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LIST OF ILLUSTRATIONS IN TEXT

FIG.		PAGE
1.	Egg of Basilarchia disippus, magnified	3
2.	Egg of Basilarchia disippus, natural size	3
3.	Egg of Papilio turnus, enlarged	4
4.	Egg of Anosia plexippus, magnified	4
5.	Egg of Anosia plexippus, natural size	4
6.	Egg of Anthocharis genutia, magnified	4
7.	Egg of Lycæna pseudargiolus, magnified	4
8.	Egg of Melitæa phaëton, magnified	4
9.	Micropyle of egg of Pieris oleracea, magnified	5
10.	Eggs of Grapta comma, magnified	5
11.	Eggs of Vanessa antiopa, magnified	5
12.	Caterpillar of Papilio philenor	6
13.	Head of caterpillar of Papilio asterias, magnified	6
14.	Head of caterpillar of Anosia plexippus, magnified	6
15.	Head of caterpillar of Anosia plexippus, side view, enlarged	7
16.	Caterpillar of Anosia plexippus, natural size	7
17.	Fore leg of caterpillar of Vanessa antiopa, enlarged	7
18.	Anterior segments of caterpillar of A. plexippus	7
19.	Proleg of caterpillar of Vanessa antiopa, enlarged	7
20.	Caterpillar of Basilarchia disippus	8
21.	Early stages of goatweed butterfly	9
22.	Head of caterpillar of Papilio troilus	9
23.	Caterpillar of milkweed butterfly changing into chrysalis	11
24.	Chrysalis of milkweed butterfly	12
25.	Chrysalis of Papilio philenor	12
26.	Caterpillar and chrysalis of Pieris protodice	12
27.	Chrysalis of Pieris oleracea	13
28.	Butterfly emerging from chrysalis	13
29.	Head of milkweed butterfly, showing parts	14
30.	Cross-section of sucking-tube of butterfly	15
31.	Longitudinal section of the head of the milkweed butterfly	15
32.	Interior structure of head of milkweed butterfly	16
33.	Labial palpus of butterfly	16
34.	Legs of butterfly	17
35.	Parts of leg of butterfly	17
36.	Scales on wing of butterfly	18
37.	Androconia from wing of butterfly	18
38.	Outline of wing of butterfly	20
39.	Arrangement of scales on the wing of a butterfly	20
40.	Figure of wing, showing names of veins	21
41.	Internal anatomy of caterpillar of milkweed butterfly	22
42.	Internal anatomy of milkweed butterfly	23
43.	Plan for folding net-ring	27
44.	Insect-net	27
45.	Plan for making a cheap net	27
46.	Cyanide-jar	29
47.	Paper cover for cyanide	29
48.	Method of pinching a butterfly	30
49.	Cheap form of breeding-cage	35
50.	Breeding-cage	36
51.	Butterfly in envelope	38
52.	Method of making envelopes	38
53.	Setting-board	39
54.	Setting-block	39
55.	Butterfly on setting-block	39
56.	Setting-needle	40
57.	Setting-board with moth upon it	40
58.	Butterfly pinned on setting-board	41
59.	Drying-box	41
60.	Drying-box	42
61.	Apparatus for inflating larvæ	45
62.	Tip of inflating-tube	46
63.	Drying-oven	46
64.	Drying-oven	47
65.	Detail drawing of book-box	48
66.	Detail drawing of box	48
67.	Detail drawing of box	49
68.	Insect-box	49
69.	Detail drawing of drawer for cabinet	51
70.	Detail drawing for paper bottom of box to take place of cork	52
71.	Manner of arranging specimens in cabinet or box	52
72.	Naphthaline cone	53
73.	Butterflies packed for shipment	55
74.	Forceps	56
75.	Forceps	57
76.	Antennæ of butterfly	61
77.	Antennæ of moths	62
78.	Neuration of genus Anosia	81
79.	Swarm of milkweed butterflies, photographed at night	83
80.	Neuration of genus Mechanitis	86
81.	Neuration of genus Ceratinia	88
82.	Neuration of genus Dircenna	89
83.	Fore leg of female Dircenna klugi	89
84.	Neuration of genus Heliconius	91
85.	Young caterpillar of Vanessa antiopa	94
86.	Neuration of genus Colænis	95
87.	Neuration of genus Dione	96
88.	Neuration of genus Euptoieta	98
89.	Neuration of genus Argynnis	101
90.	Neuration of genus Brenthis	129
91.	Neuration of genus Melitæa	138
92.	Neuration of genus Phyciodes	151
93.	Neuration of genus Eresia	157
94.	Neuration of genus Synchloë	159
95.	Neuration of genus Grapta	163
96.	Neuration of genus Vanessa	167
97.	Neuration of genus Pyrameis	170
98.	Neuration of genus Junonia	172
99.	Neuration of genus Anartia	174
100.	Neuration of genus Hypanartia	175
101.	Neuration of genus Eunica	176
102.	Neuration of genus Cystineura	177
103.	Neuration of genus Callicore	178
104.	Neuration of genus Timetes	179
105.	Neuration of genus Hypolimnas	181
106.	Neuration of genus Basilarchia	182
107.	Leaf cut away at end by the caterpillar of Basilarchia	183
108.	Hibernaculum of caterpillar of Basilarchia	183
109.	Neuration of genus Adelpha	187
110.	Neuration of genus Chlorippe	188
111.	Neuration of genus Pyrrhanæa	192
112.	Neuration of genus Ageronia	193
113.	Neuration of genus Victorina	195
114.	Neuration of genus Debis	199
115.	Neuration of genus Satyrodes	200
116.	Neuration of genus Neonympha	201
117.	Neuration of genus Cœnonympha	205
118.	Neuration of genus Erebia	208
119.	Neuration of genus Geirocheilus	211
120.	Neuration of genus Neominois	212
121.	Neuration of genus Satyrus	214
122.	Neuration of genus Œneis	219
123.	Caterpillars of Œneis macouni	221
124.	Neuration of genus Libythea	226
125.	Neuration of base of hind wing of genus Lemonias	228
126.	Neuration of genus Lemonias	229
127.	Neuration of genus Calephelis	232
128.	Neuration of genus Eumæus	237
129.	Neuration of Thecla edwardsi	238
130.	Neuration of Thecla melinus	242
131.	Neuration of Thecla damon	246
132.	Neuration of Thecla niphon	249
133.	Neuration of Thecla titus	250
134.	Neuration of genus Feniseca	251
135.	Neuration of genus Chrysophanus	252
136.	Neuration of Lycæna pseudargiolus	267
137.	Neuration of Lycæna comyntas	268
138.	Neuration of genus Dismorphia	273
139.	Neuration of genus Neophasia	274
140.	Neuration of genus Tachyris	276
141.	Neuration of genus Pieris	277
142.	Neuration of genus Nathalis	281
143.	Neuration of genus Euchloë	282
144.	Neuration of genus Catopsilia	286
145.	Neuration of genus Kricogonia	287
146.	Neuration of genus Meganostoma	288
147.	Neuration of genus Colias	289
148.	Neuration of genus Terias	295
149.	Neuration of genus Parnassius	305
	An Astronomer's Conception of an Entomologist	317
150.	Head and antenna of genus Pyrrhopyge	319
151.	Neuration of genus Pyrrhopyge	319
152.	Neuration of genus Eudamus	321
153.	Antenna and neuration of genus Plestia	322
154.	Neuration of genus Epargyreus	323
155.	Neuration of genus Thorybes	324
156.	Neuration of genus Achalarus	326
157.	Antenna and neuration of genus Hesperia	327
158.	Neuration of genus Systasea	329
159.	Neuration of genus Pholisora	330
160.	Neuration of genus Thanaos	332
161.	Neuration of genus Amblyscirtes	340
162.	Neuration of genus Pamphila	342
163.	Neuration of genus Oarisma	343
164.	Neuration of genus Ancyloxypha	345
165.	Neuration of genus Copæodes	346
166.	Neuration of genus Erynnis	347
167.	Neuration of genus Thymelicus	351
168.	Neuration of genus Atalopedes	352
169.	Neuration of genus Polites	353
170.	Neuration of genus Hylephila	354
171.	Neuration of genus Prenes	355
172.	Neuration of genus Calpodes	355
173.	Neuration of genus Lerodea	356
174.	Neuration of genus Limochores	357
175.	Neuration of genus Euphyes	360
176.	Neuration of genus Oligoria	361
177.	Neuration of genus Poanes	362
178.	Neuration of genus Phycanassa	362
179.	Neuration of genus Atrytone	364
180.	Neuration of genus Lerema	366
181.	Megathymus yuccæ, ♁	367
182.	Larva of Megathymus yuccæ	368
183.	Chrysalis of Megathymus yuccæ	368
	The Popular Conception of an Entomologist	369

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LIST OF COLORED PLATES

Produced by the color-photographic process of the Chicago Colortype Company, 1205 Roscoe Street, Chicago, Ill.

		Facing
		Page
I.	Spring Butterflies	Frontispiece
II.	Caterpillars of Papilionidæ and Hesperiidæ	6
III.	Caterpillars of Nymphalidæ	18
IV.	Chrysalids in Color and in Outline—Nymphalidæ	30
V.	Chrysalids in Color and in Outline—Nymphalidæ,
	Lycænidæ, Pierinæ	44
VI.	Chrysalids in Color and in Outline—Papiloninæ
	and Hesperiidæ	58
VII.	Anosia and Basilarchia	80
VIII.	Ithomiinæ, Heliconius, Dione, Colænis, and Euptoieta	88
IX.	Argynnis	100
X.	Argynnis	104
XI.	Argynnis	108
XII.	Argynnis	112
XIII.	Argynnis	116
XIV.	Argynnis	122
XV.	Brenthis	130
XVI.	Melitæa	138
XVII.	Melitæa, Phyciodes, Eresia	152
XVIII.	Argynnis, Brenthis, Melitæa, Phyciodes, Eresia,
	Synchloë, Debis, Geirocheilus	156
XIX.	Grapta, Vanessa	164
XX.	Grapta, Vanessa, Junonia, Anartia, Pyrameis	168
XXI.	Timetes, Hypolimnas, Eunica, Callicore	178
XXII.	Basilarchia, Adelpha	184
XXIII.	Chlorippe	190
XXIV.	Pyrrhanæa, Ageronia, Synchloë, Cystineura, Hypanartia,
	Victorina	196

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XXV.	Satyrodes, Cœnonympha, Neonympha, Neominois, Erebia	204
XXVI.	Satyrus	214
XXVII.	Œneis	220
XXVIII.	Libythea, Lemonias, Calephelis, Eumæus, Chrysophanus, Feniseca	228
XXIX.	Chrysophanus, Thecla	236
XXX.	Thecla, Lycæna	246
XXXI.	Lycæna	256
XXXII.	Lycæna, Thecla, Nathalis, Euchloë	266
XXXIII.	Catopsilia, Pyrameis	272
XXXIV.	Euchloë, Neophasia, Pieris, Kricogonia	280
XXXV.	Tachyris, Pieris, Colias	288
XXXVI.	Meganostoma, Colias	294
XXXVII.	Terias, Dismorphia	298
XXXVIII.	Papilio	302
XXXIX.	Parnassius	306
XL.	Papilio	310
XLI.	Papilio	314
XLII.	Papilio	316
XLIII.	Papilio, Colias, Pyrameis, Epargyreus	318
XLIV.	Papilio	323
XLV.	Papilio, Pholisora, Eudamus, Achalarus, Pyrrhopyge, Plestia, Calpodes, Thanao	330
XLVI.	Hesperiidæ	338
XLVII.	Hesperiidæ	350
XLVIII.	Hesperiidæ and Colias eurytheme	360

INTRODUCTION

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INTRODUCTION

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CHAPTER I

THE LIFE-HISTORY AND ANATOMY OF BUTTERFLIES

"The study of butterflies—creatures selected as the types of airiness and frivolity—instead of being despised, will some day be valued as one of the most important branches of biological science."—Bates, Naturalist on the Amazons.

In studying any subject, it is always well, if possible, to commence at the beginning; and in studying the life of animals, or of a group of animals, we should endeavor to obtain a clear idea at the outset of the manner in which they are developed. It is a familiar saying that "all life is from an egg." This statement is scientifically true in wide fields which come under the eye of the naturalist, and butterflies are no exception to the rule.

THE EGGS OF BUTTERFLIES

The eggs of butterflies consist of a membranous shell containing a fluid mass composed of the germ of the future caterpillar and the liquid food which is necessary for its maintenance and development until it escapes from the shell. The forms of these eggs are various. Some are spherical, others hemispherical, conical, and cylindrical. Some are barrel-shaped; others have the shape of a cheese, and still others have the form of a turban. Many of them are angled, some depressed at the ends. Their surface is variously ornamented. Sometimes they are ribbed, the ribs running from the center outwardly and downwardly along the sides like the meridian lines upon a globe. Between these ribs there is frequently found a fine network of raised lines variously arranged. Sometimes the surface is covered with minute depressions, sometimes with a series of minute elevations variously disposed. As there is great variety in the form of the eggs, so also there is great variety in their color. Brown, blue, green, red, and yellow eggs occur. Greenish or greenish-white are common tints. The eggs are often ornamented with dots and lines of darker color. Species which are related to one another show their affinity even in the form of their eggs. At the upper end of the eggs of insects there are one or more curious structures, known as micropyles (little doors), through which the spermatozoa of the male find ingress and they are fertilized. These can only be seen under a good microscope.

Fig. 6.—Egg of Anthocharis genutia, magnified 20 diameters.

Fig. 7.—Turban-shaped egg of Lycæna pseudargiolus, greatly magnified.

Fig. 8.—Egg of Melitæa phaëton, greatly magnified.

The eggs are laid upon the food-plant upon which the caterpillar, after it is hatched, is destined to live, and the female reveals wonderful instinct in selecting plants which are appropriate to the development of the larva. As a rule, the larvæ are restricted in the range of their food-plants to certain genera, or families of plants.

The eggs are deposited sometimes singly, sometimes in small clusters, sometimes in a mass. Fertile eggs, a few days after they have been deposited, frequently undergo a change of color, and it is often possible with a magnifying-glass to see through the thin shell the form of the minute caterpillar which is being developed within the egg. Unfruitful eggs generally shrivel and dry up after the lapse of a short time.

The period of time requisite for the development of the embryo in the egg varies. Many butterflies are single-brooded; others produce two or three generations during the summer in temperate climates, and even more generations in subtropical or tropical climates. In such cases an interval of only a few days, or weeks at the most, separates the time when the egg was deposited and the time when the larva is hatched. When the period of hatching, or emergence, has arrived, the little caterpillar cuts its way forth from the egg through an opening made either at the side or on the top. Many species have eggs which appear to be provided with a lid, a portion of the shell being separated from the remainder by a thin section, which, when the caterpillar has reached the full limit allowed by the egg, breaks under the pressure of the enlarging embryo within, one portion of the egg flying off, the remainder adhering to the leaf or twig upon which it has been deposited.

CATERPILLARS

Structure, Form, Color, etc.—The second stage in which the insects we are studying exist is known as the larval stage. The insect is known as a larva, or a caterpillar. In general caterpillars have long, worm-like bodies. Frequently they are thickest about the middle, tapering before and behind, flattened on the under side. While the cylindrical shape is most common, there are some families in which the larvæ are short, oval, or slug-shaped, sometimes curiously modified by ridges and prominences. The body of the larvæ of lepidoptera consists normally of thirteen rings, or segments, the first constituting the head.

The head is always conspicuous, composed of horny or chitinous material, but varying exceedingly in form and size. It is very rarely small and retracted. It is generally large, hemispherical, conical, or bilobed. In some families it is ornamented by horn-like projections. On the lower side are the mouth-parts, consisting of the upper lip, the mandibles, the antennæ, or feelers, the under lip, the maxillæ, and two sets of palpi, known as the maxillary and the labial palpi. In many genera the labium, or under lip, is provided with a short, horny projection known as the spinneret, through which the silk secreted by the caterpillar is passed. On either side, just above the mandibles, are located the eyes, or ocelli, which in the caterpillar are simple, round, shining prominences, generally only to be clearly distinguished by the aid of a magnifying-glass. These ocelli are frequently arranged in series on each side. The palpi are organs of touch connected with the maxillæ and the labium, or under lip, and are used in the process of feeding, and also when the caterpillar is crawling about from place to place. The larva appears to guide itself in great part by means of the palpi.

The body of the caterpillar is covered by a thin skin, which often lies in wrinkled folds, admitting of great freedom of motion. The body is composed, as we have seen, of rings, or segments, the first three of which, back of the head, correspond to the thorax of the perfect insect, and the last nine to the abdomen of the butterfly. On each ring, with the exception of the second, the third, and the last, there is found on either side a small oval opening known as a spiracle, through which the creature breathes. As a rule, the spiracles of the first and eleventh rings are larger in size than the others.

Every caterpillar has on each of the first three segments a pair of legs, which are organs composed of three somewhat horny parts covered and bound together with skin, and armed at their extremities by a sharp claw (Fig. 17). These three pairs of feet in the caterpillar are always known as the fore legs, and correspond to the six which are found in the butterfly or the moth. In addition, in most cases, we find four pairs of prolegs on the under side of the segments from the sixth to the ninth, and another pair on the last segment, which latter pair are called the anal prolegs. These organs, which are necessary to the life of the caterpillar, do not reappear in the perfect insect, but are lost when the transformation from the caterpillar to the chrysalis takes place. There are various modifications of this scheme of foot-like appendages, only the larger and more highly developed forms of lepidoptera having as many pairs of prolegs as have been enumerated.

Fig. 17.—Fore leg of caterpillar of Vanessa antiopa, enlarged.

Fig. 18.—Anterior segments of caterpillar of milkweed butterfly, showing thoracic or true legs (Riley).

Fig. 19.—Proleg of caterpillar of Vanessa antiopa, enlarged.

The bodies of caterpillars are variously ornamented: many of them are quite smooth; many are provided with horny projections, spines, and eminences. The coloration of caterpillars is as remarkable in the variety which it displays as is the ornamentation by means of the prominences of which we have just spoken. As caterpillars, for the most part, feed upon growing vegetation, multitudes of them are green in color, being thus adapted to their surroundings and securing a measure of protection. Many are brown, and exactly mimic the color of the twigs and branches upon which they rest when not engaged in feeding. Not a few are very gaily colored, but in almost every case this gay coloring is found to bear some relation to the color of the objects upon which they rest.

Caterpillars vary in their social habits. Some species are gregarious, and are found in colonies. These frequently build for themselves defenses, weaving webs of silk among the branches, in which they are in part protected from their enemies and also from the inclemencies of the weather. Most caterpillars are, however, solitary, and no community life is maintained by the vast majority of species. Many species have the habit of drawing together the edges of a leaf, in which way they form a covering for themselves. The caterpillars of some butterflies are wood-boring, and construct tunnels in the pith, or in the soft layers of growing plants. In these cases, being protected and concealed from view, the caterpillars are generally white in their coloration, resembling in this respect the larvæ of wood-boring beetles. A most curious phenomenon has within comparatively recent years been discovered in connection with the larval stage of certain small butterflies belonging to the family Lycœnidœ. The caterpillars are carnivorous, or rather aphidivorous; they live upon aphids, or plant-lice, and scale-insects, and cover themselves with the white exudations or mealy secretions of the latter. This trait is characteristic of only one of our North American species, the Harvester (Feniseca tarquinius).

In addition to being protected from enemies by having colors which enable them to elude observation, as has been already stated, some caterpillars are provided with other means of defense. The caterpillars of the swallowtail butterflies are provided with a bifurcate or forked organ, generally yellow in color, which is protruded from an opening in the skin back of the head, and which emits a powerful odor (Fig. 22). This protrusive organ evidently exists only for purposes of defense, and the secretion of the odor is analogous to the secretion of evil odors by some of the vertebrate animals, as the skunk. The majority of caterpillars, when attacked by insect or other enemies, defend themselves by quickly hurling the anterior part of the body from side to side.

Moults.—Caterpillars in the process of growth and development from time to time shed their skins. This process is called moulting. Moulting takes place, as a rule, at regular intervals, though there are exceptions to this rule. The young larva, having emerged from the egg, grows for a number of days, until the epidermis, or true skin, has become too small. It then ceases feeding, attaches itself firmly to some point, and remains quiet for a time. During this period certain changes are taking place, and then the skin splits along the middle line from the head to the extremity of the last segment, and the caterpillar crawls forth from the skin, which is left behind it, attached to the leaf or branch to which it was fastened. The skin of the head sometimes remains attached to the head of the caterpillar for a time after it has moulted, and then falls off to the ground. Ordinarily not more than five, and frequently only four, moults take place between hatching from the egg and the change into the chrysalis. In cases where caterpillars hibernate, or pass the winter in inaction, a long interval necessarily elapses between moults. Some arctic species are known in which the development from the egg to the perfect insect covers a period of two or three years, long periods of hibernation under the arctic snows taking place. The manner in which the caterpillar withdraws itself from its exuviæ, or old skin, is highly interesting. Every little spine or rough prominence is withdrawn from its covering, and the skin is left as a perfect cast of the creature which has emerged from it, even the hairs and spines attached to the skin being left behind and replaced by others.

The Food of the Caterpillar.—The vast majority of the caterpillars of butterflies subsist upon vegetable food, the only exceptions being the singular one already noted in which the larvæ feed upon scale-insects. Some of the Hesperiidæ, a group in which the relationship between butterflies and moths is shown, have larvæ which burrow in the roots and stems of vegetation.

Duration of the Larval State.—The duration of the larval state varies greatly. In temperate climates the majority of species exist in the caterpillar state for from two to three months, and where hibernation takes place, for ten months. Many caterpillars which hibernate do so immediately after emerging from the egg and before having made the first moult. The great majority, however, hibernate after having passed one or more moults. With the approach of spring they renew their feeding upon the first reappearance of the foliage of their proper food-plant, or are transformed into chrysalids and presently emerge as perfect insects. A few species live gregariously during the period of hibernation, constructing for themselves a shelter of leaves woven together with strands of silk.

Transformation.—The larval or caterpillar stage having been completed, and full development having been attained, the caterpillar is transformed into a pupa, or chrysalis. Of this, the third stage in the life of the insect, we now shall speak at length.

THE PUPA, OR CHRYSALIS

The caterpillars of many butterflies attach themselves by a button of silk to the under surface of a branch or stone, or other projecting surface, and are transformed into chrysalids, which are naked, and which hang perpendicularly from the surface to which they are attached. Other caterpillars attach themselves to surfaces by means of a button of silk which holds the anal extremity of the chrysalis, and have, in addition, a girdle of silk which passes around the middle of the chrysalis, holding it in place very much as a papoose is held on the back of an Indian squaw by a strap passed over her shoulders.

The Form of Chrysalids.—The forms assumed by the insect in this stage of its being vary very greatly, though there is a general resemblance among the different families and subfamilies, so that it is easy for one who has studied the matter to tell approximately to what family the form belongs, even when it is not specifically known. Chrysalids are in most cases obscure in coloring, though a few are quite brilliant, and, as in the case of the common milkweed butterfly (Anosia plexippus), ornamented with golden-hued spots. The chrysalids of the Nymphalidæ, one of the largest groups of butterflies, are all suspended. The chrysalids of the Papilionidæ, or swallowtail butterflies, are held in place by girdles, and generally are bifurcate or cleft at the upper end (Fig. 25), and are greenish or wood-brown in color.

A study of the structure of all chrysalids shows that within them there is contained the immature butterfly. The segments of the body are ensheathed in the corresponding segments of the chrysalis, and soldered over these segments are ensheathing plates of chitinous matter under which are the wings of the butterfly, as well as all the other organs necessary to its existence in the airy realm upon which it enters after emergence from the chrysalis. The practised eye of the observer is soon able to distinguish the location of the various parts of the butterfly in the chrysalis, and when the time for escape draws near, it is in many cases possible to discern through the thin, yet tough and hard, outer walls of the chrysalis the spots and colors on the wings of the insect.

Duration of Pupal Life.—Many butterflies remain in the chrysalis stage only for a few weeks; others hibernate in this state, and in temperate climates a great many butterflies pass the winter as chrysalids. Where, as is sometimes the case, there are two or three generations or broods of a species during the year, the life of one brood is generally longer than that of the others, because this brood is compelled to overwinter, or hibernate. There are a number of butterflies known in temperate North America which have three broods: a spring brood, emerging from chrysalids which have overwintered; an early summer brood; and a fall brood. The chrysalids in the latter two cases generally represent only a couple of weeks at most in the life of the insect. In tropical and semi-tropical countries many species remain in the chrysalis form during the dry season, and emerge at the beginning of the rains, when vegetation is refreshed and new and tender growths occur in the forests.

The Transformation from the Chrysalis to the Imago.—The perfectly developed insect is known technically as the imago. When the time of maturity in the chrysalis state has been reached, the coverings part in such a way as to allow of the escape of the perfect insect, which, as it comes forth, generally carries with it some suggestion of its caterpillar state in the lengthened abdomen, which it with apparent difficulty trails after it until it secures a hold upon some object from which it may depend while a process of development (which lasts generally a few hours) takes place preparatory to flight. The imago, as it first emerges, is provided with small, flaccid wings, which, together with all the organs of sense such as the antennæ, require for their complete development the injection into them of the vital fluids which, upon first emergence, are largely contained in the cavities of the thorax and abdomen. Hanging pendant on a projecting twig, or clinging to the side of a rock, the insect remains fanning its wings, while by the strong process of circulation a rapid injection of the blood into the wings and other organs takes place, accompanied by their expansion to normal proportions, in which they gradually attain to more or less rigidity. Hardly anything in the range of insect life is more interesting than this rapid development of the butterfly after its first emergence from the chrysalis. The body is robbed of its liquid contents in a large degree; the abdomen is shortened up; the chitinous rings which compose its external skeleton become set and hardened; the wings are expanded, and then the moment arrives when, on airy pinions, the creature that has lived a worm-like life for weeks and months, or which has been apparently sleeping the sleep of death in its cerements, soars aloft in the air, the companion of the sunlight and the breezes.

ANATOMY OF BUTTERFLIES

The body of the butterfly consists of three parts—the head, the thorax, and the abdomen.

The Head.—The head is globular, its breadth generally exceeding its length. The top is called the vertex; the anterior portion, corresponding in location to the human face, is called the front. Upon the sides of the head are situated the large compound eyes, between which are the antennæ, or "feelers," as they are sometimes called. Above the mouth is a smooth horny plate, the clypeus. The labrum, or upper lip, is quite small. On both sides of the mouth are rudimentary mandibles, which are microscopic objects. The true suctorial apparatus is formed by the maxillæ, which are produced in the form of semi-cylindrical tubes, which, being brought together and interlocking, form a complete tube, which is known as the proboscis, and which, when not in use, is curled up spirally, looking like a watch-spring. At the upper end of the proboscis, in the head, is a bulb-like enlargement, in the walls of which are inserted muscles which have their origin on the inner wall of the head. When these muscles contract, the bulb-like cavity is enlarged, a vacuum is produced, and the fluids in the cup of the flower flow up the proboscis and into the bulb. The bulb is also surrounded by muscles, which, when contracting, compress it. The external opening of the tube has a flap, or valve, which, when the bulb is compressed, closes and causes the fluid in it to flow backward into the gullet and the stomach. The arrangement is mechanically not unlike that in a bulb-syringe used by physicians. The process of feeding in the case of the butterfly is a process of pumping honeyed water out of the flowers into the stomach. The length of the proboscis varies; at its base and on either side are placed what are known as the maxillary palpi, which are very small. The lower lip, or labium, which is also almost obsolete in the butterflies, has on either side two organs known as the labial palpi, which consist of three joints. In the butterflies the labial palpi are generally well developed, though in some genera they are quite small. The antennæ of butterflies are always provided at the extremity with a club-shaped enlargement, and because of this clubbed form of the antennæ the entire group are known as the Rhopalocera, the word being compounded from the Greek word (ῥοπαλον), which means a club, and the word κεραζ (keras) which means a horn.

It will be observed from what has been said that the head in these creatures is to a large extent the seat of the organs of sense and alimentation. What the function of the antennæ may be is somewhat doubtful, the opinion of scientific men being divided. The latest researches would indicate that these organs, which have been regarded as the organs of smell and sometimes as the organs of hearing, have probably a compound function, possibly enabling the creature to hear, certainly to smell, but also, perhaps, being the seat of impressions which are not strictly like any which we receive through our senses.

Thorax.—The thorax is more or less oval in form, being somewhat flattened upon its upper surface. It is composed of three parts, or segments, closely united, which can only be distinguished from one another by a careful dissection. The anterior segment is known as the prothorax, the middle segment as the mesothorax, and the after segment as the metathorax. The legs are attached in pairs to these three subdivisions of the thorax, the anterior pair being therefore sometimes spoken of as the prothoracic legs, the second pair as the mesothoracic legs, and the latter pair as the metathoracic legs (Fig. 34). On either side of the mesothorax are attached the anterior pair of wings, over which, at their insertion into the body, are the tegulæ, or lappets; on either side of the metathorax are the posterior pair of wings. It will be seen from what has been said that the thorax bears the organs of locomotion. The under side of the thorax is frequently spoken of by writers, in describing butterflies, as the pectus, or breast.

The Abdomen.—The abdomen is formed normally of nine segments, and in most butterflies is shorter than the hind wings. On the last segment there are various appendages, which are mainly sexual in their nature.

The Legs.—Butterflies have six legs, arranged in three pairs, as we have already seen. Each leg consists of five parts, the first of which, nearest the body, is called the coxa, with which articulates a ring-like piece known as the trochanter. To this is attached the femur, and united with the femur, forming an angle with it, is the tibia. To the tibia is attached the tarsus, or foot, the last segment of which bears the claws, which are often very minute and blunt in the butterflies, though in moths they are sometimes strongly hooked. The tibiæ are often armed with spines. In some groups of butterflies the anterior pair of legs is aborted, or dwarfed, either in one or both sexes, a fact which is useful in determining the location of species in their systematic order.

The Wings.—The wings of butterflies consist of a framework of horny tubes which are in reality double, the inner tube being filled with air, the outer tube with blood, which circulates most freely during the time that the insect is undergoing the process of development after emergence from the chrysalis, as has been already described. After emergence the circulation of the blood in the outer portion of the tubes is largely, if not altogether, suspended. These horny tubes support a broad membrane, which is clothed in most species upon both sides with flattened scales which are attached to the membrane in such a way that they overlap one another like the shingles on a roof. These scales are very beautiful objects when examined under a microscope, and there is considerable diversity in their form as well as in their colors. The males of many species have peculiarly shaped scales arranged in tufts and folds, which are called androconia, and are useful in microscopically determining species (Fig. 37). The portion of the wings which is nearest to the thorax at the point where they are attached to the body is called the base; the middle third of the wing is known as the median or discal area, the outer third as the limbal area. The anterior margin of the wings is called the costal margin; the outer edge is known as the external margin, the inner edge as the inner margin. The shape of the wings varies very much. The tip of the front wing is called the apex, and this may be rounded, acute, falcate (somewhat sickle-shaped), or square. The angle formed by the outer margin of the front wing with the inner margin is commonly known as the outer angle. The corresponding angle on the hind wing is known as the anal angle, and the point which corresponds to the tip or apex of the front wing is known as the external angle (Fig. 38). A knowledge of these terms is necessary in order to understand the technical descriptions which are given by authors.

If a wing is examined with the naked eye, or even with a lens, a clear conception of the structure of the veins can rarely be formed. Therefore it is generally necessary to remove from the wings the scales which cover them, or else bleach them. The scales may be removed mechanically by rubbing them off. They may be made transparent by the use of chemical agents. In the case of specimens which are so valuable as to forbid a resort to these methods, a clear knowledge of the structure of the veins may be formed by simply moistening them with pure benzine or chloroform, which enables the structure of the veins to be seen for a few moments. The evaporation of these fluids is rapid, and they produce no ill effect upon the color and texture of the wings. In the case of common species, or in the case of such as are abundantly represented in the possession of the collector, and the practical destruction of one or two of which is a matter of no moment, it is easy to use the first method. The wing should be placed between two sheets of fine writing-paper which have been moistened by the breath at the points where the wing is laid, and then by lightly rubbing the finger-nail or a piece of ivory, bone, or other hard substance over the upper piece of paper, a good many of the scales may be removed. This process may be repeated until almost all of them have been taken off. This method is efficient in the case of many of the small species when they are still fresh; in the case of the larger species the scales may be removed by means of a camel's-hair pencil such as is used by painters. The chemical method of bleaching wings is simple and inexpensive. For this purpose the wing should be dipped in alcohol and then placed in a vessel containing a bleaching solution of some sort. The best agent is a solution of chloride of lime. After the color has been removed from the wing by the action of the chloride it should be washed in a weak solution of hydrochloric acid. It may then be cleansed in pure water and mounted upon a piece of glass, as microscopic slides are mounted, and thus preserved. When thus bleached the wing is capable of being minutely studied, and all points of its anatomy are brought clearly into view.

The veins in both the fore and hind wings of butterflies may be divided into simple and compound veins. In the fore wing the simple veins are the costal, the radial, and the submedian; in the hind wing, the costal, the subcostal, the upper and lower radial, the submedian, and the internal are simple. The costal vein in the hind wing is, however, generally provided near the base with a short ascending branch which is known as the precostal vein. In addition to these simple veins there are in the fore wing two branching veins, one immediately following the costal, known as the subcostal, and the other preceding the submedian, known as the median vein. The branches of these compound veins are known as nervules. The median vein always has three nervules. The nervules of the subcostal veins branch upwardly and outwardly toward the costal margin and the apex of the fore wing. There are always from four to five subcostal nervules. In the hind wing the subcostal is simple. The median vein in the hind wing has three nervules as in the fore wing. Between the subcostal and the median veins, toward the base in both wings, is inclosed the cell, which may be wholly or partially open at its outer extremity, or closed. The veinlets which close the cell at its outward extremity are known as the discocellular veins, of which there are normally three. From the point of union of these discocellular veins go forth the radial veins known respectively as the upper and lower radials, though the upper radial in many genera is emitted from the lower margin of the subcostal.

An understanding of these terms is, however, more readily derived from a study of the figure in which the names of these parts are indicated (Fig. 40).

Butterflies generally hold their wings erect when they are at rest, with their two upper surfaces in proximity, the under surfaces alone displaying their colors to the eye. Only in a few genera of the larger butterflies, and these tropical species, with which this book does not deal, is there an exception to this rule, save in the case of the Hesperiidæ, or "skippers," in which very frequently, while the anterior wings are folded together, the posterior wings lie in a horizontal position.

Internal Organs.—Thus far we have considered only the external organs of the butterfly. The internal organs have been made the subject of close study and research by many writers, and a volume might be prepared upon this subject. It will, however, suffice for us to call the attention of the student to the principal facts.

The muscular system finds its principal development in the thorax, which bears the organs of locomotion. The digestive system consists of the proboscis, which has already been described, the gullet, or œsophagus, and the stomach, over which is a large, bladder-like vessel called the food-reservoir, a sort of crop preceding the true stomach, which is a cylindrical tube; the intestine is a slender tube, varying in shape in different genera, divided into the small intestine, the colon, and the rectum. Butterflies breathe through spiracles, little oval openings on the sides of the segments of the body, branching from which inwardly are the tracheæ, or bronchial tubes. The heart, which is located in the same relative position as the spine in vertebrate animals, is a tubular structure. The nervous system lies on the lower or ventral side of the body, its position being exactly the reverse of that which is found in the higher animals. It consists of nervous cords and ganglia, or nerve-knots, in the different segments. Those in the head are more largely developed than elsewhere, forming a rudimentary brain, the larger portion of which consists of two enormous optic nerves. The student who is desirous of informing himself more thoroughly and accurately as to the internal anatomy of these insects may consult with profit some of the treatises which are mentioned in the list of works dealing with the subject which is given elsewhere in this book.

Polymorphism and Dimorphism.