 271
— Theridium spirale, 159
—Trochosa cinerea, sand-colored spider,

152,153
— Xysticus formosus, 158

Arcella, 290
Archaeozoic, 30, 31, 41
Arrowhead, Sagittaria latifolia
Ash-elm association, 241
Aster blossom, spider of, 108
Aster, rush, Aster junceus
Atmosphere, beginnings, 26

Back swimmer, see Hemiptera

Baneberry, Actaea

Bare-bottomed ponds, 1 79

Basalt, 19, 75, 76

Bat, brown, see Mammals

Beach association, 115, 119

Bearberry, Arctostaphylos Uva-ursi

Bee, carpenter, 219

Beetles, see Coleoptera

Beggar-ticks, Bidens frondosa

Bedstraw, Galium aparine

Bellflower, marsh, Campanula apari-

noides

Bellwort, Uvularia grandiftora
Bender, see Crustaceae
Bergamot, Monarda fistidosa
Betelgeuse, 21

3I2

NATURALIST IN THE GREAT LAKES REGION

Birds, bones of, 105
Birds:

— Bittern: American, 240,243; least, 240
—Blackbird: red-winged, 240; yellow-
headed, 240
—Bluebird, 166
— Blue jay, 166
— Bobwhite, 229, 269
— Brown thrasher, 229
— Bunting:

indigo, 229, 270
lark, 254

—Cardinal grosbeak, 270
—Catbird, 229
— Chewink, 229, 269
—Chickadee, 159, 270
— Crow, 1 66

—Cuckoo, black-billed, 270
—Curlew, Hudsonian, 151
— Dickcissel, 254
— Flycatcher:

great crested, 220, 270
least, 1 66
— Gallinule, 241
— Godwit, Hudsonian, 157
—Goldfinch, 229
—Grosbeak, cardinal, 270
—Hawk:

red-shouldered, 166, 202
red-tailed, 166
—Heron, green, 242
— Kingbird, 156
—Kinglet:

golden-crowned, 159
ruby-crowned, 159
—Knot, 151
—Lark:

meadow, 254
prairie horned, 254
—Mourning dove, 229
—Oriole, Baltimore, 270
— Ovenbird, 220, 270
—Owl:

great horned, 220
screech, 220
—Phoebe, 269

— Pewee, wood, 166, 220, 269
— Plover:

killdee, 152
piping, 152
semipalmated, 152
—Prairie chicken, 254
—Rails, 241
— Sanderling, 151
— Sandpiper:
least, 151

semipalmated, 151
solitary, 271
spotted, 752, 270, 271
—Shrike, 229
—Sparrow:

chipping, 229
grasshopper, 254
song, 229
vesper, 254
—Swallow:

bank, 156, 265
rough-winged, 265
tree, 156

— Tanager, scarlet, 220
— Thrush:

hermit, 270
Wilson's, 270
wood, 166, 220, 270
—Turnstone, 151
— Vireo, red-eyed, 220
— Warbler :

black and white creeping, 166, 220
black-throated green, 159
pine, 159
yellow, 166, 220
— Whippoorwill, 269
— Willet, 151
— Woodpecker :
downy, 159
hairy, 159
red-headed, 166
—Wren:

marsh, 240
nest, 242

Black oak association, 115, 132
Bladderwort, Utricularia vulgaris
Bladderwort-milfoil ponds, 179
Blazing star, Liairis
Bloodroot, Sangninaria canadensis
Bloodworm ponds, 1 79
Blow-out, 14. 141
Bluebell, Campanula rotundifolia
Blue Island, 36, 78, 83, 85, 86
Bluffs, lake shore, 2, 259, 260
Boneset, Eupatorium perfoliatum
Braiderwood, 13
Breccia, 70

Bronze tiger association, 150, 157, 163
Brown-eyed Susan, Rudbeckia hirta
Bugs, see Hemiptera
Bugseed, Corispermum hyssopifollum
Bulrush, Scirpus

INDEX

Bulrush zone, 237
Bur reed, Sparganum eurycarpum
Butter and eggs, Linaria vulgaris
Butter-cup, water, Ranunculus aquatilis
Butterflies, see Lepidoptera
Butterfly weed, Asdepias tuberosa

Caboma, 103

Cactus, Opuntia Rafinesquii

Caddis fly: Leptocera, 175; net-
building, see Hydropsyche

Caddis worm, Goer a, 169

Calcite, 77

Calumet stage of Lake Chicago, 82, 83

Canadian period, 46, 47

Canon Diablo, 23, 24

Cardinal flower, Lobelia cardinalis

Carrot, wild, Daucus carota

Cassandra zone, 198

Cat-tail, Typha

Cat-tail zone, 238

Caves, 10

Cenozoic, 30, 31

Chalcopyrite, 72

Champlain Sea, 88

Chalk, 71

Chara ponds, 1 79

Checkerberry, Gaultheria procumbens

Cherry, ground, Phy sails

Cheveril, Anthricus cerefolium

Chicago: Lake, see Lake Chicago;
site of, 50, 52, 57, 64, 88

Chickweed, Stellaria aquatica

Chirotenetes siccus May-fly, 289

Chlorite, 71

Cicada, see Hemiptera

Cicely, sweet, Osmorhiza Claytoni

Cinquefoil: beach, Potentillacanadensis;
shrubby, P. fruticosa; silver, P.
Anserina

Clams, distribution of, 279

Clams (Pelecypoda) :

— Alasmodonta marginata, 169, 770, 171

—Anadonta grandis, 169, 170, 171

—Lampsilis luteola, 169, 770, 171, 234

— Sphaerium simile, 184, 184

Clay pinnacles, 10

Clearweed, Pilea pumila

Cleavage, 69, 770

Climax forest, 202

Closed gentian, Gentiana Andrewsii

Clover:

— Bush, Lespedeza capilata

— Prairie, Petalostemum purpureum

—White sweet, Melilotus alba

Coal beds, 5 1

Cocklebur, Xanthium echinatum

Coleoptera, Beetles:

— Alaus oculatus, eyed elater, 219

— Balaninus, nut weevil, 223

— Boletotherus bifurcus, fungus beetle,
219, 220

— Buprestidae, metallic wood-boring
beetles, 158, 219

— Calloides nobilis, 225, 226

— Calosoma:

calidum, the fiery hunter, 153, 753
scrutator, the searcher, 153, 753

— Chalcophora liberta, metallic wood-
borer, 158, 159

— Chalepus:
nervosa, 223
rubra, 223

— Chrysobothris femorata, flathead apple-
tree borer, 226

— Cidndela:

ancocisconenses, sphagnum tiger

beetle, 149, 201
cuprascens, copper tiger beetle, 148,

M9, 153
formosa generosa, large tiger beetle,

148, 149, 158
hirlicollis, 148, 149
lepida, white tiger beetle, 148, 149,

limbalis, clay bluff tiger, 149, 260
re panda, 149, 149
'scutellaris lecontei, bronze tiger

beetle, 148, 149, 158
sexguttata, green tiger beetle, 149,

149

tranquebarica, 149

—Cicindelidae, tiger beetles, 148, 149
— Diaperis maculata, fungus beetle, 219,

220

— Disonycha quinquemttata, 154, 755
— Dytisctis, diving beetle, 104, larva,

186, 1 88, 239

— Elaphidion villosum, 223
— Elateridae, click beetles, 219
— Eupsalis minuta, oak borer, 227, 228

3H

NATURALIST IN THE GREAT LAKES REGION

Coleoptera, Beetles — Continued

— Galerites janus, yellow-legs, 153

— Galetucella luteola, 223

— Graphisurusfasciatus, 225, 226

— Gyrinus, whirligig beetles, 105, 186,187

— Hydrophilidae, water- scavenger

beetles, 186, 239
—Lacon rectangularis, 161
— Liophus alpha, 226
— Meracintha contracta, darkling beetle,

228

— Molorchus bimaculatus, 225, 226
— Monohammus scutellatus, a long-horn

beetle, 158, 159

— Nyctobates pennsylvanica, 228
— Oncideres cingulatus, hickory girdler,

222

— Parandra brunea, heartwood borer,

227, 227
— Passalus cornutus, horned Passalus,

219, 220, 227, 228
— Pisenus humeralis, fungus beetle,

219, 220
— Plectrodera scalator, cotton wood borer,

156

— Prasocuris phellandrus, 161
— Psephenus lecontei, brook beetle, 287,

289
— Saperda:

later alls, 226

tridentata, elm borer, 224, 225

vestile, 226

— Sphenophorus, snout beetles, 155
— Stenosphenius tenebrioides, 228
— Tetraopes tetraophthalmus, milkweed

beetle, 230
— Tymnes:

matasternalis, leaf beetle, 223

tricolor, leaf beetle, 223
— Uloma impressa, darkling beetle, 228
— Xanthonia zo-notata, 223
— Xylopinus saperdioides, 227
— Xylotrechus colonus, rustic borer, '2 24,

225

Columbine, Aquilegia canadensis
Compass plant, Silphium laciniatum
Coneflower, Brauneria purpurea
Conglomerate, 71
Continents, 41
Corals, 49, 50
Corn plant association, 108
Corn root aphis, 108
Cotton-boll weevil, 301
Cottonwood association, 115, 120, 122

Cress, bitter, Cardamine

Crickets, see Orthoptera

Crustaceans:

— Acroperus, 290

— Asellus, the water sow bug, 93, 94

— Cambarus:

dio genes, 252

gracilis, 252, 254

virilis, crayfish, 234
— Canthocampus, 93, 290
— Cyclisticus convexus, sow bug, 218
— Cyclops, 93, 94, 290
— Cypris marginata, 93, 94
— Daphnia, 93, 94, 290
— Eubranchipus serratus, the fairy

shrimp, 92, 93
— Eucrangonyx gracilis, bender or scud,

178
—Gammarus fasciatus, the 'bender, 93,

177

— Hyalella Knickerbocker i, bender, 777
— Leptobora, 290
— Palaemonetes palndosus, the shrimp,

— Porchellio rathke, sow bug, 218
Crystal, 68

Culver's root, Veronica virginica
Cup plant, Silphium perfoliatum

Dalles of the Wisconsin, 6, 7

Damsel fly, see Odonata

Damsel-fly nymph, 105, 186

Delwood Park, 10

Deposition, 15; of river, 16

Desplaines River, 3, 66, 80, 83

Desplaines Bay, 80, 83

Devonian period, 33, 38, 50, 55, 58

Diabase, 75

Difflugia, 290

Digger wasp association, 150, 154, 156,

163

Diorite, 75, 76
Diptera, Flies:

— Chironomus, a midge, 175, 287
— Corethra, 290
— Culex, mosquito, 104, 187
— Exoprospa, bee fly, 154
— Simulium, black fly, 186, 287
Distribution of plants and animals,

factors determining, 90
Dobson, larva of Corydalis cornuta, 186

INDEX

315

Dolomite, 72

Dragon flies, distribution of, in streams,

280

Dragon fly, see Odonata
Dragon, green, Arisaema dracontium
Dunes, 13, 112, 123, 150; formation of,

13, 112, 114, 116, 122; plants of,

tabulation, 144-47; rate of advance

of, 13

DuPage River, 67
Dutchman's breeches, Dicentra cucul-

laria
Dyke, 39, 40

Earth: crust of, 17, 29; heat of, 25;

origin of, 22, 25
Earth worm, 165
Erosion: agents of, 2, 27; amount of,

4i
Eskers, 68

Feldspar, 72

Ferns:

— Adiantum pedatum, maidenhair fern,

210, 213
— Aspidium:

cristatum, 199, 200, 247
marginale, margined fern, 210, 213
novdboracense, pale wood fern, 210,

213

spinulosum, florist's fern, 210, 213
Thelypteris, marsh fern, 195, 198
— Asplenium:

acrostichoides, wood spleenwort,

210, 213

angustifolium, spleenwort, 100
Filix-femina, lady fern, 210, 213
— Comptosorus rhizophyllus, walking

fern, 266, 269
— Cystopteris:

bulbifera, bladder fern, 264, 265
fragilis, fragile fern, 100, 264
— Onoclea:

sensibilis, sensitive fern, 179, 180,

221

struthiopteris, ostrich fern, 210, 213
— Osmunda:

Claytoniana, Clayton's fern, in-
terrupted fern, 180, 181, 182, 221,
270
cinnamomea, cinnamon fern, 180,

182, 182, 200, 221, 270
regalis, royal fern, 180, 181, 182,
200

— Pellaea atropurpurea, purple-stemmed

cliff brake, 265
— Phegopteris polypodioides, beech fern,

210, 213
— Polopodium mlgare, rock polypody,

268, 269
— Polystichium acrostichoides, Christmas

fern, 210, 213
— Pteris aqmlina, bracken fern, 211,

214, 221

Fish:

—Bass:

black, large-mouthed, Micropterus

salmoides

black, smallTmouthed, M . dolomieu
rock, Ambloplites rupestris

— Bluegill, Lepomis pallidus

—Bullhead:

black, Ameiurus melas
spotted, A. nebulosus

—Cat:

mud, Leptops oliiiaris
stone, Notorus flavus
tadpole, Schilbeodes gyrinus

— Chub, river, Hybopsis kentuckiensis

— Crappie, black, Pomoxis sparoides

—Dace:

black-nosed, Rhinichthys atronasus
horned, Semotilus atromaculatus
red-bellied, Chrosomus erythro-
gaster

—Darter:

banded, Etheostoma zonale
black-sided, Hadropterus aspro
fantail, Etheostoma flabellare
Johnny, Boleosoma nigrum
rainbow, Etheostoma coeruleum
sharp-headed, Hadropterus phoxo-
cephalus-

— Dogfish, Amia caha

— Miller's thumb, Coitus ictalops

— Minnow:

blunt-nosed, Pimephales notatus
Cayuga, Notropis^ cayuga
mud, Umbri limi
red-faced, Notropis rubrifrons
red fin, N. lutrensis
straw-colored, N. blennius
sucker-mouthed, Phenacobius mira-

bilis
top, Fundulus dispar

— Perch, yellow, Perca flavescens

—Pike:

Esox lucius

grass or small pickerel, E. vermicu-
latus

316 A NATURALIST IN THE GREAT LAKES REGION

Fish — Continued

— Pumpkin seed, Eupomotis gibbosus

— Redhorse, Moxostoma aureolum

— Sculpin, Cottus ictalops

— Shad, gizzard, Dorosoma cepedianum

— Shiner :

Notropis atherinoides

common, N. cornutus

golden, Abramis crysoleucas
— Silversides, brook, Lapidesthes sic-

culus

— Stone roller, Campostoma anomalum
— Sucker:

chub, Erimyzon sucetta

common, Catostomus commersonii

hog, C. nigricans '
Fish:
— Abramis crysoleucas, golden shiner,

174, 175, 284

— Ambloplites rupestris, rock bass, 284,

285
— Ameiurus:

melas, black bullhead, 184, 284

nebula sus, spotted bullhead, 174, 176
— Amia calva, dogfish, 284
— Boleosoma nigrum, Johnny darter,

234, 282, 283
— Campostoma anomalum, stone roller,

283, 284
— Catostomus:

commersonii, common sucker, 283,
284

nigricans, hog sucker, 284
— Chrosomus erythrogaster, red-bellied

dace, 282, 283

— Cottus ictalops, blob, sculpin, 234
— Dorosoma cepedianum, gizzard shad,

284
— Erimyzon sucetta, chub sucker, 174,

175, 284
— Esox:

lucius, pike, 168, ///, 172
•vermiculatus, grass pike, 284

— Etheostoma:

coeruleum, rainbow darter, 282,

283, 285

flabellare, fan-tailed darter, 285, 286
zonale, banded darter, 284, 285

— Eupomotis gibbosus, pumpkin seed,
173, 234, 284

— Fundulus dispar, striped top minnow,
239, 284

— Hadropterus:

aspro, black-sided darter, 285, 286
phoxocephalus, sharp-headed darter,
286, 287

— Hybopsis kentuckiensis, river chub, 284

— Lapidesthes sicculus, brook silver-
sides, 284

— Lepomis pallidus, bluegill, 173, 234,
284

— Leptops olivaris, mud cat, 284

— Micropterus:

dolomieu, small-mouthed black

bass, 234, 284

salmoides, large-mouthed black
bass, 234, 284

— Moxostoma aureolum, red horse, 168,
284

— Notropis:

atherinoides, shiner, 772, 172
blennius, straw-colored minnow,

234, 284, 285
Cayuga, Cayuga minnow, 168, 171,

172
cornutus, common shiner, 169, 171,

.284

lutrensis, redfin, 284
rubrifrons, red-faced minnow, 284

— Notorus flavus, stone cat, 284

— Perca flavescens, yellow perch, 234,
284

— Phenacobius mirabilis, sucker-
mouthed minnow, 285, 286

— Pimephales notatus, blunt-nosed min-
now, 234, 282, 283

— Pomoxis sparoides, black crappie, 234,
284, 285

— Rhinichthys atronasus, black-nosed
dace, 283

— Schilbeodes gyrinos, tadpole cat, 174,
/75,. 176, 284

— Semotilus atromaculatus, horned dace,
281, 283

— Umbri limi, mud minnow, 174, 174,
185, 284

Fish, distribution of, in streams, 283

'Fishes: •

— Age of, 50

—Fossil, 50

Flag, sweet, Acorus Calamus

Flathead, 67

Flies, see Diptera

Floating sedge zone, 196

Floed plain, 17, 272

Flowering plants (see also Vines, Shrubs,
and Trees; for common names see
General Index) :

— Acer ales viridiflora, green milkweed,
117, //p, 132

INDEX

317

Flowering Plants- — Continued

— Acorus Calamus, sweet flag, 238, 239

— Actaea:

alba, white baneberry, 210, 210, 211

rubra, red baneberry. 210
— Agrostis perennans, thin grass, 244,

246

— Allium cernuum, wild onion, 248, 250
— -Ammophila arenaria, marram grass,

119, 120
— Amorpha canescens, lead plant, 250,

254

— Anacharis, 103
— Andropogon jurcatus, prairie grass,

245, 247, 249
— Anemone cylindrica, thimble weed,

132, J33, 134

— Anemonellathalictr aides, anemone, 92
— Angelica atropurpurea, angelica. 266,

268
— Aquilegia canadensis, columbine, 132,

133, 209, 264, 269

— Arabis lyrata, rock cress, 132, 134, 135
— Aralia nudicaulis, sarsaparilla, 264,

267, 269

— Arethusa bulbosa, 194, 197, 198
— Arisaema:

dracontium, green dragon, 209, 210

triphylhim, Jack-in-the-pulpit, 208,

209
— Artemisia caudata, wormwood, 117,

118
— Asarum canadense, wild ginger, 209,

275
— Asclepias:

cornuta, common milkweed, 106
incarnata, swamp milkweed, 197
syriaca, common milkweed, 229
tuber os a, butterfly weed, 132, 135,

137, 249

— Aster junceus, 199, 200
— Bidens:

frondosa, beggar-ticks, 249

purpurea, 237

— Brasenia Schrebcri, water shield, 196
— Brauneria piirpurea, cornflower, 249,

251

— Caboma, water moss, 103
— Cakile edentula, sea rocket, 115, ii7>

118
— Calamagrostis canadensis, blue-joint

grass, 244, 246
— Calamovilfa longifolia, sand reed grass,

119, 120
— Calapogon pidchellus, grass pink, 194,

197
— Caltha palustris, marsh marigold, 179,

274

— Cammasia esculenla, vrild hyacinth,

248, 249
— Campanula:

aparinoides, marsh bellflower, 197

rotundifolia, bluebell, 124, 126, 128,

264, 269
— Carex:

aquatilis, 246

conjuncta, 244, 246

cristata, 244, 246

filiformis, 193, 196

lupuliformis, 244, 246

riparia, 193, 197, 246

stricta, 244, 246
— Cardamine:

bulbosa, bitter cress, 247, 248

Douglassii, 247

pennsyhanica, 247
—Castalia tuberosa, white water lily,

179, 196

— Castilleja cocdnea, painted cup, 183
— Cerastium mdgatum, chickweed, 247,

248
— Ceratophyllum demersum, hornwort,

103, 178, 236
— Chaerophyllum procumbens, cheveril,

273, 274
— Cirsium:

arvense, Canada thistle, 228, 260

lanceolatum, spear or bull thistle,
228

Pitcherii, sand thistle, 118, 119

pumilum, pasture or prairie thistle,

249
— CJaytonia virginica, spring beauty, 91,

92, 209

— Comandra umbellata, bastard toad-
flax, 132, 133, 134, 264
-Coreopsis grandi flora, tickseed, 195,

197
— Corispermum hyssopifolium, bugseed,

117, 118

— Crotalia sagittalis, rattlebox, 266, 269
— Cryptotaenia canadensis, honewort,

273, 275

— Cydoloma atriplicifolium, winged pig-
weed, 117, 119
— Cypripedium parmflorum, yellow

lady's-slipper, 138, 141
— Daucus carota, Queen Anne's lace,

wild carrot, 266, 268
— Dentaria laciniata, toothwort, 91, 92,

209
—Dicentra cucullaria, Dutchman's

breeches, 91, 92, 209
— Dodecatheon meadia, shooting star,

247, 249
— Draba caroliniana, whitlow grass,

266, 269

318 A NATURALIST IN THE GREAT LAKES REGION

Flowering Plants — Continued

— Droserarptundifolia, sundew, 195, 197

— Eleocharis acicularis, spike rush, 235,

238

— Elodea, water weed, 236
— Elymus canadensis, rye grass, 117, ng
— Eriophorum gracile, cottony grass,

195, 197, 198
—Eryngium yuccifolium, 249, 253

— Erythronium americanum, yellow

adder's tongue, 91, 92, 209
— Eupatorium perfoliatum, boneset, 266,

268
— Euphorbia:

corollata, flowering spurge, 132, 135,
136

polygonifolia, seaside spurge, 117,

119, 120
— Galium aparine, bedstraw, 210, 210,

212
— Gautheria procumbens, checkerberry,

124, 126
— Gentiana Andrews?!, closed gentian,

107 _
— Geranium:

carolinianum, wild geranium, 132,
135, 136

maculatum, wild geranium, 136,

138, 140, 141

: — Glyceria nervata, 244, 246
— Habenaria lacera, the ragged orchis,

196, 198

— Hepatica triloba, hepatica, 92, 138,

140, 142, 209, 267

— Heucheraamericana, alumroot,266, 269
— Hieracleum lanatum, cow parsnip,

273, 275
— Hydrophyllum mrginianum, water

leaf, .310, 210, 2/7
— Hypericum Kalmianum, St. John's-

wort, 124, 126, 129
— Impatiens:

biflora, touch-me-not, 100, 210, 212

pallida, 212

— Iris versicolor, blue flag, 101, 182
— Juncus: bog rush

balticus, 235, 238

canadensis, 235, 237

ejjusus, 235

tennis. 235
— Lactuca scariola, wild lettuce, 101,

249
— Lathyrus maritimus, beach pea, 117,

118

— Lemna minor, duckweed, 234
— Lespedeza capitata, bush clover, 132,

135, I3S

— Liatris:

cylindrica, blazing star, 137

scariosa, blazing star, 737

spicata, blazing star, 137, 249
— Linaria vidgans, butter and eggs,

toad flax, 107
— Lithospermum canescens, puccoon,

124, 126, 129

— Lobelia cardinalis, cardinal flower, 248
— Lupinus perennis, lupine, 132, 134,

134
— Maianihemum canadense, false lily-

of-the-valley, 124, 127, 128, 264
— Melilotus alba, white sweet clover,

260
— Monarda:

fistulosa, wild bergamot, 132, 136,
137

punctata, horse mint, 124, 126, I2g
— Myriophyllum hctcrophyllitm, mil-
foil, 102, 103, 168, 178, 197, 236
— Nymphaea advena, yellow water lily,

179, 196.
— Opuntia Rafinesquii, cactus, 98, 99,

132
— Osmorhiza Claytoni, sweet cicely,

210, 210, 212
— Panax trifolium, ginseng, 210, 211,

212
— Panicum virgatum, switch grass, 244,

246

— Parnassia caroliniana, grass of Par-
nassus, 183
— Pastinaca saliva, wild parsnip, 266,

268
— Pedicularis canadensis, lousewort,

wood betony, 132, 135, 757, 267
— Petalostemum purpureum, prairie

clover, 250, 254
-Phlox:

divaricata, wood phlox, 209, 274

pilosa, hairy phlox, 124, 72p, 249,

252

— Phragmites communis, reed, 238, 239
— Physalis, ground cherry, 229
— Pilea pumila, clearweed, 100, 210,

210, 272

— Poa triflora, prairie grass, 247

— Podophyllum peltatum, May apple,

138, 740, 142, 228
— Polygonatum bifiorum, Solomon's seal,

124, 210
— -Polygonum:

lapathifolium, smart weed, 246, 248

persicaria, 248
— Potamogeton, pond weed, 178, 235,

236

INDEX

319

Flowering Plants — Continued

— Potentilla:

Anscrina, cinquefoil, 117, 118
canadensis, beach cinquefoil, 118
frulicosa, shrubby cinquefoil, 1^3,184

— Prenanthes alba, rattlesnake root,
138, 140, 142, 264, 269

— Proserpinaca palustris, mermaid
weed, 247, 248

— Ranunculus aquatilis, water buttercup,
102, 236

— Rudbeckia hirta, brown-eyed Susan,
248, 251

— Sagittaria latifolia, arrowhead,237, 238

— Sanguinaria canadensis, 92, 209

— Sarracenia purpurea, pitcher plant,.
198, 199

— Saxifraga pennsyhanica, swamp saxi-
frage, 178, 1 80

— Scirpus: bulrush or club rush
atrovirens, 235, 237
Torreyi, 235, 237
validus, 235, 237

—Scutellaria galericulata, skull cap, 247,
248

— Silphium:

laciniatum, compass plant, 101
perfoliatum, cup plant, 107, 108
terebinthinaceum, rosinweed, 249, 252

— Sisyrinchium angustifolium, blue-eyed
grass, 124, 128, 182

— Smilacina racemosa, false Solomon's
.seal, 124, 128, 129

— Sparganium eurycarpum, bur reed~,
237, 238

— Spartina Michauxiana, slough grass,
244, 246

— Spiranthes Romanzoffiana, fragrant
ladies'-tresses, 197, 198

— Sporobolus cry ptandrus , 249, 252

— Steironema ciliatum, fringed loose-
strife, 273, 275

— Symphocarpus foetidus, skunk cab-
bage, 273, 274

— Tephrosia mrginiana, hoary pea, 132,
134, 135

— Thaliclnum dasycarpum, meadow rue,
266, 267

— Tradescantia virginica, spiderwort,
132, 133, 134, 269

— Trientalis americana, star flower, 124,
127, 128

—Trillium:

grandiflorum, trillium, 92, 209
recnrvatum, red or purple trillium,
92, 209

— Typha:

angustifolia, narrow-leaved cat- tail,
101

latifolia, cat-tail, 101, 238
— Utricularia vulgaris, bladderwort,

102, 103, 178, 236
— Uvularia grandiflora, bellwort, 124,

126, jjo

— Vattisneria, tape grass, 236
— Verbascum Thapsus, mullein, 119, 720
— Veronica virginica, Culver's root, 248,

250
—Viola:

blanda, white violet, 179, 248

canadensis, Canada violet, 138,
140, 142, 209

palmata, wood violet, 209

pedata, bird's-foot violet, 132, 135

pedatafida, 248

rostrata, long-spurred violet, 138,
140, 142, 209

sagittata, arrow-leaved violet, 132,

135, 182

— Xanthium echinatum, cocklebur, 118
— Xyris caroloniana, yellow-eyed grass,

182

— Zizania aquatica, wild rice, 237, 238
— Zizia aurea, golden old man, 248, 250
Fold of rock in Illinois, 52, 54
Food supply and distribution, 106
Fore-dune association, 115, 119
Forest margin association, 228, 261
Forest succession, 202
Fossils, 28, 49, 51, 53
Frost, 27
Fracture, 70
Fraction Run, 3, 8
Frog, hibernation of, 105
Frogs, see Amphibians
Frogs' eggs, 94

Gabbro, 75, 76

Galena-Platteville limestone, 34, 38, 46,

52, 54

Galenite, 68, 71
Galls of oak, 163, 164
Gentian, Gentiana Andrewsii
Geologic ages, 30
Geranium, wild, Geranium carolinia-

num; G. maculatttm
Ginger, wild, Asarum canadense
Ginseng, Panax trifolium

320 A NATURALIST IN THE GREAT LAKES REGION

Glacial drift, 63, 64, 68; thickness of, 63

Glacial bowlder, 60

Glacial periods, 5 7

Glacial period, origin of, 56

Glacial striae, 60, 61

Glacier, 9, 19, 20, 56; thickness of, 62

Glencoe, 4, 1 1

Glenwood stage of Lake Chicago, 79, 81

Golden old man, Zizia aurea

Gopher, see Mammals

Granite, 75, 76

Grape, wild, see Vines

Grass:

— Blue-eyed, Sisyrinchiutn angustifolium

— Blue joint, Calamagrostis canadensis

— Cottony, Eriophorum gracile

— Dropseed, Sporobolus cryptandrus

— Fowl meadow, Glycera ntrvata

—Goose, Potentilla Anserine

— Marram, Ammophila arenaria

— Of Parnassus, Parnassia caroliniana

— Prairie :

A ndropogon furcatus

Poa triflora

— Rye, Elymos canadensis
— Sand reed, Calamovilfa longi folia
— Thin, Agrostis perennans
— Switch, Panicum virgatum
— Whitlow, Draba caroliniana
— Yellow-eyed, Xyris caroliniana
Grasshopper, see Orthoptera
Green dragon, Arisaema dracontium
Gypsum, 71

Hardness of minerals, 70
Hematite, 72

Helicopsyche, caddis fly, 287, 188
Hemiptera, Bugs:

— Arctocorixa interrupta, water boat-
man, 187, 188, 239

— Belostoma, lesser waterbug, 186, 188
— Benacus griseus, giant waterbug, 104,

186, 188, 239

— Cicada linei, cicada, 212, 221, 222, 224
— Gerris remigis, water skater, 187
— Gelastocoris oculatus, toadbug, 269,

271

— -Hydrometria, marsh strider, 187
—Notonecta undulata, back swimmer,

187, 1 88

— Ranatra americana, water scorpion,
104, 187, 239

Hepatica, Hepatica triloba

Hexagenia, May- fly, 289

Honewort, Cryptotaenia canadensis

Hornwort, Ceratophyllnm dcmersum

Hound's tongue, Cyanoglossum officiniale

Hudson River Valley, 18

Hyacinth, water, Cammasia esculenta

Hydrophyte, 95

Hydropsyche, caddis fly, 286, 288

Hylodes association, 150

Hymenoptera, Ants, Bees, Wasps:

— Ammophila procera, digger wasp, 160

— Bembex spinolae, digger wasp, no

no, 154

— Camptonotus pennsyhanicus. car-
penter ant, 219, 227
— Formosa subpolitavar neogagatcs, ant,

— Lasius niger americanus, black ant,

158
— Microbembex monodonta, digger wasp,

iS3, 154

Ice, n

Igneous rocks, 25

Illinoian glacial period, 57, 62, 63

Illinois River, 8, 54

lowan glacial period, 57, 63

Iris, Iris -versicolor

Ischnura verticalis ponds, 179

Ivy, poison, Rhus toxicodendron

Jack-in-the-pulpit, Arisaema triphyllum
June beetle, 95

Kames, 67

Kansan Glacial Period, 57

Kaolin, 71

Katydid, see Orthoptera

Lady's-slipper, yellow, Cypripedium

parviflorum

Lake Chicago, 62, 78, 80, 81, 85
Lake Michigan, 58, 59
Lakeside, 10

Lamps His luteolus ponds, 179
Lava, 18, 19
Lead plant, Amorpha cancsccns

INDEX

321

Leming, Lapland, 298

Lepidoptera, Butterflies:

— Angle wings, 166, 230

— Cosmopolitan, 230

— Fritillary, 165, 230

— Hair-streak, Edward's, 166

— Monarch, 165, 230

— Mourning cloak, 166

—Nymph, wood, 165, 224, 230

— Painted lady, 230

—Red Admiral, 166

— Satyr, wood, 166, 224

— Swallowtail :

: giant, Papilio cresphontes, 222, 241
< pawpaw, P. ajax, 219, 221

spice bush, P. troilus, 166, 220, 221
tiger, P. turnus, 222

— Viceroy, 165, 230

Lepidoptera, Moths:

— Actias luna, lunar moth, 222

— Basttona imperials, imperial moth,

222

— Calosoma promethea, promethea moth,

222
— Catocala:

amatrix, sweetheart, 272

neogama, bride, 272

retecta, yellow-gray underwing,
222

vidua, widow, 222

— Cither onia regalis, royal moth, 222
— Cressonia juglandis, wahiut sphinx,

222

— Diacrisia virginica, yellow bear moth,
257, 258

— Estigmena acraea, salt-marsh cater-
pillar, 257, 258

— Feltia subgothica, dingy cutworm
moth, 257, 258

— Isia Isabella, Isabella moth, 258

— Prionoxystus robiniae, goat moth, 226

— Samia cecropia, cecropia moth, 222,
272

— Scolecocampa liburna, 228

— Telea polyphemns, polyphemus moth,
222

Lettuce, wild, Lactuca scariola

Light, as a factor in plant distribution,
zoo, 109

Light intensity in forests, 202

Lily-of-the-valley, false, Maianthemum
canadensis

Limestone, 45, 70

Limonite, 72

Lizard, six-lined, see Reptilia

Locust, see Orthoptera

Loosestrife, fringed, Steironema cili-

atum

Lousewort, Pedicularis canadensis
Lung fish, 105
Lupine, Lupinus perennis
Luster, 70

Magnesian limestone, 34, 36, 47, 54

Mammals :

— Blarina brevicaudata, short-tailed

shrew, 214, 274, 275
— Citellus:

franklini, Franklin's ground squir-
rel, gopher, or spermophile, 229,

2S3

tridecemlineatus, thirteen-lined
ground squirrel, gopher, or
spermophile, 252, 255
— Condylura cristata, star-nosed mole,

252

— Fiber zibethicus, muskrat, 241
— Geomys bursarius, pocket gopher, 253,

255
— Marmota monax, woodchuck, 165,

229, 230
— Microtus:

ochrogaster, field mouse, 253

pennsylvanicus, Pennsylvania

meadow mouse, 253, 254, 256
— Myotis lucifugus, brown bat, 227
— Peromycus:

bairdii, prairie deer mouse, 253

leucopus novaboracensis, white-
footed deer mouse, 214, 217, 275
— Scalopus aquaticus, mole, 165, 214,

217, 275
— Sciurus:

carolinensis leucotis, gray squirrel,
166

hudsonicus loquax, red squirrel, 159

niger rufiventer, fox squirrel, 166
— Sorex personatus, common shrew, 229
— Sylvilagus fioridanus mearnsii, gray or

cottontail rabbit, 229
— Tamias striatus griseus, chipmunk,

159, 229

— Zapus hudsonius, jumping mouse, 229
Maple-beech association, 115, 203, 206
Maquoketa shale, see Richmond shale
Marble, dolomitic, 40
Marsh marigold, Caltha palustris
May apple, Podophyllum pdtatum

322 A NATURALIST IN THE GREAT LAKES REGION

May-fly, 95; nymph, 186, 239
Meadow rue, Thalictrium dasycarpum
Meadow-sweet, see Shrubs
Mermaid weed, false, Proserpinaca

palustris
Mesophyte, 96
Mesozoic, 30, 31
Meteorite, 23
Meteors, 23
Mica, 71

Millipede, see Myriopoda
Milfoil, Myriophyllum heterophyllum
Milkweed, Asclepias
Milkweed, green, Acerates mridiflora
Minerals, 68, 69; table of, 71-73
Minooka Ridge, 64
Mint, horse, Monarda punctata
Mixed oak association, 115, 165
Monadnock, 40
Moons, 21
Moon, craters of, 25
Moraine: ground, 63; terminal, 19, 20,

61, 62, 64, 65, 66; Valparaiso, 78
Morris basin, 62, 66
Mosquito larvae, 104
Moths, see Lepidoptera
Mount Forest Island, 64, 78, 83, 85, 86
Mullein, Verbascum Thapsus
Myriopoda, Centipedes and Millipedes :
— Fontaria corrugate, 218, 218
— Geophilus rubens, 218
— Lithobius, 224
— Lysiopetalum lactarhim, 218
— Polydesmus, 224
— Spirobolus marginatus, 218

Nebula, 25

New Buffalo, 4

Niagara limestone, 33, 36, 38, 44, 47, 58

North America, beginnings of, 41

Oak-hickory association, 115, 221

Odonata, Damsel flies:

— Ischnura verticalis, 177, 177

— Lestesjorcipatus, i6g, 169, 170, 770

Odonata, Dragon flies:

— Aeschna, 184, 281

— Aescfanidae, 281

— Agrionidae, 280

— Anaxjunius, 184, 185, 239, 281

— Boyeria, 184, 281

— Calopterygidae, 280

— Celethemis eponina, i6p, 170

— Cordulegaster obliquus, lance-head

dragon fly, 269
— Cordidegasteridae, 281
— Diastatomma, 281
— Dromogomphus, 281
— Epicordulia, 282
— Gomphidae, 281
— Gomphus spicatus, 174, 174, 185, 239,

282

— Hagenius, 281
—Leucorhinia inlacla, 185, 185
—Libellula piilchella, 185, 188, 23^
— Libellulidae, 281, 282
— Macromia, 282
—Progomphus, 281
— Somatochlora, 283
— Tetragoneuria, 283
— Tramea lacerta, i6g
Oceans, origin of, 27
Olivine, 73

Onion, wild, Allium cernuum
Orchids:

— Arethusa bulbosa
— Grass pink, Calopogon pidchellus
— Ladies'-tresses, Spiranthes Roman-

zoffiana

— Ragged, Habenaria lacera
— Yellow lady's-slipper, Cypripedit n

parviflorum

Ordovician period, 34, 38, 46, 48
Orthoptera:
— Ageneotettix arenosus, sand locutt,

157, 15^
— A mblycorypha:

oblongifolia, oblong-wing katydid,
231, 241

rotimdifolia, round-wing katydid,

224, 231
— Anoxipha exigua, small brown cricket,

201
— Ccuthophilus maculatus, camel cricket,

224, 225
— Chloealtis conspersa, sprinkled locust,

162, 163, 231
— Conocephalus:

ensiger, sword-bearing grasshopper,
163

palustris, marsh conehead, 190, 192
— Cyrtophillus perspicillatus, katydid ,

222
— Diapheromera femorata, common

walking stick, 166

INDEX

323

Orlhoptcra- — Continued

— Dicromorpha viridis, short-winged

green locust, 190, 191, 192
—Dissosteira Carolina, Carolina locust,

' 261
— Hippisais tuberculatus , coral-winged

locust, 162, 163
— Ischnoptera pennsyhanica, cockroach,

218

— Leptysma marginicollis, slender-
bodied locust, 190, 191
— Mecostethuslineatus, striped locust, 201
— Melanoplus:

angustipennis, narrow-winged lo-

(i cust, 157, 158

atlanis, lesser migratory locust,

1^7, JS7
bimttatus, two-lined grasshopper,

255, 256

blatchleyi, Blatchley's locust, 219
extremis, northern locust, 201
femur-rubrum, red-legged locust,

255) 256

scudderi, short-winged locust, 231
•viridipes, green-legged locust, -219,

256
—Nemobius:

fasciatus, striped ground cricket,
, .. 190, 192, 1 93

palnstns, marsh ground cricket, 201
— Oecanthus:
u angustipennis, tree cricket, 166,

222, 231

fasciatus, 222, 231
latipennes, 222
nivens, 222, 231
?' quadripunctatus, 222
— Orchelmium mdgare, meadow grass-

, hopper, 256
—Paratettix cucullatus, hooded grouse

, locust, 269, 271
— Paroxya:

/z0<m'm,Hoosier locust, 190, 191,192
scudderi, Scudder's paroxya, 190,

191, 192

— Phaelaliotes nebrascensis, Nebraska
locust, 190, 192, 193

—Psinidia fenestralis, long-horned lo-
cust, 156, 157, 158

— Schistocerca:

alutacea, leather-colored locust, 162,

192, 193

' rubiginosa, rusty locust, 162
—"-Scudderia:

furcata, forked- tailed katydid, 224,

243
texensis, Texan katydid, 241, 243

— Sparagemon wyomingianum, mottled

sand locust, 156, 158
— Stenobothrus curtipennis, short-winged

brown locust, 201
— Telligidea:

armata, grouse locust, 188

granulatus, 190

lateralis, 188, 190

parvipennis, 188, 255

pennata, 255
— Trimerotropis maritima, maritime

locust, 156, 156
— Tryxalis brevicornis, 190, 191
— -Xiphidium:

brevipenne, short-winged grass-
hopper, 255, 256, 271

ensiferum, sworded grasshopper,
231

fasciatum, 255

nemorale, woodland grasshopper,
231

nigropleura, black-sided grass-
hopper, 241

strictwn, straight-lanced grass-
hopper, 163, 256

saUans, glade grasshopper, 256
Oxygen, a factor in distribution, 106

Painted cup, Castilleja coccinea
Palaeozoic, 30, 31, 51
Paleontology, 28
Panne, 114, 115
Parsnip :

— Cow, Heracleum lanatum
— Wild, Pastinaca saliva
Pea:

—Beach, Lat hyrus maritimus
. — Hoary, Tephrosia virginiana
Pennsylvanian period, 32, 38, 51, 54
Peridote, 75
Phlox:

— Hairy, Phlox pilosa
— Wood, P. divaricata
Pigeon berry, see Shrubs, Cornus

canadensis
Pigweed, winged, Cycloloma atriplici-

folium

Pine association, 115, 124
Pitcher plant, Sarracenia purpurca
Planarians, 291
Planets, 21, 25
Planetesimal hypothesis, 22

324

A NATURALIST IN THE GREAT LAKES REGION

Plankton, food of fish, 109
Platteville-Galena limestone
Polyzoan, Pectinclla magnified, 240
Ponds: filling of, 15, 16, 167, 232; in

dunes, 167, 179; first type, 168, 179;

second type, 182, 183; third type,

179, 193, 194

Ponds, temporary, life of, 92
Pondweed, Potamogeton
Porphyry, 74
Pot holes, 86

Potsdam formation, 46, 47
Prairie, 179, 242, 245
Predatory beetle association, 150
Preglacial river system, 58
Proterozoic, 30, 31, 41
Puccoon, Lithospermum canescens
Pyrite, 72
Pyroxene, 72

Quarries, 36, 37, 45

Quartz, 68, 69, 73

Quartzite, 40

Queen Anne's lace, Daucus Carota

Rabbit, wild, see Mammals
Railroads, routes determined by, 88
Rain, an erosion agent, 11,27
Rainfall, effect on plant distribution, 95,

96, 97

Rattlebox, Crotalia sagittalis
Rattlesnake master, Eryngium yucci-

folium

Rattlesnake root, Prenanthes alba
Ravine: clay, 4, 259; formation of, 3,

5, 6, 261; rock, 6, 7, 263
Reptilia, Snakes, Turtles:
— Aromochelys odorata, musk turtle,

178, 239
— Aspidonectes spinifer, soft-shelled

turtle, 239
— Chelydra serpentina, snapping turtle,

240
— Chrysemus marginata, painted turtle,

239, 240
— Cnemidophorasexlineatus, sand lizard,

99, 160, 161
— Coluber constrictor, blue racer, 161

— Graptcmys geographicus, geographic
turtle, 239

— Helerodon platirhinos, hog-nosed
snake, 162

— LeiopcUis vernalis, prairie green snake,

255
— Thamnophis radix, prairie garter

snake, 255

Rice, wild, Zizania aquatica
Richmond shale, 34, 38, 47, 52, 58
Rivers, action of, 3, 27
River bottom association, 271
Rock: dumps, 12

Rocks, 68; Chicago region, 38, 43; earli-
est, 25, 29, 39; igneous, 73; forma-
tion, 17, 28, 44; metamorphic, 39,
40, 76; Plutonic, 73; sedimentary,
17, 28, 29, 70; systems of, 31, 38;
table of, 75; volcanic, 73
Rock River, 6, 54

Rosin weed, Silphium terebinthinaceum
Rotifers, 288

Rotting log association, 225
Rush, bog, Juncus, several species
Rush, spike, Eleocharis acicularis

Sag Station, 8, 78

St. John's-wort, Hypericttm Kalmianum

St. Peter's sandstone, 34, 38, 46, 54

Salt Creek, 3, 4, 83

Sandbars, 113

Sarsaparilla, Aralia nudicaulis

Sawfly, 257

Saxifrage, swamp, Saxifraga penn-
sylvanica

Schist, 4.0, 76

Sea rocket, Cakile edentula

Seas, epicontinental, 44

Seasonal distribution of plants, 92,
248

Sedges, see Carex
Sedimentation, 28
Serpentine, 71
Shale, 46, 76

INDEX

325

Shrubs:

— Andromeda polifolia, 198, 199

— Arctostaphylos Uva-tirsi, bearberry,

124, 125, 727
— Benzoin aestivalis, spice bush, 205,

207, 221

— Betida pumila, swamp birch, 199
— Cephalanthus occidentalis, button

bush, 177, 179, 241, 274
— Chamaedaphne calyculata, leatherleaf,

198, 199, 200
— Chimaphila umbellata, Prince's pine,

124, 126, 128
— Cornus:

alternifolia, alternate-leaved dog-
wood, 228

Amomum, silky dogwood, 241

canadensis, pigeon berry, 205, 209

paniculata, panicled dogwood, 228,
264

stolonifera, red-osier dogwood, 122,

123, 124, 183, 200, 241, 260
— Diermlla Lonicera, bush honeysuckle,

132, 133, 134

— Dirca palustris, leatherwood, 205, 209
— Ewnymus:

americana, strawberry bush, 205,

208, 20p, 274
atropurpureus, wahoo or burning

bush, 205, 207, 208, 274
— Gaultheria procumbens, checkerberry,

124, 126, 128, 180, 205
— Gaylussacia baccata, huckleberry, 132,

133, 134, 264

— Hamamelis iiirginiana, witch-hazel,

205, 206, 207, 221, 228, 270
— Hydrangea arborescens, 265, 267
— Ilex verticillata, swamp holly, 180,

181, 181
— Juniperus:

communis, common juniper, 124,
127

horizontalis, prostrate juniper, 114,

121, 124, 127
— Physocarpus opulifolius, ninebark,

264
— Prunus pumila, sand cherry, 119, 120,

121

— Pyrola elliptica, shinleaf, 124, 126, 128
— Pyrus arbutifolia, chokeberry, 198,

199
— Rhus:

canadensis, aromatic sumac, 124,

13°, J3i
copallina, dwarf sumac, 124, 130,

131
glabra, smooth sumac, 228, 264

typhina, staghorn sumac, 124, 130,

131, 228, 260, 264
vernix, poison sumac, 130, 131,

200
— Ribes:

florid-urn, black currant, 205
Cynosbati, prickly gooseberry, 205
— -Rosa acicularis, 129
blanda, 129
humilis, 129
virginiana, 200
— Salix:

glancophylla, broad-leaved willow,

J2o, 260

syrticola, furry willow, 119, 120, 122
— Sambmus canadensis, elderberry, 205,

208, 209, 274
— Spirea:

latifolia, meadow-sweet, 180, 181,

181
tomentosa, steeplebush, 180, 181,

181
— Staphylea trifolia, bladdernut, 273,

274
— Vaccinum:

macrocarpon, large cranberry, 198
pennsyhanicum, blueberry, 132,

264

oxycoccos, small cranberry, 198
— Viburnum:

acerifolium, maple-leaved vibur-
num, 205, 207, 241
lentago, nannyberry, 205, 207, 208,

228
opulus, high bush cranberry, 205,

207, 208
— Zanthoxylum americanum, prickly

ash, 241, 273, 274
Shooting star, Dodecatheon meadia
Shooting star, see Meteor
Silurian period, 33, 38, 47, 48
Siphlurus alternatus, May-fly nymph,
287

Skokie Bay, 81

Skokie Marsh, 81

Skunk cabbage, Symplocarpus Joeti-

dus

Skull cap, Scutellaria galericulata
Slate, 40
Slugs:

— Agriolimax campestris, 217, 218
— Pallifera dorsalis, 218
— Philomycus carolinensis, 216, 218
Smart weed, Polygonum

326 A NATURALIST IN THE GREAT LAKES REGION

Snails, aquatic:
— A mnicola:

dncinnaliensis, 175, 176, 233

emarginata, 233

limosa, 175, 176
• — Ancylus fuscus, 233, 288
— Campeloma:

integrum, 233, 289

ponderosum, 233

subsolidum, 233, 289
— Goniobasis livescens, 232, 233, 288
— Lymnaea:

desidiosa, 176, 777

humilis, 176

reflexa, 176, 188, 233

stagnates, 233

woodruffi, 233
— Physa:

gyrina, 175

heterostropha, 233
— Planorbis:

bicarinaius, 176, 177, 233

campanulatus, 176, 777, 188, 233

hirsutus, 176, 177

parvus, 176, 177, 1 88

trivolvis, 233
— Pleurocera:

elevatum, 232, 233

subulare, 232, 233
— Valvata tricarinata, 233
— Vivipara:

contectoides, 232, 233

subpurpurea, 233
Snails, terrestrial:
— Bifidaria armifera, 216
— Circinaria concava, 214, 216, 227, 269,

270

— Cochliocopa lubrica, 216
— Helicodiscus parallelus, 216
— Omphalina:

friabilis, 214, 217, 270

fuliginosa, 214, 216, 217, 227, 270
— Polygyra:

albolabris, 214, 215, 217, 226, 269,
270

clausa, 217, 270

fraudulenta, 214

fraterna, 270

hirsuta, 214, 215

injlecta, 270

monodon, 214, 216, 270

multilineatus, 215, 217, 270

oppressa, 214, 270

palliata, 214, 215, 270

pennsylvanica, 215, 2/7, 270

profunda, 165, 215, 217

thyr aides, 215, 2/7, 226, 269, 270

tridentata, 215, 216
— Pyramidula:

alternata, 214, 216, 2/7, 227, 269,
270

perspectiva, 214, 216, 2/7, 227, 270

solitaria, 214, 216, 2/7, 269, 270

striatella, 217
— Succinea:

avara, 216, 272

ovalis, 216, 272

retusa, 216, 272
— Vertigo ovata, 216
— Zonitoides arboreus, 165, 214, 216,

217, 227, 270

Snake, see Reptilia
Soil formation, 27
Solomon's seal, Polygonatum biflorum;

false, Smilacina racemosa
Sowbug, 218
Sphaeridae, 184
Sphagnum moss, 194, 195
Sphalerite, 72
Spiders, see Arachnida
Spiderwort, Tradescantia iiirginica
Sporebearers (see also Ferns) :
—Chara, 168, 172, 172, 178, 196
— Cladophora, 234
— Conocephalus, 265
— Equisetum:

arvensis, 260

fluviatile, 195, 198, 248

hyemale, 122, 260, 261
— Hydrodicton, 234
— Marchantia, 265
— Oedogonium, 234
— Riccia, 234
— Ricciocarpus, 234
—Selaginella rupestris, 265
—Sphagnum, moss, 234
Spring beauty, Claytonia virginica
Spring flora, 92
Spurge:

— Flowering, Euphorbia corollata
— Seaside, E. polygonifolia
Squirrel, see Mammals
Star flower, Trientalis americana
Star, new, 22
Stars: morning and evening, 21;

number of, 21, 22
Starved Rock, 7, 8, 9

INDEX

327

Stone fly, larva, 186

Stony Island, 36, 85, 87

Streak, 70

Stream: action of, 3; communities,

276, 277, 278
Sugar Creek, 10

Sun, 21 ; rate of movement of, 22
Sundew, Drosera rotundifolia
Sweet Cicely, see Cicely
Syenite, 75

Talus, 12

Tamarack-sphagnum bog, 179, 193, 194

Tamarack zone, 200

Tape grass, Vallisneria

Temperature, effect of, on plant and

animal distribution, 90
Termites, Termes fiavipes, 152
Tiger beetle, distribution of, 148
Thimbleweed, Anemone cylindrica
Thistle:

— Bull, Cirsium lanceolatum
— Canada, C. arvense
— Pasture or prairie, C. pumilum
— Sand, C. Pitcherii
Thorn Creek, 2, 4
Tickseed, Coreopsis grandiflora
Toadflax, bastard, Comandra umbettata
Toad: life-history of, 102; see Amphibia
Tolleston stage of Lake Chicago, 84, 87
Toothwort, Dentaria laciniata
Touch-me-not, Impatiens biflora
Trees:
— Acer:

saccharinum, river-bank maple,
272, 274

saccharum, hard, rock, or sugar

maple, 205, 206
— Amelanchier canadensis, Juneberry,

shadbush, sugar plum, 132, 133,

205
— Asimina triloba, pawpaw, 205, 208,

274

— Betula alba, white birch, 260
— Carpinus caroliniana, water beech,

W. I38, Uo, 205, 206, 270
— Celtis occidentalis, hackberry, 203,

204, 204
— Cercis canadensis, red-bud, 205, 206,

208, 274

— Cornus florida, flowering dogwood,

205, 206, 207, 274
— Crategus, hawthorne, 228
— Fagus grandifolia, beech, 204
— Fraxinus:

americana, white ash, 272, 274

nigra, black ash, 272, 274

pennsylvanica, red ash, 272

quadrangulata, blue ash, 272, 274
— Gymnodadus dioecia, Kentucky coffee

tree, 271, 274
— Juglans:

cinerea, white walnut, 203, 204,
221, 274

nigra, black walnut, 203, 204, 221
— Juniperus virginiana, red cedar, 124,

127, 260
— Larix laricina, larch, tamarack, 193,

200
— Lirodendron Tulipifera, tulip tree,

20 3, 203, 274

— Nyssa sylvatica, sour gum, 178, 180

— Ostrya virginiana, hop hornbeam, 137,
138, 205, 206, 270

—Pinus:

Banksiana, jack pine, 124, 127, 260
strobus, white pine, 7, 124, 127, 260

— Platanus occidentalis, sycamore, 203,

204, 205, 274
— Populus:

deltoides, cotton wood, 114, 116,

120, 122, 260
grandldentata, large-toothed aspen

228, 260
tremoloides, small-toothed aspen

228, 260
— Prunus:

nigra, wild plum, 228
pennsylvanica, pincherry, 132, 133
serotina, black cherry, 203, 204, 204,

221, 274
virginiana, choke cherry, 132, 133,

264, 265
— Ptelea trifoliata, hop tree, 132, 134,

270

— Pyrus coronaria, wild crabapple, 228
— Quercus:

alba, white oak, 137, 138, 139
bicolor, swamp white oak, 139
coccinea, scarlet oak, 139
ellipsoidalis, northern pin or hill

oak, 139

imbricaria, shingle oak, 139
macrocarpa, bur oak, 139
marilandica, blackjack oak, 139
Michauxii, basket oak, 139

328 A NATURALIST IN THE GREAT LAKES REGION

Trees— Continued

Muhlenbergii, cinquapin or chest-
nut oak, 132, 137, 139
palustris, pin or swamp oak, 139
rubra, red oak, 137, 138, 139
velutina, black oak, 132, 137, 139,

264
—Salix:

longifolia, 272
lucida, shiny willow, 183
nigra, 272

— Sassafras variifolium, 131, 732
— Thuja occidentalis, arbor vitae, 124,

126, 127
— Tilia americana, linden or basswood,

137, 138, 221, 274
—Ulmus:

americana, white elm, 138, 203, 205,

272
fidva, red or slippery elm, 137, 203,

272
Trillium, Trillium grandiflorum; T. re-

curvatum
Turtle, see Reptilia

Unglaciated region, 60
Upheaval of rock beds, 17, 18

Valley: drowned, 18; formation, 4, 5,

7, 8, 9.

Valley trains, 20, 64, 66, 67, 87
Vines:
— Celastrus scandens, bittersweet, 122,

124, 730, 131, 274

— Lonicera Sullivantii, honeysuckle, 274
— Menispermum canadense, moonseed,

273, 274
— Psedera quinquefolia, woodbine, 124,

130, 274
— Rhus Toxicodendron, poison ivy, 124,

7J7, 132, 274

— Smilax hispida, 272, 273
—Vitis:

aestivalis, summer grape, 130, 131

cordifolia, frost grape, 130, 131

wlpinus, river-bank grape, 130,

131. 274
Violet:

— Arrow-leaved, Viola sagittaia
— Birdfoot, V. pedata

— Canada, V. canadensis

— Dogtooth, Erythronium americanum

—Long-spurred, V. rostrata

—White, V. blanda

—Wood, V. palmata

Virginia creeper, see Vines

Volcanoes, 18

Warren's Woods, 205

Water as a factor in plant and animal

distribution, 95

Water boatman, see Hemiptera
Water breathers, 101, 102
Water buttercup, Ranunculus aqiia-

tilis

Waterleaf, Hydro phyllum virginianum
Water lily:

— Yellow, Nymphaea advena
— White, Castalia tuberosa
Water mite, Limnochares aquaticus,

175
Water penny, Psphenus Icconlei, 287,

288

Water scavenger, 187
Water scorpion, see Hemiptera
Water shield, Brasenia Schreberi
Water sowbug, Asellus
Water tiger, 186
Wave action, 2, 3, 27
Waves, force of, 3
Weathering, 27
Weevil, see Coleoptera
White ants, 152
Wild ginger, Asarum canadense
Willow Springs, 13, 36, 64 t
Wind, erosion agent, 13
Wintergreen, see Checkerberry
Wisconsin Glacial Period, 57, 63, 79
Wormwood, Artemisia caudata

Xerophyte, 96
Xerophytic adaptations, 98

Zonation of life, 90

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