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Wild Bees, Wasps and Ants and Other Stinging Insects

<h2>WILD BEES, WASPS AND ANTS</h2> <div class="figcenter"> <ANTIMG style="width:100%" src="images/PlateA.png" alt="Plate A" title="Plate A" /> Plate A. 1. Formica sanguinea, male. 2. Formica sanguinea, female. 3. Formica sanguinea, worker. 4. Mutilla europæa, male. 5. Mutilla Europæa, female. 6. Cerceris arenaria, female. 7. Ammophila sabulosa, female. 8. Crabro cribrarius, male. 9. Odynerus spinipes, male. [front. </div> <h1>WILD BEES, WASPS AND ANTS</h1> <h3>And Other Stinging Insects</h3> By <h3>EDWARD SAUNDERS</h3> F.R.S., F.L.S., etc With numerous Illustrations in the text, and Four Coloured Plates by CONSTANCE A. SAUNDERS   <div class="figcenter"> <ANTIMG style="width:100%" src="images/pmark.png" alt="Printers Mark" title="Printers Mark" /></div>   LONDON GEORGE ROUTLEDGE & SONS, LIMITED New York: E. P. DUTTON & CO. <hr class="full" /> {v} <h3>PREFACE</h3> The object of this little book is to give in as simple a form as possible a short account of some of the British Wild Bees, Wasps, Ants, etc., scientifically known as the Hymenoptera Aculeata. Of these the non-scientific public rarely recognizes more than the Hive Bee, the Humble Bee, the Wasp, and the Hornet, whereas there are about 400 different kinds to be found in this country, and they can be recognized by any one who is disposed to make a special study of the group. The author has not hesitated to make free use of the experiences of others in regard to the habits of the insects he describes, and he has not thought it necessary in each case to make separate acknowledgment of this. He takes this opportunity of thanking Mr. H. Donisthorpe and Mr. F. W. L. Sladen for assistance in the chapters on Ants and their Lodgers, and Humble Bees, respectively. {vi} These pages are written only for the non-scientific, as the scientific entomologist will be already familiar with the elementary facts recorded; but it is hoped that they may be of interest to lovers of Nature who wish to know a little about the insects they see round them and how they spend their lives. Of this knowledge very little exists, as the scraps which have been here brought together evidence. There is an immense field open for research and observation, and the writer of this little book will be very glad if the following pages should encourage any one to take up the subject and add to our present scanty stock of information. <div class="poem"> <div class="stanza"> EDWARD SAUNDERS. </div> </div> St. Ann's, Woking. <hr class="full" /> {vii} <h3>CONTENTS</h3> <table class="nobctr" summary="Table of Contents" title="Table of Contents"> <tr><td class="spacsingle"> </td><td class="spacsingle" style="text-align:right;"> PAGE</td></tr> <tr><td class="spacsingle"> The Subject in General, </td><td class="spacsingle" style="text-align:right;"> 1</td></tr> <tr><td class="spacsingle"> The Solitary Groups, </td><td class="spacsingle" style="text-align:right;"> 6</td></tr> <tr><td class="spacsingle" style="padding-left:2em;"> The Solitary Bees, </td><td class="spacsingle" style="text-align:right;"> 9</td></tr> <tr><td class="spacsingle" style="padding-left:2em;"> The Cuckoo Bees, </td><td class="spacsingle" style="text-align:right;"> 14</td></tr> <tr><td class="spacsingle" style="padding-left:2em;"> The Fossors, or Diggers, </td><td class="spacsingle" style="text-align:right;"> 18</td></tr> <tr><td class="spacsingle" style="padding-left:2em;"> The Solitary Wasps, </td><td class="spacsingle" style="text-align:right;"> 24</td></tr> <tr><td class="spacsingle"> The Social Groups, </td><td class="spacsingle" style="text-align:right;"> 28</td></tr> <tr><td class="spacsingle" style="padding-left:2em;"> The Ants, </td><td class="spacsingle" style="text-align:right;"> 31</td></tr> <tr><td class="spacsingle" style="padding-left:2em;"> The Social Wasps, </td><td class="spacsingle" style="text-align:right;"> 35</td></tr> <tr><td class="spacsingle" style="padding-left:2em;"> The Humble Bees, </td><td class="spacsingle" style="text-align:right;"> 39</td></tr> <tr><td class="spacsingle"> The Bees With Bifid Tongues, </td><td class="spacsingle" style="text-align:right;"> 44</td></tr> <tr><td class="spacsingle"> The Bees with Pointed Tongues, </td><td class="spacsingle" style="text-align:right;"> 48</td></tr> <tr><td class="spacsingle"> Leaf-Cutting Bees, </td><td class="spacsingle" style="text-align:right;"> 52</td></tr> <tr><td class="spacsingle"> Osmia and Its Habits, </td><td class="spacsingle" style="text-align:right;"> 55</td></tr> <tr><td class="spacsingle"> A Colony of Anthophora, </td><td class="spacsingle" style="text-align:right;"> 61</td></tr> <tr><td class="spacsingle"> Bees and Pollen-Collecting, </td><td class="spacsingle" style="text-align:right;"> 65</td></tr> <tr><td class="spacsingle"> On Bees' Tongues, and how They suck Honey, </td><td class="spacsingle" style="text-align:right;"> 72</td></tr> <tr><td class="spacsingle"> A Dreadful Parasite, </td><td class="spacsingle" style="text-align:right;"> 77</td></tr> <tr><td class="spacsingle"> {viii} Amongst the Bees at Work, </td><td class="spacsingle" style="text-align:right;"> 81</td></tr> <tr><td class="spacsingle"> Ants, their Guests, and their Lodgers, </td><td class="spacsingle" style="text-align:right;"> 88</td></tr> <tr><td class="spacsingle"> How can an "Aculeate" be Recognized?, </td><td class="spacsingle" style="text-align:right;"> 92</td></tr> <tr><td class="spacsingle"> Males and Females, </td><td class="spacsingle" style="text-align:right;"> 95</td></tr> <tr><td class="spacsingle"> The Vagaries of Colour and Structure in the Sexes, </td><td class="spacsingle" style="text-align:right;"> 100</td></tr> <tr><td class="spacsingle"> The Distribution, Rarity, or Abundance of Various Species,</td><td class="spacsingle" style="text-align:right;"> 105</td></tr> <tr><td class="spacsingle"> On Bees' Wings, </td><td class="spacsingle" style="text-align:right;"> 110</td></tr> <tr><td class="spacsingle"> On Breeding Aculeates, etc., </td><td class="spacsingle" style="text-align:right;"> 113</td></tr> <tr><td class="spacsingle"> On Colour, </td><td class="spacsingle" style="text-align:right;"> 119</td></tr> <tr><td class="spacsingle"> The Development of Insects from the Egg, </td><td class="spacsingle" style="text-align:right;"> 124</td></tr> <tr><td class="spacsingle"> On Structure, </td><td class="spacsingle" style="text-align:right;"> 132</td></tr> <tr><td class="spacsingle"> Index, </td><td class="spacsingle" style="text-align:right;"> 141</td></tr> </table> <hr class="short" /> {ix} <h3>LIST OF ILLUSTRATIONS IN THE TEXT</h3> <table class="nobctr" summary="List of Illustrations" title="List of Illustrations"> <tr><td class="spacsingle"> </td><td class="spacsingle" style="text-align:right;"> PAGE</td></tr> <tr><td class="spacsingle"> Fig.  1. Bombus, larva and nymph: after Packard </td><td class="spacsingle" style="text-align:right;"> 11</td></tr> <tr><td class="spacsingle">   ,,    2. Ammophila </td><td class="spacsingle" style="text-align:right;"> 22</td></tr> <tr><td class="spacsingle">   ,,  3-4. Spines on the tarsi of female Ammophila </td><td class="spacsingle" style="text-align:right;"> 23</td></tr> <tr><td class="spacsingle">   ,,    5. Tubular entrance to hole of wasp </td><td class="spacsingle" style="text-align:right;"> 25</td></tr> <tr><td class="spacsingle">   ,,    6. Basal segments of ants </td><td class="spacsingle" style="text-align:right;"> 33</td></tr> <tr><td class="spacsingle">   ,,    7. Rose-leaf partially eaten by bees </td><td class="spacsingle" style="text-align:right;"> 52</td></tr> <tr><td class="spacsingle">   ,,    8. Tufted hairs of hind leg of Andrena </td><td class="spacsingle" style="text-align:right;"> 67</td></tr> <tr><td class="spacsingle">   ,,    9. Corbicula of humble bee </td><td class="spacsingle" style="text-align:right;"> 67</td></tr> <tr><td class="spacsingle">   ,,  10-12. Cleaning apparatus of bees </td><td class="spacsingle" style="text-align:right;"> 69</td></tr> <tr><td class="spacsingle">   ,,  13-18. Hairs of bees, magnified </td><td class="spacsingle" style="text-align:right;"> 71</td></tr> <tr><td class="spacsingle">   ,,  19. Tongues of bees, magnified </td><td class="spacsingle" style="text-align:right;"> 73</td></tr> <tr><td class="spacsingle">   ,,  20. Diagram of tongue of bee </td><td class="spacsingle" style="text-align:right;"> 75</td></tr> <tr><td class="spacsingle">   ,,  21. Stylops </td><td class="spacsingle" style="text-align:right;"> 77</td></tr> <tr><td class="spacsingle">   ,,  22. Stylops larva in abdominal cavity of bee </td><td class="spacsingle" style="text-align:right;"> 78</td></tr> <tr><td class="spacsingle">   ,,  23. Antennæ of "Keyhole" wasps </td><td class="spacsingle" style="text-align:right;"> 101</td></tr> <tr><td class="spacsingle">   ,,  24. Legs of male "Keyhole" wasps </td><td class="spacsingle" style="text-align:right;"> 101</td></tr> <tr><td class="spacsingle">   ,,  25. Tibia of male Crabro cribrarius </td><td class="spacsingle" style="text-align:right;"> 103</td></tr> <tr><td class="spacsingle">   ,,  26. Antennæ of male Crabro cribrarius </td><td class="spacsingle" style="text-align:right;"> 103</td></tr> <tr><td class="spacsingle">   ,,  27. Head of male and female Crabro clypeatus </td><td class="spacsingle" style="text-align:right;"> 103</td></tr> <tr><td class="spacsingle">   ,,  28. Parts of the insect </td><td class="spacsingle" style="text-align:right;"> 133</td></tr> </table> <hr class="short" /> {xi} <h3>DESCRIPTION OF THE COLOURED PLATES</h3> PLATE A <blockquote class="b1n"> Figs. 1, 2, 3. Formica sanguinea Latr.: male, female, and worker. The host of Lomechusa (p. 89), also a slave-making species; makes irregular nests of dead leaves, etc., generally against a sloping bank. Figs. 4, 5. Mutilla europæa Linn.: male and female. One of the few British species of Aculeates where the female is wingless; found in sandy places running in the sun. Fig. 6. Cerceris arenaria L.: female; burrows in the sand, and provisions its nest with beetles (p. 20). Fig. 7. Ammophila sabulosa L.: female; burrows in the sand, provisions its nest with caterpillars, peculiar for its very elongated waist (p. 22). Fig. 8. Crabro cribrarius L.: male; peculiar for its paddle-like tibiæ and flattened antennæ (p. 103). Fig. 9. Odynerus spinipes L.: male; peculiar for the form of its middle femora, which are cut out almost in two semicircles (p. 101); female makes a tubular entrance to her nest (p. 25). </blockquote> PLATE B <blockquote class="b1n"> Fig. 10.—Colletes succinctus L.: female; lines its cells with a gluey material (p. 44); colonizes in sandy banks; host of Epeolus rufipes (fig. 19). {xii} Fig. 11. Sphecodes subquadratus Smith: female; cuckoo of a species of Halictus; female hibernates like its host (p. 17). Fig. 12. Halictus lencozonius Schr.: burrows in the ground; the host of Sphecodes pilifrons Thoms (p. 17). Fig. 13. Vespa crabro L.: female (the Hornet), nests in hollow trees; host of the rare beetle Velleius dilatatus (p. 38). Fig. 14. Vespa vulgaris L.: female: one of our commonest wasps; nests usually in the ground (p. 35); host of a peculiar beetle (Met&oelig;cus paradoxus) (p. 38) Figs. 15, 16. Andrena fulva Schr.: male and female; the bee which burrows in lawns, etc. (p. 9); host of Nomada ruficornis var. signata (p. 15). Fig. 17. Panurgus ursinus Gmel.: Female; legs loaded with pollen, burrows in hard sandy paths, etc. (p. 49). Males sleep curled up amongst the rays of yellow composite flowers. Fig. 18. Nomada ruficornis L. var. signata: cuckoo of Andrena fulva (figs. 15 and 16). Fig. 19. Epeolus rufipes Thoms: female; cuckoo of Colletes succinctus (fig. 10). </blockquote> PLATE C <blockquote class="b1n"> Fig. 20.—Megachile maritima Kirby: female; burrows in the ground, makes its cells of pieces of leaves, which it cuts out with its mandibles; host of C&oelig;lioxys conoidea. Figs. 21, 22. C&oelig;lioxys conoidea Illig: male and female; cuckoo of Megachile maritima. Fig. 23. Burrows of Megachile Willughbiella Kirby, in a piece of rotten willow; each burrow originally contained six cells, but two of the left-hand series have been lost. </blockquote> {xiii} PLATE D <blockquote class="b1n"> Figs. 24 and 25. Anthophora pilipes F.: male and female. A spring bee, the male of which may often be seen in gardens, darting from flower to flower (p. 81); while the female collects pollen; it forms large colonies (p. 62). Fig. 26. Melecta armata Pz.: cuckoo of Anthophora pilipes. Fig. 27. Anthidium manicatum L.: invests its cells with the down off the stems of labiate plants, which it strips off with its mandibles (p. 50). Fig. 28. Osmia bicolor Schr.: female; nests in snail-shells, which it sometimes covers up with small pieces of grass-stems till a little mound is formed, resembling a diminutive ants' nest (p. 59). Fig. 29. Bombus terrestris L.: female. One of the commonest of our Humble Bees; it nests in the ground. It is the host of Psithyrus vestalis, which resembles it very closely in colour; it is this species that was exhibited by Mr. Sladen at the Maidstone Agricultural Hall (p. 41). Fig. 30. Bombus lapidarius L.: another common Humble Bee, also an underground builder; it is the host of Psithyrus rupestris. Fig. 31. Psithyrus rupestris F.: female; the cuckoo of Bombus lapidarius, which it closely resembles except for the nearly black colour of the wings. </blockquote> <hr class="full" /> {1} <h3>THE SUBJECT IN GENERAL</h3> I think I ought here to say why I propose to limit myself to an account of a certain portion only of the Hymenoptera. The reason for this, in the first place, is that the section which I have selected is the only one of which I have any special knowledge; it consists of the bees, wasps, ants and sandwasps, four groups which make up the stinging section of the order—or perhaps more accurately, which have poison bags connected with their egg-laying apparatus or ovipositor. Another reason for their selection lies in their nesting habits; these enable one to get a further insight into their economy and ways than can be obtained from those of almost any other group or order—at any rate they make them comparatively easy to study; one can, so to say, find these little creatures at home, whereas in most orders there seems to be no definite home to which the {2}individuals may be traced; a great advantage also in selecting the stinging groups for study is that they are creatures of the spring and summer, and of the sunshine, so that the weather which tempts them out to their duties is of the kind most agreeable to those who wish to investigate their habits. The habits of the hive bee have not been touched on, as so many excellent treatises have been written on them that any observations here would be superfluous. Although these groups are distinguished by their stinging habits, it is only the female that possesses a sting—the male is a most harmless creature and quite incapable of injuring any one. A male wasp or even a male hornet may be handled with absolute impunity, only it is wise to be certain as to the sex of the individual before presuming to play with it too much! A word here may perhaps be said about stinging. People often talk about a gnat stinging or a stinging fly; it may be difficult to define exactly what "to sting" means, but the writer has always considered that a sting is inflicted by the tail end of the creature or a {3}bite by the mouth. A fly or gnat no doubt inserts its proboscis into one's flesh just as a wasp does its sting; but the actions of such opposite parts of the body surely demand distinct names. As we have been alluding to flies it may not be inappropriate to say here that all the creatures we are going to consider have four membranous wings except the worker ants and a very few forms which are comparatively seldom met with. By this character they may at once be known from flies, which have only two membranous wings. The large brown "drone flies", so often seen on the windows of our rooms, especially in autumn, and which most people mistake for hive bees, to which they certainly bear a considerable general resemblance, may be detected at once by wanting the two hind wings of the bee. The "aculeate", or stinging, Hymenoptera, are divided into sections and families according to their structure; but the groups which stand out most clearly in regard to their habits are the solitary and social species, the predaceous and non-predaceous and the inquilines or cuckoos. {4} The vast majority of the aculeate Hymenoptera are what are called "solitary", i.e. one male and one female alone are interested in the production of the nest; but there are also three "social" groups—the ants, the true wasps, and the humble and hive bees. These are called social because they form communities and all work together towards the maintenance of the nest. In the social species there are two forms of the females—the queens and the workers; these latter have the ovaries imperfectly developed, and in the humble bees and wasps they only differ outwardly from the fully developed females or queens by being smaller. In the ants, however, the workers are wingless, and of a very different form from that of the queen. The rôle of these workers seems to be to do the general work of the nest; they have been known to lay fertile eggs, but the resulting offspring has always been male. Between these conditions of solitary and social we know of no actually intermediate stages. We do not seem to see any attempts on the part of solitary bees to become social or vice versâ. The only condition known which {5}could possibly be considered as intermediate is shown in certain species where a number of individuals make their nests close to each other in some particular bank, forming a colony. These colonies are sometimes very extensive, and the burrows of the individual bees very close together; it has also been shown that the burrows sometimes unite—at the same time there seems to be no positive evidence that there is any work done in the colony which could be considered as done for the common good. <hr class="short" /> {6} <h3>THE SOLITARY GROUPS</h3> All the solitary kinds appear to feed themselves on vegetable juices, honey, etc., but there is a well-marked division between those who provision the cells of their offspring with insects, either fully developed or in the larval stages, and those who provision them with the pollen of flowers, honey, etc. The theory is that originally all fed their cells with insects, but that by degrees the more progressive found that the food which suited themselves would equally nourish their offspring, and accordingly provided them with vegetable nourishment. We find no intermediate stages. A certain class still goes on feeding on the old principle. The members of this class are known as "fossors" or diggers, while those which feed on the new principle are called "Anthophila" or flower-lovers. These are not very happy names, as many of the Anthophila dig out holes for their nests just {7}in the same way as the fossors do, and many of the fossors are found in flowers, apparently enjoying them just as much as a truly anthophilous species would, although no doubt often with the ulterior object of capturing some insect for their young! Still these names are known as representing these two sections all over the world, and therefore it is better to keep to them even if they are not as descriptive as one would like them to be. The fossors, or "diggers", have all comparatively short and bifid tongues, and have, as a rule, little in the way of hairy covering, and what hairs they have are simple and only in very rare instances branched or feather-like. The hind legs of the females are not modified in any way so as to enable them to collect pollen, their legs are usually long and slender, and they are admirably adapted to their life habits of hunting spiders, insects, etc., for their young. On the other hand, the Anthophila or "flower-lovers", are specially adapted for pollen collecting. Their tongues vary from a short form like that of some fossors to the long tongues of the humble bees. Their hairs are always plumose {8}or branched on some part of the body and the hind legs of the females in most species are provided on the tibia or shin with a special brush on which pollen may be collected. In some of the long-tongued bees, however, this brush occurs on the underside of the body instead of on the tibia. The pollen-collecting arrangements of the different genera of the Anthophila and the corresponding organs for cleaning off the pollen again are amongst the most interesting instances of modification and adaptation: some of the more striking of these will be mentioned later on. (See pp. 65 sqq.) <hr class="short" /> {9} <h3>THE SOLITARY BEES</h3> The life-history of an ordinary pair of solitary bees is, roughly, as follows: I will take for an example one of the spring species of Andrena. Many people know the little red bee, which for some apparently unaccountable reason suddenly appears in myriads on their lawn or gravel path, throwing up little mounds of finely powdered earth—in this respect being quite different from worm casts, which are formed of wet mould and the particles of which cling together—sometimes causing considerable alarm as to the possible effect on the lawn. These have hatched out from burrows made by their parents in the previous year, the mouths of which have been filled up with earth and therefore are quite invisible till the newly fledged bees gnaw their way out. They, in their turn, are now making fresh burrows for their own broods; possibly they infested some one else's lawn the year before or were only in comparatively small {10}numbers on the lawn under notice and so passed unrecognized. They may safely be left alone, as they never seem to breed many consecutive years in one such locality: probably the treatment of a lawn does not suit them, mowing and rolling upsetting their arrangements. We will now consider these arrangements. The female bee, so soon as she realizes that she is charged with the duty of providing for her future offspring, makes a burrow in the ground, and the earth thrown up from the tunnel forms the little heap which is so observable; this burrow varies in depth from 6 to 12 inches and has short lateral branches; each of these she shapes, more or less, into the form of a cell, provisions it with a small mass of pollen mixed with honey for the maintenance of the larva when hatched, and lays her egg; she then seals up that cell and proceeds to the next, and in this way fills the burrow up until pretty near the surface. The bee caterpillar when hatched is a white grub-like creature which, after devouring the food provided for it, becomes more or less torpid; it then makes its final change of skin, after how long a period is probably uncertain, and appears in the nymph stage. {11}<ANTIMG style="width:100%" src="images/Fig1.png" alt="Fig 1. Bombus" title="Fig 1. Bombus" />Fig. 1. Bombus, larva and nymph: after Packard. This stage corresponds to the chrysalis of a moth or butterfly, the creature being shortened up and rather more like the perfect insect compacted into the smallest form possible. People are often misled into the idea that the caterpillar forms the chrysalis over its former self, whereas the chrysalis has been all the time forming inside the caterpillar and only shows itself when the final skin is shed; of course some caterpillars spin a cocoon over themselves before they change their skin, but then the true chrysalis is found inside the cocoon. A curious fact connected with the change from the nymph to the perfect insect is that this takes place sometimes as early as August in the year preceding their appearance; so that cells dug up in August may contain fully fledged insects which are not due to appear till April or May of the following year. It is wonderful also how long life can be {12}sustained by these creatures in the "full-fed larva" condition. Some years ago I collected a number of pierced bramble stems in order to breed out some of the small "sandwasps" which nest in them. On opening them in May, when the perfect insects are generally ready to appear, I found that several of the larvæ had rather shrunk up and had not changed into nymphs. These I left in the stems, covering them up again, and they appeared as perfect insects in the May of the following year. The account given of the nesting habits of the above Andrena of our lawns, etc., is more or less true of nearly all the solitary bees. Their methods vary, some burrow in the ground, some in old wood, some in snail shells, some in bramble stems or straws or the hollow stems of various plants, some in holes or crevices in walls, etc., and their methods of building their cells vary exceedingly: all of these are of great interest and some display an ingenuity which is quite surprising. Of these special nesting habits some of the most striking will be mentioned later on. Before leaving these general remarks on the {13}solitary bees the habits of two genera must be specially noticed, as they differ in an essential point from those of the others. These are known to entomologists under the names of Halictus and Sphecodes. In most species of these the males and females of the new brood are not hatched out till after midsummer, and no work is done for the provisioning of new burrows that autumn; but the female, after having undertaken the duties of maternity, hibernates, i.e. goes back into a burrow and lives there till the next spring, the males dying off before the winter. In the spring the ♀ wakes up and does the necessary work for the future brood just as any ordinary spring bee would—but there are no attendant males—the duties of that sex having been performed in the autumn. The larvæ contained in these burrows hatch out after midsummer and therefore never spend a winter in the ground. In this respect they resemble the social bees and wasps, about which more hereafter; in the meanwhile a few words must be said about the cuckoos or inquilines, which are perhaps the most interesting creatures of all. <hr class="short" /> {14} <h3>THE CUCKOO BEES</h3> These cuckoos live at the expense of their hosts. The mother of the industrial brood makes her cell and provisions it, and lays her egg. The cuckoo bee manages to enter also and lay her egg in the same cell, the usual result being that the cuckoo devours most of the food instead of the rightful offspring, which gradually gets starved and dies, the cuckoo appearing in its place; but there have been cases, how frequent they are is difficult to say, in which both offsprings have emerged. The whole problem of the relationships between host and cuckoo is most interesting. In some cases the cuckoos are so like their hosts that it is difficult to tell one from the other, in others they are so unlike that it is difficult to trace any resemblance between them. There are a great number of different kinds of cuckoos, and most of them select a special host to associate {15}with, and are never found except with that species. There are, however, cases of cuckoos which visit the nests of more than one host, and cases of hosts which are visited by several kinds of cuckoos. In the short-tongued bees, with the exception of Halictus and Sphecodes, the cuckoos are quite unlike their hosts both in form and colour. In the Andrenas (the lawn bee being one of them) the hosts are clothed with reddish, or brown and black, hairs, and are of a more or less stout build (pl. B, 15, 16). The cuckoos are elegant in shape, almost devoid of hairs, and most of them are striped with yellow or brown across the body so that they present a wasp-like appearance (pl. B, 18). Species more unlike one another than host and cuckoo one could hardly imagine; still this stranger seems to get access to the nest of its host without opposition. In a colony of Andrena one may see the cuckoos (which rejoice in the name of Nomada or wanderers) flying about among the females of the industrious bee, and no alarm or concern appears to be felt by the latter. As we go up in the scale of bees, i.e. towards the more specialized, and arrive at those with longer tongues, the {16}cuckoos are found as a rule to resemble their hosts more closely, both in colour and structure, and when we reach the social genus Bombus (i.e. the humble bees) we find the cuckoos so like their hosts (pl. D, 30, 31) that even entomologists of experience mistake one for the other. Apis (the hive bee) has no cuckoo. It seems to be theoretically probable that both cuckoo and host once originated from common parents; this is suggested by the similarity of structure of certain parts of both host and cuckoo, even in cases where they are otherwise most dissimilar. Andrena and Nomada, for instance, which are very unlike, as stated above, agree in both having very feeble stings and in possessing three conspicuous spines on the upper and posterior edge of the orbit of the larva. Also, although Andrena the host has a short tongue, and Nomada, its cuckoo, a long one, the appendages (labial palpi) of the latter's tongue are framed on the same plan as those of the tongue of Andrena, and are quite unlike those of the other long-tongued bees. On the other hand, the cuckoos of the social species resemble them so closely in structure as well as {17}appearance that it is more necessary to search for points of difference than of similarity. There is only one case known of a cuckoo wasp, and that resembles its host even more closely than do the cuckoos of the humble bees. All these points certainly suggest the probability that the social bees and wasps and their cuckoos adopted different habits at a much more recent date than the solitary species, and therefore have not had so much time to become differentiated in structure. The only short-tongued bees which have cuckoos of similar structure are the species of Halictus (pl. B, 12); their cuckoos, Sphecodes (pl. B, 11), are closely allied to them, but then Halictus and Sphecodes are most peculiar genera; although short-tongued, their females spend the winter in the earth, as do the social bees and wasps (see p. 13), and they colonize largely, which may prove to be a step towards socialism. <hr class="short" /> {18} <h3>THE FOSSORS OR DIGGERS</h3> In many respects the insects of this section adopt the same methods as the solitary bees so far as the construction of their nests is concerned, but the food brought home for their offspring is animal instead of vegetable. In order to supply their larvæ with "fresh meat" these little creatures, when they have captured a suitable prey, sting it in such a way that it becomes paralyzed, but does not die; after provisioning a cell with the necessary number of these paralytics, the mother lays her egg on one of them or amongst them, and closes up the cell. In consequence of this wonderful maternal instinct, foresight, or whatever the faculty may be, the larva when hatched finds fresh food ready for consumption. The various species provision their nests with different kinds of foods, and some appear to be most fastidious in their selection, and are said never to err in choosing {19}species of some particular family, thereby displaying a discernment worthy of any advanced entomologist. Some provision their cells with beetles, some with grasshoppers, others with spiders, caterpillars, plant lice, etc. The strength possessed by the female fossor must be proportionately enormous, as she can bring back to her burrow, after paralyzing them, insects many times her own size. It is a most interesting sight to see the excitement and flurry of the captor as it tries to drag along some huge prey to its nest. I remember seeing one dragging along a good-sized caterpillar, of a noctuid moth, over rather rough ground: the poor creature had a difficult job; it had to go backwards itself, and pull the body of the caterpillar, after it—its behaviour was very much like that of an ant which has a large burden; at times it would loose its hold of it and try it from some other quarter; however, by degrees, by pulling and tugging, the prey was safely brought home, but the force expended must have been very great. Many species, however, hunt insects of much smaller size than themselves, and it is those which take a fancy to grasshoppers and {20}caterpillars which seem to be the most doughty in deeds of force. One, a very rare kind in this country, sets its affection especially on the honey bee as a prey; the two insects are about equal in size, but the hive bee must be a dangerous foe to attack, and one would have thought as likely to sting its captor as its captor would be to sting it; also one would imagine that a hive bee, unless thoroughly paralyzed, would be a dangerous subject for a juvenile larva to commence making a meal upon! but whether the venture ever turns out unsatisfactorily there are no data to show, so far as I am aware. The larvæ must vary very much in their tastes; one can imagine that a nice juicy caterpillar, or even a good fat grasshopper, may be appetizing and easily assimilated, but one can equally fancy that the larvæ, who wake up to find their food consisting of small hard beetles, may feel more or less resentment against their parents' ideas of dainties for the young! Still they seem to thrive on it, and come out eventually as exact likenesses of their parents. A large number of the fossors inhabit dry sandy wastes, such as the dunes along the sea coast at Deal, Lowestoft, {21}etc.; many of these, when they leave their burrows, throw up some sand over the hole so as completely to cover it; how these insects find the spot again after a lengthy chase after spiders or other prey is a marvel; and yet those who have observed carefully say that they come home from long distances with unerring precision. No sense of which we have any knowledge, however accentuated, seems to explain this. To be able to arrive back at a home in an extensive arid sandy plain, where no outward sign indicates its whereabouts, must surely require perception of a different nature from any of those with which we are endowed. Some fossors are subject to the depredations of cuckoos, just as the solitary bees are, but their cuckoos are rarely of aculeate origin. The only ones which I have had any opportunity of studying are the species which nest in bramble stems. The cuckoos which associate with them are some of the smaller jewel flies and Ichneumons: the habits of both these differ from those of the aculeate cuckoos, the jewel flies devouring the larva of the aculeate and the Ichneumon laying its eggs in it. The fossors {22}<ANTIMG style="width:100%" src="images/Fig2.png" alt="Fig 2. Ammophila" title="Fig 2. Ammophila" />Fig. 2. vary exceedingly in size, shape and colour. Our largest species are about an inch long and our smallest about the eighth of an inch, nearly all having the body where it joins the thorax constricted into a very narrow waist; this is sometimes of considerable length. In one genus known to entomologists by the name Ammophila (fig. 2) or "lover of the sand", the waist is practically the longest part of the body, so that looking at one sideways as it flies along, one could almost be deceived into thinking that there were two insects, one following the other (cf. pl. A, fig. 7). In colour, there seem to be three dominant schemes: Black (cf. pl. B, fig. 17); black with a red band across the body (cf. pl. A, fig. 7); and black banded with yellow, like a wasp (cf. pl. A, figs. 6 and 8, etc.) In some the yellow bands may not be complete, and appear only as spots on each side of the body segments, or the red band may be almost obliterated, or the black species may {23}<ANTIMG style="width:100%" src="images/Fig3.png" alt="Fig 3. Spines of Ammophila" title="Fig 3. Spines of Ammophila"/>Fig. 3. <ANTIMG style="width:100%" src="images/Fig4.png" alt="Fig 4. Spines of Ammophila" title="Fig 4. Spines of Ammophila"/>Fig. 4. be more or less variegated with yellow spots on the head and thorax, but as a general rule all our species fall into one or other of these colour schemes. The females of some of our sand frequenting species have beautiful combs on their front feet, each joint of the tarsi having one or more long spines on its external side (figs. 3 and 4). These are of importance to them in their burrowing, as they enable them to move with one kick of their front leg a considerable amount of the dry sand in which they make their nests. Although sandy commons, etc., are the resort of many fossors, others may be found burrowing in wood or in hard pathways or banks; in fact, like most other insects, some of their members may be found almost anywhere. <hr class="short" /> {24} <h3>THE SOLITARY WASPS</h3> The ordinary wasps are acquaintances of every one, but the solitary or keyhole wasps are not so well known, although they are far from uncommon. They are little narrow black insects striped across the body with yellow, belonging to the genus Odynerus (pl. A, 9), and might hardly be recognized as belonging to the same family as the true or social wasps. Still they have considerable powers of stinging, and fold their wings lengthwise when at rest like their larger relatives. I dare say some people may have noticed that a wasp's wing sometimes assumes a narrow straight form, quite unlike what it is when expanded. This is due to the wasp being able to fold its wing lengthwise like a fan. The wasp tribe are, so far as I know, the only stinging Hymenoptera which have this power. <div class="figright"> <ANTIMG style="width:100%" src="images/Fig5.png" alt="Fig 5. Entrance to wasp hole" title="Fig 5. Entrance to wasp hole" /> Fig. 5.</div> They make their nests of mud, etc., in crevices of walls, in banks, in plant stems, and often {25}in most inconvenient places, such as keyholes, etc. Some of the solitary wasps have a very curious habit of making a tubular entrance to their hole. These may sometimes be seen projecting from sandy banks. The tube is composed of a series of little pellets of mud, which the wasp by degrees, with the help of its mouth secretions, sticks together till a sort of openwork curved tube of sometimes an inch long is formed (fig. 5). This curve is directed downwards, so that the wasp has to creep up it before reaching the actual orifice of the nest. It looks as if the first shower of rain would wash the whole structure away, and I have very little doubt that it often does so. The object of these tubes is difficult to appreciate. There is a bee on the continent which makes straight chimneys above its holes, so as to raise the entrance above the surrounding herbage; possibly these solitary wasps once required {26}their tubes also for some such purpose, and have continued on truly conservative lines to build them long after all usefulness has passed away from the habit; anyhow they are very interesting and beautiful structures. I have found the tubes of one of our rarer species projecting perpendicularly out of the level sand, but even then the tubes were curved over at the end, so that the wasp had to go up and down again before entering its actual hole. The Rev. F. D. Morice in 1906 found the tubes of the same species in numbers projecting from the walls of an old stuccoed cottage situated close to the locality where I found mine, so it is evident that more than one situation suits its requirements. The solitary wasps provision their cells with caterpillars, stinging them in the same way as the fossors do. One very peculiar genus, of one species only in this country, has its body much narrowed at the waist by reason of the constricted form of the basal segment; it makes a little round nest of clay which it suspends from a twig of heather or other plant. This species is rarely met with except on the heathery commons of Surrey, Hants, Dorset, etc. The {27}solitary wasps are subject to the attacks of cuckoos belonging to the jewel fly or Chrysis tribe; these behave differently from those belonging to the aculeate groups, as their larvæ do not eat the food laid up for the wasp, but wait till the wasp larva has finished feeding up, and then devour it. Unlike as these cuckoos are to their hosts in their brilliant metallic coloration, etc., they have structural characters curiously like theirs, so that even here a common parentage in bygone generations may be reasonably suspected. At present, however, they are placed, except by a few systematists, in quite distinct families of the Hymenoptera. In general form these solitary wasps resemble the fossors more than the bees; they have mostly short tongues (I think all our British ones have), and their hairs are simple or more or less spirally twisted. <hr class="short" /> {28} <h3>THE SOCIAL GROUPS</h3> The social bees are certainly the most highly specialized of the Anthophila, and the social wasps of the Diploptera or insects with folded wings. The ants occupy a less definite position: they would seem to be the outcome of specialization among the fossors, only they feed their young with vegetable juices and not with animal as the latter do. They are always kept as a separate tribe under the name Heterogyna, but for our purposes the better known word "ant" will suffice. The hive bee and the social wasps are the only British Hymenoptera which adopt the hexagonal cell-formation in their nests, the bee fashioning its cells in wax, the wasps and hornet in masticated wood or paper. The formation of ants' nests is far less regular, being composed of irregular passages, called galleries, and open spaces, no doubt built on a plan, but probably {29}in respect of plan no two nests are exactly alike. The humble bees again differ from either in their nesting habits: the female in the spring seeks out a mouse's nest or other suitable foundation of moss, etc., in or on the surface of the ground, according to the species. This she lines with wax, deposits a heap of pollen, and lays her eggs in it. She also makes waxen cells for honey, but these are not hexagonal and symmetrical as are those of the hive bee, but are more like little pots, and are known as "honey pots". It must be borne in mind that the economic arrangements of the wasps and humble bees only last for a single season, whereas those of the ant and hive bee exist for many years. In consequence of this the swarming habits belong exclusively to the ants and hive bee. That of the hive bee is well known to all, and most people must have observed the swarms of male and female ants which fill the air on some sultry summer or autumn evening. Thousands of these must perish, but a certain number of the females accept the responsibility of starting a fresh nest, and so the ant population is kept up. {30}It will be seen from these remarks that the three social groups are very distinct in their methods of nest making, and have really very little in common except the social habit. The humble bees have their cuckoos; one species of wasp has a cuckoo, and there is a possible case of a cuckoo amongst the continental ants, but this has not yet been observed in this country. The ants harbour so many species of insects in their nests besides their own family that it is difficult to form an idea as to whether the case in question is at all analogous to that of host and cuckoo in the other aculeates or not. <hr class="short" /> {31} <h3>THE ANTS</h3> These little creatures are probably the most intelligent of all the insects—and yet at times they seem to wander about almost aimlessly. A worker may be found with an insect or something which it is eagerly dragging along and drops probably from fear. It appears anxious to regain its hold of it, but goes about in all sorts of wrong directions before it again finds it, it may be to make sure its enemy is clear away before it resumes operations, but the effect to the ordinary onlooker is one of sheer incapacity—at the same time the wonderful habits of the tribe, the way in which they keep plant lice for their larvæ, their methods of carrying each other, their nest-building, and the slave-making instincts of some of the species, show an intelligence surpassed by no other family of insects. Their nests are formed in very various ways: the same species even will sometimes nest under a stone and sometimes make ant hills; some {32}of the large species make their nests of huge heaps of fir needles, and number 400 to 500 thousand in one nest—others live in quite small communities, nesting in bramble stems, old rotten wood, moss, etc. One little species, rare with us, lives in the walls of other ants' nests, just as mice live in the walls of our houses; another quite small species lives apparently on friendly terms with the common large red or horse ant, and may be found running about amongst them, on and in their nests, but, so far as I know, nothing is known as to how its young are reared. There is a curious division in the family between the ants that have true stings and those which have not. The large ants of our fir woods can bite and are able to eject poison through the apical opening of the body into the wound they create, but these as well as the larger and smaller black ants and some others have the sting undeveloped, whereas some of our small species have a sting which they can use with considerable effect; this difference in habit is accompanied by a difference in the structure in the basal segments of the body. In the stingless species the basal segment is reduced {33}<ANTIMG style="width:100%" src="images/Fig6.png" alt="Fig 6. Basal segments of ants" title="Fig 6. Basal segments of ants"/>Fig. 6 to a flat upright transverse scale (fig. 6, 1); in the stinging ants two segments at the base are reduced to nodes (fig. 6, 3). There is an exception in the case of one little rare genus, Ponera, which has only the basal abdominal segment reduced to a scale although a much thicker scale than in the others (fig. 6, 2), and yet which has a distinct sting. These arrangements give the body very free movement so that the tail can be bent forward till it reaches the head. Another curious distinction between the stingers and non-stingers is that the larvæ of the former spin cocoons and those of the latter do not; the larvæ of Formica fusca occasionally do not do so, but they are an exception to the rule. Cocoon spinning seems to involve the larvæ in some difficulties, as without the help of the worker ants they are often unable to extract themselves from their prison. This is a condition which does not, I believe, exist in other groups. In the stingless ants there is a curious difference in habit between the {34}species of the genus Formica, where, according to Forel, the workers do not follow in line over unknown ground, and frequently carry one another, the one carried being rolled up under the head of the other, and the species of Lasius, where the workers follow one another in line, but never carry each other. Among the stinging ants another method of carrying occurs in certain genera. The porter seizes the one she wishes to carry by the external edge of one of her mandibles and then throws her over her back, so that she lies along the back of her porter with her ventral aspect uppermost and her legs and antennæ folded as in the nymph state. Neither of these methods sounds very comfortable, but then probably an ant's idea of comfort and our own may be very different. Lord Avebury, in his Ants, Bees and Wasps, tells us that he has known a male of Myrmica ruginodis live for nine months, although no doubt, as he says, they generally die almost immediately, and he has known queen ants to live for seven years, and workers, which he had in his nest, for six years. <hr class="short" /> {35} <h3>THE SOCIAL WASPS</h3> Of these we have only seven different kinds, and with the exception of the hornet they are all very much alike. One often hears people say that they have seen such a large wasp that they think it must have been a hornet, but no one who has ever seen a hornet could mistake a wasp for one. A hornet is red-brown with yellow markings (pl. B, 13), a wasp is black and yellow, and altogether a less formidable-looking creature (pl. B, 14). Even a queen wasp is not so large as a small worker hornet. The hornet nests in hollow trees, our three commoner wasps nest, as a rule, in the ground, but occasionally in outhouses, under roofs, etc. One of the others as a rule makes its nest in shrubs, but occasionally in the ground, another always nests in a bush or shrub, preferring a gooseberry or currant bush, and the only remaining one is a cuckoo of one of the ground species. The gooseberry-bush {36}wasp is not a common species in the south, but in the midlands and north it is abundant. Wasps will eat most things, but are especially fond of syrups and sweets. One species, Vespa sylvestris, which seldom enters our houses, is very partial to the flowers of Scrophularia (Figwort). One rarely finds a plant of this in full blossom without finding its attendant wasps. I have seen other species of wasps also visiting it, but sylvestris is practically sure to be there. The diet which wasps provide for their larvæ is probably a mixed one, but consists largely of insects. Dr. Ormerod says that a microscopic examination of the contents of a larval stomach shows "the mass to consist of scales, hairs and other fragments of insects, hairs of vegetables and other substances less easy of recognition." <div class="figcenter"> <ANTIMG style="width:100%" src="images/PlateB.png" alt="Plate B" title="Plate B" /> Plate B. 10. Colletes succinctus, female. 11. Sphecodes subquadratus, female. 12. Halictus leucozonius, female. 13. Vespa crabro, female. 14. Vespa vulgaris, female. 15. Andrena fulva, male. 16. Andrena fulva, female. 17. Panurgus banksianus, female. 18. Nomada ruficornis, var. signata, female. 19. Epeolus rufipes, female. [face p. 36. </div> {37} Wasps do not store honey in their nest; the papery nature of their cells would make such storage impossible. I dare say some of my readers will have noticed wasps sitting in the sun on a wooden paling busily engaged apparently eating something—they are really pulling off little fibres of wood which they chew up into a substance fitted for the walls of their cells; they will also chew paper, and the experiment has been tried of giving them coloured papers, which resulted in stripes of colour appearing in their nests. The different species vary somewhat in the architecture of their nests; but they are built very much on the same general plan. The population of some underground nests is very large. The Rev. G. A. Crawshay estimated the number in a large nest of Vespa vulgaris, which he took on September 20, 1904, at about 12,000; of these he actually counted, including eggs and larvæ, 11,370, and estimated the rest as having left the nest and escaped, so that anyhow the computation cannot be far wrong. This, however, was probably a very large nest. The cuckoo wasp (Vespa austriaca), formerly known as V. arborea, is an associate of Vespa rufa; its habits had been suspected for a long time, but Mr. Robson set all doubts at rest by finding the nymphs of the cuckoo in the actual nest of rufa. It is a rare species in the south, but far from uncommon as one goes north, and also in Ireland, where the relationship of the host and cuckoo have been {38}carefully studied by Prof. Carpenter and Mr. Pack Beresford. Vespa vulgaris has a beetle parasite, but this is somewhat of a rarity. This creature Met&oelig;cus paradoxus lays its egg in the cell of the wasp, and enters the body of the larva, eventually entirely devouring it. The hornet also has a beetle associate, but this is a great rarity. It is a large black species of the "Devil's coach horse" or "Cock tail" tribe (Velleius dilatatus), but in what relation it stands to the hornet beyond inhabiting its nest is not known. <hr class="short" /> {39} <h3>THE HUMBLE BEES</h3> Of these beautiful creatures we have thirteen kinds in this country. Their velvety clothing and bright colours make them the favourites of most people. They are most industrious and may be seen on the wing from early morning often till quite late on summer evenings, whereas the solitary bees do not, as a rule, commence work till nine or ten in the morning, except in very hot weather, and generally retire about four or five p.m. There is an idea prevalent that humble bees do not sting, but this is fallacious. They can sting pretty severely, but I do not think they are so ready to use their defensive weapon as a wasp or hive bee is. The length of the tongue in these creatures makes them of great value to the farmer and gardener, as they can fertilize the red clover and probably other flowers which require a longer tongue to reach the nectary than is possessed by the hive bee. {40}In New Zealand, when first the red clover was introduced from this country, it was found impossible to fertilize it, and humble bees had to be sent out. Now they are established there its fertilization is carried on quite successfully. The humble bees are divided into two natural groups, the underground species, i.e. those that make a subterranean nest, and the carder bees, as they have been called, which make a nest on the surface of the ground. The former live in much larger communities and are far more aggressive and pugnacious than the latter. They also feed their young, according to Mr. F. W. L. Sladen, of Ripple Court, in a different way. The carder bees "form little pockets or pouches of wax at the side of a wax-covered mass of growing larvæ into which the workers drop the pellets of pollen direct from their hind tibiæ. The pollen storers, on the contrary, store the newly gathered pollen in waxen cells, made for the purpose, or in old cocoons, specially set apart to receive it, from which it is taken and given to the larvæ mixed with honey through the mouths of the nurse-bees as required." As the author remarks, the methods of the underground {41}species more resemble those of the hive bee than do those of the carder bees. Mr. Sladen has made many experiments in trying to domesticate humble bees, and succeeded so far with Bombus terrestris (pl. D, 29, our common black and yellow banded species with a tawny tail) as to get it to breed in captivity, and in 1899 was able to show nests in full work at the Maidstone agricultural show, the bees coming in and out of the building to their nest. An interesting case of one of the carder bees (Bombus agrorum) is recorded by F. Smith. It invaded a wren's nest, heaping up its pollen, etc., amongst the eggs of the bird, till the parent bird was forced to desert the nest. The underground species are more subject to the attacks of cuckoos than the carder bees. Altogether the humble bees afford an excellent subject for study, as they appear to be amenable to treatment, and to any one who could give time and careful attention to them many interesting problems connected with them and not yet understood might have light thrown upon them. Dead humble bees are often found in numbers in a mutilated state, under lime trees. These {42}have been caught after they have filled themselves with honey, and become torpid in consequence, by the great tomtit and possibly other birds. The bird pecks a hole in the insect's thorax, enjoys the honey it has eaten and then drops the quivering body which falls to the ground. I once had the opportunity of seeing this slaughter going on, and was able to detect the great tomtit as the murderer. In colour the humble bees vary remarkably, the variation occurring chiefly in the females. This variation is not so noticeable in this country, although in many species even here the variability is very great, but when we trace a common species such as terrestris, which varies very little here, over a large area such as the Palæarctic region its liveries are so diverse that its females have been treated as belonging to many different species. In the Siberian district its yellow bands become of a pale, almost whitish or straw colour, and the whole appearance of the insect is altered. If, instead of going north, we go to the Mediterranean region we find a large, fine form tolerably common, with bright yellow hairs on the legs. In Corsica {43}again we find a quite different form; entirely black except for the bright red hairs on the apex of the body, and bright red tibiæ, clothed with red hairs. In the Canaries another coloration occurs: the whole insect is black with the exception of the apex of the body which is clothed with white hairs; but in all these the male varies comparatively little. In the Siberian and Canary forms it resembles the female, but in the others it varies very little from some varieties we find here. A rather similar series of varieties occurs in Bombus hortorum, another species little liable to variation here. In Italy and south-east Europe a form with entirely black body and black wings occurs, and in Corsica a black form with reddish hairs on the apical segments. The male keeps throughout very constant to its normal coloration. The tendency to vary towards an entirely black form seems to exist in nearly all the species, although in Britain black varieties of some are very rare. <hr class="short" /> {44} <h3>THE BEES WITH BIFID TONGUES</h3> In this country we have only two genera in which the tongue is bifid at the apex, and on this account they are kept together as close allies in our classification. They are, however, very different in general appearance. One of these groups is called Colletes, on account of its habit of lining its cells with a gluey material, the other, Prosopis, on account of the markings on the face. The various kinds of Colletes are densely clothed on the head and thorax with brownish hairs, and the segments of the body have whitish bands composed of a dense, tight-fitting, duvet of hairs (pl. B, 10). There is in this country only one exception, a large insect like a hive bee, but rarely met with, its headquarters being the Wallasey Sandhills near Liverpool, and other localities in Lancashire. All the species tend to colonize; some building in huge colonies {45}in sandy cuttings, etc. They are preyed upon by a pretty little cuckoo bee called Epeolus (pl. B, 19), which is black, ornamented with brownish red and whitish spots. One of our best known species, Colletes fodiens, can often be found in abundance on the heads of ragwort along the sea-coast in July. The other genus Prosopis is outwardly entirely unlike Colletes: its species are nearly all very small coal-black insects, with scarcely any noticeable hairs, rather unusually narrow and cylindrical in form; they emit a peculiar, agreeably scented fluid when handled; in the males the face is almost always white or yellow, in the females there is generally a yellow spot on each side near the eye. These little creatures are especially fond of burrowing in bramble stems. They like those which have been cut off in trimming the hedges, because in them the pith is exposed and they can burrow their way into it without gnawing through the wood. If any one, going along a hedge which has been trimmed, containing a lot of brambles, in the autumn or winter, would examine the cut-off ends they would soon find some with holes in them. These {46}may be the work of Prosopis, but there are other bees and fossors which also burrow in this way. So the stems should be brought home and opened. Then the Prosopis cells may be known by the fine membranous pellicle which surrounds them, but possibly even then a little jewel-bee cuckoo may be found in possession of the cell, instead of the rightful owner. When these little bees emerge they are generally to be found on wild mignonette, bramble flowers or those of the wild parsley tribe. Some are very common, others of great rarity. The males of this genus seem to have a peculiar tendency to develop eccentricities in the shape of the first joint of the antennæ, or feelers, some having it expanded and concave, others rounded but thickened towards the apex; in only one British species, P. cornuta, does the female show any special peculiarity of form, but in this the face is produced on each side between the eyes into a distinct horn-shaped process. In the females there is scarcely any indication of pollen brush, and for this reason they used to be considered as possessors of cuckoo instincts, but there is now no doubt of their industrious habits; but {47}there is no other genus of industrious bees in this country, with the exception of Ceratina, with so little specialization for pollen collecting. <hr class="short" /> {48} <h3>THE BEES WITH POINTED TONGUES</h3> All the genera, except the two mentioned in the last chapter, belong to this section, which comprises a variety of very different styles of bees, beginning with the short spear-shape-tongued species and ascending to the long-tongued species, which are considered to culminate in the hive bee. The habits of these genera vary very greatly in some respects; special notice has been or will be given of Halictus (pl. B, 12) and Sphecodes (B, 11), Andrena (B, 15, 16), Nomada (B, 18) and the other cuckoos, Osmia (D, 28) and Anthophora (D, 24, 25) and the leaf-cutting bees, but there are several other genera which deserve a passing notice, although their habits are not so peculiar as those of the specially selected ones. Cilissa, which is a very close ally of Andrena, is peculiar in having the hairs of the tongue erect and arranged almost in bottle-brush fashion. Its habits are much like those of {49}Andrena. Dasypoda, so called on account of the enormously long hairs of the pollen brushes of the legs in the female, is one of our most beautiful bees; it is of moderate size, a little more than half an inch long, with a brown haired thorax, and a black body with white apical bands on the segments; the hind legs are rather unusually long and the brush is composed of very long bright fulvous hairs, and when the bee returns home laden with pollen it is, as F. Smith says, "sufficiently singular to attract the attention of the most apathetic observer." It burrows in sandy places much after the fashion of Andrena, etc. The male is a different looking insect, entirely covered with yellowish hairs. Panurgus (pl. B, 17) is a curious genus of coal-black bees, whose females have bright yellow pollen brushes on their hind legs; they visit yellow composite flowers and the males often sleep curled up amongst their rays; they are most active bees, and burrow generally in hard pathways. I was watching a large colony of one of the species near Chobham in the end of June—they were burrowing in a gravel path, under which the soil was of a black sandy nature; the path was scattered all over with little black {50}hillocks of sand, and seemed alive with bees. It was showery weather, and occasionally the hillocks were washed nearly flat and a lot of sand must have entered their burrows—however, as soon as the sun came out again they cleaned out their holes and returned to their work. Panurgus is most businesslike in its pollen collecting; it flies in a rapid headlong way into a flower, and seems to do its best to bury itself, with a remarkable amount of action as if it was in a great hurry, and often bustles out of it again almost immediately and goes on to the next. Its methods suggest that it does more work in five minutes than any other bee would do in ten. Another genus, Anthidium (pl. D, 27), this time one of the long-tongued bees, is peculiar in having the male larger than the female. Both sexes are black, variegated with yellow markings and spots, but the male is more ornate in this respect than the female and also has a peculiarly shaped body, which is unusually flat, curving downwards towards the apex, which is armed with five teeth, two bent ones on the sixth segment and three on the seventh. The female collects pollen on the underside of its body and collects the {51}down off the stems of various plants, especially those of the dead nettle or "labiate" tribe, with which it invests its cells. I cannot do better than quote the following from F. Smith: "This is the social bee which White in his History of Selbourne has so well described in the following words: 'There is a sort of wild bee frequenting the Garden Campion for the sake of its tomentum, which probably it turns to some purpose in the business of nidification. It is very pleasant to see with what address it strips off the pubes running from the top to the bottom of a branch and shaving it bare with the dexterity of a hoop shaver; when it has got a vast bundle, almost as large as itself, it flies away, holding it secure between its chin and fore legs.'" <hr class="short" /> {52} <h3>LEAF-CUTTING BEES</h3> <div class="figright"> <ANTIMG style="width:100%" src="images/Fig7.png" alt="Fig 7. Leaf cut by bees" title="Fig 7. Leaf cut by bees" /> Fig. 7.</div> These are amongst the specially interesting of the bees in their habits. They are dull-brown coloured creatures rather like a stout hive bee in form (pl. C, 20). They all collect pollen on the underside of their body. They burrow either in decayed wood or in the ground, but they make their cells of pieces of leaves which they cut off from rose bushes or other plants; these cells when completed are wonderful works of art. Probably some of my readers may have noticed rose leaves with semicircular pieces cut out of them, and often with almost circular ones; this is the work of the leaf cutter (fig. 7). <div class="figcenter"> <ANTIMG style="width:100%" src="images/PlateC.png" alt="Plate C" title="Plate C" /> Plate C. 20. Megachile maritima, female. 21. C&oelig;lioxys conoidea, male. 22. C&oelig;lioxys conoidea, female. 23. Nest of Megachile willughbiella. [face p. 52. </div> {53} She alights on a leaf, holds on to the edge of the piece she wants to cut off with her legs, and then cuts it out by means of her jaws, or mandibles; as soon as it is cut free she uses her wings and so prevents herself from falling, and goes off with the cut off piece safely held under her body by her legs. I have frequently seen bees flying home with their leafy burden, and once or twice I have seen them cutting the pieces out. They cut round the piece they select with great rapidity—the marvel is that they can arrange so exactly as not to fall when the last attachment is removed. The pieces they cut have to be of several shapes in order to build up the cell they require; some are more or less lozenge shaped, some almost circular; the cells they make are somewhat thimble-shaped. The lozenge-shaped pieces are used to build up the sides and lower end of the cell, and the circular pieces to close it in with at the top; it is all cemented together with a gluey substance excreted by the bee. The burrows of the leaf-cutters are made, as stated above, either in the ground or in rotten wood. I have never had a subterranean nest to examine, but have had several nests in rotten wood under my notice, one of which is now before me (pl. C, 23). It is in a piece of very {54}soft willow, almost in a touchwood condition. So that by carefully cutting away the wood I have been able to expose the whole series of cells. Two distinct burrows run almost parallel to each other; both of them are slightly curved and each has contained six cells; these are about half an inch long, and they fit one over another in the tube as closely as possible so as to look like two long thick green worms. Each cell is composed of many pieces of leaf, and the final plug which closes the cell is often made of several rounds of leaf one over the other. The amount of labour taken by the mother bee to make these cells must be enormous. The cells are provisioned like those of any other solitary bee with pollen, etc., and the egg is laid upon it. Most of the leaf-cutters have their attendant cuckoos, which are rather smaller than themselves, of a deep black with white bands on the sides of the body. The female has a very pointed tail, and the male's body ends in a series of spine-like projections (pl. C, 21, 22). <hr class="short" /> {55} <h3>OSMIA AND ITS HABITS</h3> I have tried as much as possible to avoid scientific names, but the misfortune is that there are hardly any popular names in use which can be attached for certain to any particular species, and unless this can be done it is of no use using vague names like the "Carpenter Bee", the "Mason Bee", etc. There are many carpenter bees and many mason bees, and though their habits may be alike in this one particular they differ among themselves in the way they use their tools, and it is necessary to know which one we are talking about. It is a common thing to hear people inveighing against Latin names, etc., but they forget that there are no English ones in use, and what is more important, that Greek and Latin names are common property to all nations, so that we can all know what we are talking about, whereas if we call an insect by an English name and the Russians {56}call it by a Russian name, the difficulty of coming to a mutual understanding is very great. This is only an aside to justify the use of classical names. I quite feel that for popular use in this country a good series of English names might be useful, but we have not got one, and it would require a great deal of care and thought to frame a nomenclature which would really be useable by the persons who require it. I have made these remarks here because Osmia is a genus whose members vary very much in their habits, and some species of which, like sensible beings, adapt their habits to their surroundings, so that no name such as carpenter bee, etc., would apply to all the species, or, as a rule, even to one. Osmia rufa especially adopts several methods of nesting. This little bee is clothed more or less all over with yellowish hairs; it is compact in shape like all the other species of Osmia, and like them collects its pollen on the underside of the body. It may sometimes be seen flying up and down the walls of a house looking for a crevice to build in, but it is not the least particular as to where to form its cells. In one memorable case the female selected a flute {57}which had been left in a garden-arbour. The bee constructed fourteen cells in the tube of the instrument, commencing its first cell a quarter of an inch below the mouthhole. The flute is preserved in the Natural History Museum at South Kensington. At other times this species burrows in the ground, at others it makes its cells in crevices of old walls; it has been known to build in a lock, and is said sometimes to inhabit snail shells. Other species of Osmia almost always burrow in banks, but in no case does a habit seem to be uniformly adopted by a species. One well known and rare species, Osmia leucomelana, is a regular bramble-stick species, tunnelling down the pith in the centre of the stalks, but I once found it to my surprise in fair numbers nesting in a sandy bank. Other species again, as a rule, select snail shells to build in; they find an old disused shell lying about in some sheltered place and adapt it to their purposes, commencing their cells singly in the narrow whorls of the shell and side by side as they approach its mouth, i.e. if the shell be a wide-mouthed one like the common garden snail (Helix aspersa). F. Smith, who gives a very interesting account of these {58}creatures in his Catalogue of British Hymenoptera in the British Museum, mentions a case where the bee finding the larger whorls of the shell too wide constructed two cells across the whorl. Another very interesting case given by Smith is of a nest of many cells of the rare Osmia inermis (which in his days was known as Osmia parietina). A slab of stone, 10 inches by 6, was brought to him with 230 cocoons of this Osmia attached to its under side; when found in the month of November, 1849, about a third of them were empty; in March of the following year a few males made their appearance and shortly afterwards a few females, and they continued to come out at intervals till the end of June, at which time he had 35 cocoons still unopened; in 1851 some more emerged, and he opened one or two of the closed ones and found that they still contained living larvæ; he closed them up again, and in April, 1852, examined them and found the larvæ still alive; at the end of May they changed to pupæ and appeared as perfect insects, the result being that some of the specimens were at least three years before reaching maturity. {59} There is a nest of yet another style adopted by one of our species (Osmia xanthomelana). This is formed of a series of pitcher-shaped cells made of mud, constructed at the roots of grass. The species which makes it is rare and seems to have its headquarters on the coasts of Wales, although it has occurred in the Isle of Wight and elsewhere. This species also is not constant in its habits, as it has been known to make its cells underground. A very curious habit was noticed some years ago by Mr. Vincent R. Perkins in another species of this genus (Osmia bicolor; pl. D, 28); the species nests in the ground or in snail shells, but, in the case under his observation, Mr. Perkins found that the little bees covered up all the snail shells in which they had built their cells with short pieces of "bents" so as to make a little hillock over each about two or three inches in height, somewhat resembling a miniature nest of Formica rufa, the large horse ant, each mound containing hundreds of pieces. This is the only record I know of this habit, which must entail a large amount of labour for the bee. These varying habits in the same species {60}show pretty clearly that these little creatures are not driven by any blind instinct in the adoption of their methods of nest building: they appear to have a distinct power of choice and adaptation according to their environment, unless of course it can be shown that the offspring of, say, a snail shell inhabitant follows its parents' habits, and that that of a ground borer does the same—but even that would not explain the case given by F. Smith, and quoted above, where an Osmia had filled up the whorls of a shell and then, finding the final whorl too large, placed two cells horizontally to fill it: that seems to indicate distinct design on the part of the bee and would be hard to explain as due to instinct. Unfortunately, with the exception of a very few, the species of Osmia are rare in this country, so that few opportunities are available for studying their habits, which are certainly amongst the most interesting of any genus. <div class="figcenter"> <ANTIMG style="width:100%" src="images/PlateD.png" alt="Plate D" title="Plate D" /> Plate D. 24. Anthophora pilipes, male. 25. Anthophora pilipes, female. 26. Melecta armata, female. 27. Anthidium manicatum, female. 28. Osmia bicolor, female. 29. Bombus terrestris, female. 30. Bombus lapidarius. female. 31. Psithyrus rupestris, female. [face p. 61. </div> {61} <h3>A COLONY OF ANTHOPHORA</h3> Anthophora pilipes (pl. D, 24, 25), one of our early spring bees, often forms enormous colonies. I have sometimes seen sandpits in which the sides were riddled all over with holes of this species, and where the insects were in such numbers that a distinct hum was audible from the vibration of their wings. In such colonies one is sure to detect some of their cuckoo associates, Melecta armata (pl. D, 26). They are deep black bees, much of the same size as their hosts but with more pointed tails and with a small spot of snow-white hairs on the side of each segment of the body; like other cuckoos they sail about in a more demure way than their hosts, but a more lively scene than a large colony of Anthophora can hardly be found. The Anthophora provisions its cells with honey and pollen, and its egg in consequence floats on the top—the {62}number of cells varies from five or six up to ten or eleven. Anthophora pilipes has a very close relative in Anthophora retusa, which also forms large colonies, but it is as a rule less common. These two species are exceedingly alike, in fact it requires some skill on the part of the observer to differentiate their females. They are both black and clothed with black hairs, and both have yellow pollen-brushes, but in retusa the hairs are shorter and not quite of such a deep black as those of pilipes, and the spurs of the tibiæ are pale, whereas in pilipes they are black. The males, however, differ widely, although much alike in colour; in pilipes the feet of the middle pair of legs are clothed with enormously long hairs, the basal joint has a dense fringe of black hairs in front and some long black hairs behind (see pl. D, fig. 24); in retusa the basal joint of the middle pair of feet have a fan-shaped fringe of black hairs, and the rest of the joints are clothed with longer hairs, but not long enough to be specially noticeable. A. retusa is visited by the same cuckoo as A. pilipes and also by its rare ally Melecta luctuosa, which only differs from armata {63}(pl. D, 26) in the larger and squarer spots of the body and various small structural characters hardly appreciable except by specialists. The Anthophoras have other parasites besides their cuckoos; one is a beetle, which, however, is rare, and which lays its egg in the Anthophora cells; the other is a very minute member of the Hymenopterous family, whose larva when hatched feeds upon the larva of the bee. Notwithstanding these disadvantages both species are abundant, although retusa is more local than pilipes. A very interesting fact connected with this genus has just been communicated to me by the Rev. F. D. Morice. John Ray, who lived in the seventeenth century, mentions in his book Historia Insectorum (published posthumously in 1710), p. 243, that a large colony of a bee, which from his description was clearly an Anthophora, as he specially calls attention to the great difference between the males and females, inhabited a certain locality at Kilby near "Hill Morton" in Northamptonshire. Mr. Morice, who for many years resided at Rugby, knew Hillmorton, as it is now spelled, well, and tells me that a large colony of Anthophora was in that same locality when he knew it only {64}a few years ago. Of course there is no proof that it has been there throughout the intervening period, but there seems to be no reason to doubt it, and if so it is a most interesting case of a persistent colony. <hr class="short" /> {65} <h3>BEES AND POLLEN-COLLECTING</h3> Bees whether solitary or social enter flowers for the sake of the honey in their nectaries and the pollen on their anthers. In some cases the flowers automatically deposit pollen on the bees during the operation, which enables them to fertilize other flowers of the same species, but the pollen which the bee requires for its own use has to be worked for and collected on organs specially adapted for the purpose. These vary very much in the different families and genera; they exist only in the females, and, if the males get covered with pollen, as they often do, it is probably more by chance than purpose, and it is doubtful if it is of any value to the brood, although no doubt useful in fertilizing other flowers. All our bees, as has been pointed out before, are clothed more or less with branched or feather-like hairs, which would appear to be admirably adapted for the collecting of pollen. {66}At the same time some species which have their bodies clothed with branched hairs have simple or spirally grooved hairs on the collecting organ—others collect on very much branched hairs—so that there seems to be no exact relationship between the plumosity of the hairs and their utility in collecting. The collecting brushes are either on the hind legs or, as in some cases, on the ventral surface of the body. In a female Andrena, the hind leg has a tuft of curled hairs near the base of the leg, and a more or less heavy brush on the outside of the tibia or shin (fig. 8). When a female returns after a collecting expedition these specially hairy regions are a mass of pollen grains, and the "beautiful yellow legs", so often remarked upon in some bees, are not always due to the colour of the hairs but to that of the grains of pollen adhering to them. The genera which collect on the under surface of the body have to visit flowers where the anthers lie in such a position that they can transfer the pollen on to it; the pea flower tribe are favourites with them, and also the Compositæ. All this section have long tongues so that they are able to reach the nectaries of {67}<ANTIMG style="width:100%" src="images/Fig8.png" alt="Fig 8. Leg hairs of Andrena" title="Fig 8. Leg hairs of Andrena"/>Fig. 8. <ANTIMG style="width:100%" src="images/Fig9.png" alt="Fig 9. Corbicula of humble bee" title="Fig 9. Corbicula of humble bee"/>Fig. 9. plants with long tubular flowers. In visiting these the pollen is often deposited on the back of the bee; this it is able to transfer to its under side by means of the brushes on its feet or tarsi. The arrangements of the humble bees for pollen gathering are altogether different from those mentioned above. They have the hind shin outwardly shining and rather concave, with a series of long curved hairs running down each side of it and partly curving over it, so that they carry their mass of pollen in a sort of basket, scientifically called the "corbicula" (fig. 9); this would be impossible if the pollen were gathered dry, as it is by most of the solitary bees, so the bee moistens it on the flower with the nectar she has been sucking so as to make it sticky, and then transfers it into her basket by means of her foot brushes. The pollen therefore on the hind leg of a humble bee is all in one mass and can be {68}removed as such. When the bee reaches her nest this must of course save her the trouble which the solitary bee must have of cleaning off all the separate grains of pollen which are mixed up among the hairs. A word or two may be convenient here on the combs and cleaning apparatus of bees. Any one who has watched a bee clean itself will have noticed that the front legs work more or less horizontally—a bee will lower its head and bring its front leg over it with a curved motion—and that it will clean the sides of the face with a sort of shaving-like action, also that the antennæ are apparently pulled through the foot-joint in a remarkable way, often many times in succession. Now the foot of a bee consists of five joints, and is clothed with bristly looking hairs. If these hairs be examined through a microscope they will be found to be more or less razor-shaped, having a thick back and a dilated wing or knife-like blade (fig. 10). In some the blade is of some width, and the edge is evidently very sharp: these hairs or spines no doubt do the cleaning work, and admirably adapted they are to the purpose. The antennæ-cleaner {69}<ANTIMG style="width:100%" src="images/Fig10.png" alt="Fig 10. Cleaning apparatus of bee" title="Fig 10. Cleaning apparatus of bee"/>Fig. 10. <ANTIMG style="width:100%" src="images/Fig11.png" alt="Fig 11. Antenna cleaner of bee" title="Fig 11. Antenna cleaner of bee"/>Fig. 11. <ANTIMG style="width:100%" src="images/Fig12.png" alt="Fig 12. Cleaning apparatus of bee" title="Fig 12. Cleaning apparatus of bee"/>Fig. 12. (it may possibly be used for other purposes too) is a still more wonderful adaptation; in the basal joint of the foot there is a semicircular incision, which, when examined under the microscope, is seen to be a small toothed comb. The foot itself fits into the tibia or shin, and at the apex of the latter is a modified spine which is dilated on one side into a wing, or knife-like blade; this shuts down on to the semicircular comb, and the insect by passing the antennæ between the two can clean off anything which may have stuck to it (fig. 11). When we come to examine the other legs we find that the inner surface of their tibiæ and tarsi, i.e. that which is nearest the body, is clothed with hairs which have the points dilated and spade-like (fig. 12), which {70}allowing for the different action of the hind legs makes them just as good cleaners as the razors of the front pair; the spurs at the apex of the tibiæ, which are known as the calcaria, are also doubtless useful for cleaning purposes, and this is specially suggested by the beautiful saw-like form which they assume in some species; although there is no actual semicircular comb in the first joint of the tarsi, yet there can be little doubt that the spur and this joint in conjunction can act as a cleaning organ very much in the same way as the more elaborate arrangement in the front legs. Any one who has the opportunity of examining the hairs of bees under a microscope will be amply repaid for the trouble in noticing the beautiful shapes and structures which these organs assume. (Figs. 13-18; 17 showing pollen grains adhering.) At one time, when I was specially examining bee hairs, I shaved the various parts of a large number of species and mounted their hairs dry in microscopic slides, merely securing the cover glass with liquid glue; this was twenty years ago, and many are still quite good. It may seem a difficult operation to shave a bee, but {71}the hairs come off very easily, and with a sharp dissecting knife for a razor as many hairs as one wants are almost immediately at one's disposal. <div class="figleft"> <ANTIMG style="width:100%" src="images/Fig13.png" alt="Fig 13. Hairs of bees" title="Fig 13. Hairs of bees" /> Fig. 13.</div> <div class="figleft"> <ANTIMG style="width:100%" src="images/Fig14.png" alt="Fig 14. Hair of bee" title="Fig 14. Hair of bee" /> Fig. 14.</div> <div class="figleft"> <ANTIMG style="width:100%" src="images/Fig15.png" alt="Fig 15. Hair of bee" title="Fig 15. Hair of bee" /> Fig. 15.</div> <div class="figleft"> <ANTIMG style="width:100%" src="images/Fig16.png" alt="Fig 16. Hair of bee" title="Fig 16. Hair of bee" /> Fig. 16.</div> <div class="figleft"> <ANTIMG style="width:100%" src="images/Fig17.png" alt="Fig 17. Hair of bee with pollen adhering" title="Fig 17. Hair of bee with pollen adhering" /> Fig. 17.</div> <div class="figleft"> <ANTIMG style="width:100%" src="images/Fig18.png" alt="Fig 18. Hairs of bees" title="Fig 18. Hairs of bees" /> Fig. 18.</div> <hr class="short" /> {72} <h3>ON BEES' TONGUES, AND HOW THEY SUCK HONEY</h3> In order to understand how a bee sucks honey it will be necessary to go into some rather careful details as to the construction of its tongue and mouth organs. These I will make as short and simple as I can, but the apparatus is a very complicated one, and it will be impossible to describe it without a good deal of technical phraseology. The tongue has always been considered such an important feature in a bee's structure that it has been made the chief basis of their classification. On this subject I will only say that there are three principal types of tongues—a short bifid tongue (fig. 19, 3[1]), resembling those of the fossors; a short pointed one, shaped somewhat like a spear head (fig. 19, 2, 2a); and a long parallel-sided, ribbon-like tongue (fig. 19, 1, 1a). The bees are classified on what is considered to be an {73}ascending scale, beginning with the bifid-tongued species, through those with the short spear shaped tongues to the higher forms, which have this organ elongate and parallel-sided. <div class="figcenter"> <ANTIMG style="width:100%" src="images/Fig19.png" alt="Fig 19. Tongues of bees" title="Fig 19. Tongues of bees" /> Fig. 19.</div> The tongue is the central organ of an elaborate combination of mouth parts, which I will now try to explain. If we turn a bee's head over and look at its underside we shall find a deep cavity, filled up with the base of this combination which fits into it. If we extend the tongue (a humble bee is a good subject on account of its large size, fig. 20) so as to draw its base out of the cavity, we shall find that in the edge of each side of the cavity there is articulated a short rod (20, A), more or less dilated at its apex, called {74}the stipes; on the flattened ends of these rods there swings a joint shaped something like the "merrythought" bone of a chicken, called the lora or reins (20, B), to the central angle of which are suspended the pieces of the apparatus which terminate in the tongue. This V-shaped joint can swing over on its feet, and can therefore lie either between the stipites or rods with its angle pointing towards the tail of the bee, or in the opposite direction with its angle projecting beyond them and pointing forwards. It will at once be seen that by this turn of the V the tongue can be projected a distance equivalent to twice the length of the V. This V-shaped joint varies much in the length of its arms, which are much longer in the long-tongued than in the short-tongued bees. When we examine the parts that are suspended from this joint, we shall find that the actual tongue is separated from it by two distinct pieces; the first (i.e. that next to the lora) a short joint (the submentum, 20, C), the second (the mentum, 20, D) a long semi-cylindrical joint which holds as in a trough the softer parts at the base of the tongue. From the apex of the mentum {75}project three organs; the central one is the actual tongue (or ligula, 20, E), and on each side are the organs which are called the labial palpi (20, F); these in the long-tongued bees more or less fold over the base of the tongue and protect it. There are two other large and important mouth parts called the maxillæ (20, G); these articulate on to the flattened apices of the cardines, outside the articulation of the feet of the lora, and extend on each side of the mentum; they also have flattened blades sheathing, when closed, the whole of the mentum above, as well as the base of the tongue. <div class="figcenter"> <ANTIMG style="width:100%" src="images/Fig20.png" alt="Fig 20. Tongue of bee" title="Fig 20. Tongue of bee" /> Fig. 20.</div> So far we have been looking at the back of the head and mouth parts; if we now look at the front we shall see the maxillæ; if we open these we shall see the tongue lying between the {76}labial palpi, and at the base of the tongue we shall see two little sheaths called the paraglossæ; above these the softer parts lying in the trough of the mentum; from the base of the mentum, connecting with the maxillæ, there extends a membrane which entirely invests the spaces between the bases of these organs and extends up to the mouth. A membrane also extends between the stipites and lora, and closes the cavity at the back of the head. The back of the tongue in the act of sucking can be formed into a tube through which, partly, probably by capillary action, partly by the pumping action caused by the dilating and contracting of certain parts of the mechanism, the liquid food is drawn up into the æsophagus. This, I believe, has been shown to be the principle on which all bees, short- or long-tongued, suck up their honey. The subject could be treated at much greater length, and many other structures connected with the mouth parts discussed, but more minute details are unnecessary in an elementary work such as this, and I have therefore limited myself to a description of the broad principles of the process. <hr class="short" /> {77} <h3>A DREADFUL PARASITE</h3> <ANTIMG style="width:100%" src="images/Fig21.png" alt="Fig 21. Stylops" title="Fig 21. Stylops" />Fig. 21. Of all the evils to which bee flesh is heir, there can hardly be any so terrible as the effects of the parasite Stylops on the species of Andrena and Halictus which it attacks. This very extraordinary creature, which is now considered to be a beetle, lives during the early stages of both sexes in the body of the bee, which it enters when the bee is in the larval state. Its head protrudes like a minute flat seed between the body segments (fig. 21), and so is visible externally, but the rest of the creature, which is a grub-like larva, rests amongst the intestines of the bee; the female matures in the bee's body and never leaves it. The male, however, when mature, escapes, leaving the {78}<ANTIMG style="width:100%" src="images/Fig22.png" alt="Fig 22. Stylops" title="Fig 22. Stylops" />Fig. 22. Stylops larva in abdominal cavity: after Perez. great hole which he inhabited open; he is provided with wings, and I have more than once caught one flying in the open—but to return to our afflicted bee. This may be attacked in either sex, and by one to five of the parasites. I have specimens myself with four parasites in them, and a case of five has been recorded. Mr. R. C. L. Perkins, writing on this subject, says: "On removing the integument dorsally from the bee, the large body of the female parasite will be seen lying above the viscera, often almost entirely concealing them". If this is the condition of a bee nourishing only one parasite, I must leave it to my readers to imagine the state of the poor wretch who is supporting five! The outward appearance of one with several parasites is generally much distorted; the abdomen is very much inflated, and the poor creature is unable to fly any {79}distance, and can only crawl about, or perhaps take short flights of a foot or so. The effects, however, seem to be very different in different cases. I have caught Andrenas with two Stylops in them, flying about as usual and apparently none the worse for their inmates. Probably the position the parasite occupies may make a great difference in its effects on the bee. The most notable effect produced by Stylops is the alteration in the structure and colour of certain of the bee's characteristic features. In Andrena the males differ very considerably from the females both in form and colouring. They have no pollen-brushes on their legs, and in some few species the face above the mouth is white, whereas in the female it is black. Now the effect of the parasite seems to be to unsex as it were its victims so far as their outward appearance is concerned. This is no doubt due to the internal effects it has on the larva of the bee. Anyhow, if a female is attacked, in most cases the pollen-brush is much reduced, the face tends to become more hairy, and, if it be the female of a white-faced male, spots of white are often produced on the face. On the other hand, {80}if it be a male subject, the hairiness of the face is diminished, the white colour is often reduced or absent, and the hairiness of the legs is increased. Before the effects of the parasite were recognized, several new species were described simply on specimens of unusual appearance in consequence of its presence. These effects, however, like the effects produced on the activity of the bee, vary exceedingly in extent. On some the parasite seems to have no effect, in others the alteration in appearance is very great. This, again, is probably due to the position of the parasites and to the pressure they exert on the reproductive organs of the body in the larval state. <hr class="short" /> {81} <h3>AMONGST THE BEES AT WORK</h3> Now I feel sure many will be thinking "It is all very well to talk about all these solitary and social bees, but I never see them. I certainly know a humble bee with a white tail and another with a red tail, and a wasp, and perhaps a hornet, but I never notice any others." The reason for this, no doubt, is that people are not as a rule observant, and even if they notice a creature one moment they probably forget all about it the next. If any one goes out on a bright spring morning, late in March or early in April, about 11 o'clock, into a garden well stocked with flowers, it will not, I think, be many minutes before an insect darts on the wing along some border, and, if attention be paid to the flowers, a little black hairy bee with yellow legs, like a small humble bee, will be seen diligently at work sucking honey from one of them. The darting bee, which is of a brownish red colour, gradually {82}fading to grey after a few days' exposure to the sun, is the male, and the black one the female. The male rarely settles, but flies about courting the female. Often two or three males may be seen dodging and crossing each other in their flight. The name of this bee is Anthophora. It is quite a harbinger of spring, and I mention it especially as it so forces itself on one's attention, and there are few who will not meet with it without going especially on its quest. Another opportunity of seeing several kinds of solitary bees flying together may be secured by standing on a sunny day in front of a sallow bush in full blossom, I mean what is commonly called "palm." Its catkins, when the anthers are out and covered with yellow pollen, are most attractive to all kinds of bees, humble bees, hive bees, and solitary bees, and any one who can manage to watch a sallow bush for some time will realize that there are many kinds of bees at work. Of course it is difficult, without special knowledge, to recognize which are bees and which are flies amongst the many which are coming and going, but the yellow-pollened legs of the female bees will generally betray them, as well {83}as their steadier flight. A fly turns about more rapidly than a bee, and sits down much more abruptly. Bees are very captious about the weather; they do not like an east wind and are, apparently, very sensitive to coming wet. I have often gone out on a bright morning and been surprised to find nothing stirring, and then clouds have come up and proved the wisdom of the bees in staying at home. They also fly very little in cloudy weather, especially in the early spring, when the temperature is reduced by cloud below their fancy. One may be watching a sallow bush and see dozens of insects flying about. A cloud shadows it, and almost immediately they disappear, to appear again as suddenly with the return of the sun's rays. It is interesting to watch bees at work collecting pollen, etc., but if any one wishes to study them at home, their nesting haunts must, of course, be visited. These are so various that it is impossible to point them all out, but the best locality to select is a sandy bank facing south. In June or July such a bank is often alive with bees, sand-wasps, etc.; here, again, we want sunshine or the bees will stay in their holes. {84}Even when dull, however, it is a very interesting spot, and we can notice the numbers of holes bored in the bank, and their different sizes and shapes; most of them are round, but some sandwasps make very irregular holes. If we look closely at some of the holes we shall see something closing the aperture, and, if we are too inquisitive, that something will disappear down the hole like lightning; it is the face of the owner of the burrow waiting to come out for the first ray of sunshine, but the owner is very timid and it will be some minutes before she puts her face so near danger again. In most of the sandwasps the face is clothed with bright silvery, or sometimes golden, hairs, and it is a very pretty sight to see these little silvery faces peering out of their burrows. Again, one may sometimes notice a little stream of sand emerging from a hole; this is from some bee who is enlarging her domain or clearing out some of the sand which occasionally falls in. In some cases this ejection of sand is done with a great deal of action: the sand comes streaming out and then the bee follows, quite up to the mouth of the passage, kicking out the sand as hard as it can. {85}The moment, however, that the sun comes out the whole bank is full of life; and just as in the case of the sallow bush, one wonders where it has all been during the shadow. Bees will now be seen flying home laden with pollen; they will pause at the opening of their burrow and then disappear suddenly into its depths. In a very short time they will reappear quite clean and ready for another journey. Their cleaning apparatus must be wonderfully well adapted to its purpose. I have often had to remove the pollen from a bee's leg to see what colour the hairs are, and it takes some time even to brush enough of it off to ascertain this, and yet the natural cleaning process seems to take no time in comparison. But to return to our bank, numbers of bees will be seen coursing up and down and hardly ever settling; these are males paying what attention they can to any females who have time to attend to them, and often falling foul of other males intent on similar pursuits. If one has good luck in the choice of one's bank an elegant wasp-like creature may occasionally be seen amongst the others; this is one of the cuckoos. The flight of all the cuckoo bees is peculiar; it is much {86}quieter and slower than that of the hosts, and a cuckoo may easily be seen solemnly flying up and down the bank, over the various holes, no doubt watching for the proper opportunity to enter one, and deposit its egg in it. This deliberate flight seems a curious habit in a creature which one would think would wish to escape detection. If it seemed to inspire fear in the mind of its host it would be different, but they appear to fly about together unconcerned at each other's presence, and the cuckoo sails along demurely and imposes on its hosts' labours without any apparent resentment on the latter's part; both seem to accept their relationship as a matter of course. Another very interesting frequenter of sandy banks is a pretty little stout sandwasp, about a quarter of an inch long, called Oxybelus. It has a very bright silvery face which shines most brilliantly in the sun, and the body has a row of white spots on each side, and it brings flies back to its nest. It is very active and common, and may often be seen with its fly going back to its hole. There is a rare species of the same genus, which is clothed all over with silvery hairs, and this in some places, curiously {87}enough, selects as its victim a fly which is also coated with silver. There are, of course, many other inhabitants in such a bank as this. There are sure to be ants, which are always interesting to watch, and probably now and then a Pompilus will appear on the scene. These exceedingly lively creatures which run at a very rapid pace, vibrating their wings as they go, and taking short flights between the runs, are on the hunt for spiders. They will be seen to forage amongst any grass or herbage there may be on the bank, and if they can only secure a spider it is stung and paralyzed and carried off at once to the nest. Of course every sand bank will not yield a great number of insects, but some, especially in sandy districts like Woking, Oxshott, and other parts of the Surrey commons, and the New Forest, simply teem with life—and would repay any one for hours of watching and observation. <hr class="short" /> {88} <h3>ANTS, THEIR GUESTS AND THEIR LODGERS</h3> The number of insects of different kinds which live in ants' nests, either as scavengers, stray visitors who have found a lodging for the moment, as guests carefully taken care of and appreciated by the ants, or as lodgers, either tolerated or hostile to their hosts and persecuted, and parasites, is very great. The most interesting of these from the ordinary observer's point of view are the true guests and the lodgers. The true guests are carefully attended to by the ants; they include such insects as the Aphides or plant lice, and others which the ants use as "cows" to secure the saccharine juices which they can obtain from them, and also certain strange beetles which have tufts of golden hairs on their body, which the ants lick—on account of what E. Wasmann[2] calls the etherealized oil {89}given off by them. These beetles are fairly numerous and belong to several quite distinct families; the one which perhaps is amongst the most interesting is a creature called Lomechusa strumosa. This insect has rather an interesting history in connexion with our British fauna. It used to be considered as an indigenous insect, but so many years passed without any one finding it, that the old records were suspected as doubtful, and it was removed from the list of British species. In 1906, however, it was rediscovered near Woking in a nest of Formica sanguinea (pl. A, 1, 2, 3), one of the large red ants, by Mr. H. Donisthorpe. The life-history of Lomechusa is a very curious one: it is taken great care of by the ants, and its larvæ are even placed by them with their own, on which it feeds. Its numbers are kept down apparently by the overzeal of the ants to take care of them. The ants bring their own pupæ up frequently to obtain light and air and with them it brings up the Lomechusa pupæ—this seems not to suit the latter and results in the death of many of them. It is a most interesting case of how a due balance can be maintained, and what might prove an enemy {90}kept in his proper place by kind intentions. There are also in ants' nests what Dr. Wasmann calls "tolerated lodgers"; these are mostly creatures which are supposed to escape the notice of the ants, either by their small size or by their slow, lethargic, or on the other hand very rapid movements—these in many cases act as scavengers, living on the dead bodies of insects, etc., brought in by the ants. The hostile lodgers are real enemies to the ants and devour their brood, and in consequence they are always at war with each other. These creatures generally resemble the ants considerably in form and colour and especially in their movements. Besides these lodgers there are numerous parasites of the ants, such as mites, etc., so that an ant colony is a very wonderful mixture of diverse inhabitants. The distinctions given above as to the habits of the various lodgers are not always kept up, as, in some, two or more of these habits are combined. The whole study of ants and their guests is a most fascinating one: many of the latter are great rarities and much sought after by collectors. Unfortunately, the great {91}drawback in collecting them is the havoc caused to the nests of the ants. These structures have been the result of enormous labour on the part of these little creatures, and one cannot regard their destruction without sincere regret. I think any one who, when collecting beetles, disturbs a large nest of the little garden ant (Lasius niger) or the little yellow ant (Lasius flavus) by turning over a stone, as the writer has often done himself, must have experienced a like regret at having broken up all the beautiful passages and galleries which the ants have constructed so carefully. <hr class="short" /> {92} <h3>HOW CAN AN "ACULEATE" BE RECOGNIZED?</h3> This is not an easy question to answer. We cannot make hard and fast definitions which will determine exactly what belongs to this group and what to that; there are always some intermediate forms which present themselves and make our classification unsatisfactory, but, I think, for all purposes of practical observation in the field we may say that if we find a creature with four membranous wings, burrowing in the ground or making a nest in any way, it is an aculeate or stinger. Also, that if we find a hairy-bodied insect with four clear wings collecting pollen or sucking nectar from a flower it is a bee. There are, of course, characters by which the stinging groups can be known almost for certain, but there is no single one which can be given to recognize them by. {93}They are known by a combination of many, and these are frequently small structural details which do not appeal to the field observer; in fact, which are unappreciable except under magnification. One of the chief difficulties experienced by an observer who is not versed in classification is to avoid being deceived by various flies, which in many cases greatly resemble bees, and especially wasps or the wasp-like fossors. They may mostly be known by their flight, and, when they settle, by their behaviour. A fly is more sudden in its movements—those wasp-like flies, for instance, which poise themselves in the air and appear quite stationary but dart off in a second when approached, betray themselves at once by their alertness. Anthophora and Saropoda poise in the air and dart somewhat after the same fashion, but they never remain poised for long, and do not get away from their position so rapidly. Also, a fly when it settles remains quiet, whereas an aculeate if in a flower sets to work collecting pollen, or if basking in the sun on a leaf rarely rests for many seconds without moving in some way. On a flower, if an insect is seen quietly sitting with its head away from the centre of the {94}flower, it is almost certain to be a fly. Most of the little bees (Halicti) which visit dandelions and such like "composites" fly in to them with some rapidity, attack them sideways, and move round the "flower", no doubt getting pollen from each floret in succession and with a businesslike action about it all, which is very different from the behaviour of any fly. The flies which really closely resemble bees in their flight are those which lay their eggs in the burrows of various bees and sandwasps. They are really deceptive. Last summer on the sandhills at Southbourne, near Bournemouth, I again and again was deceived by a small fly with a red belt across its body, thinking it was a red-bodied sandwasp. These it really only resembles on the wing. After having been taken in once or twice one felt ashamed of oneself for not recognizing it. The flies also which associate with the humble bees are often coloured very much like them, and could easily be mistaken for small specimens of the bees were it not for their behaviour and wings, which show a dark spot on the upper margin, not existing in the wing of the bee. <hr class="short" /> {95} <h3>MALES AND FEMALES</h3> These differ from each other very greatly in many cases. Eccentricity in structure almost always occurs in the male; excess of coloration usually in the female. In size the male is generally the smaller and the less robustly built of the two. Among the pollen-collectors, the male is usually less densely clothed with hairs than the ♀. In the fossors this rule is rather reversed, but in that section neither sex is densely clothed with hairs as are most of the pollenigerous bees. The male has normally thirteen joints in its antennæ, and the female only twelve. There are exceptions to this rule amongst the ants and in certain fossors of the genus Crabro, some species of which have the antennæ considerably distorted, and have two joints welded apparently into one. Another distinction between the sexes is that the male has seven dorsal segments {96}of the body exposed to view, and the female only six. In the males of some of those bees which collect pollen on the underside of the body, the body above terminates with the sixth segment. This is because the seventh is turned over on to the underside, and faces downwards, its apex pointing towards the head. This arrangement of course leaves less room for the regular ventral segments, and the usual apical segments are in consequence "telescoped" up under the fourth, so that the apical opening of the body lies on its underside between the fourth ventral and the inverted seventh dorsal segments. This very curious structure occurs only in those bees whose females collect pollen on the underside, and the reason of it is to me quite inexplicable. The females of a few of the fossors are destitute of wings; but in this country we have no wingless males, except in the case of one little ant (Formicoxenus); this lives in the nest of the common large red ant, and its male can hardly be known from the worker except by the number of joints in the antennæ and the absence of a sting. In the cases where the female is wingless, the male as a rule is much the larger of the two sexes. {97}There are few more puzzling questions than those which arise over these eccentricities of structure; they seem to have no relation to any habits of the creatures' lives so far as we can judge, neither can one suggest any useful purpose which they can serve. In some groups the males of all the species seem built on one regular plan—in others the males of each species seem to vie with the next as to what eccentricity of structure in antennæ or legs or apex of the body it can exhibit. In numbers, the males probably considerably exceed the females, and are far more frequently met with, as they seem to be less particular as to weather, and not being intent on obtaining food for their offspring they fly about more casually, and certainly are more in evidence generally. The great difference in structure, etc., between the males and females makes the work of pairing the sexes very difficult, especially in those genera where the males and females appear together only for a few weeks, as is the case in Halictus and Sphecodes. If one visits a locality in the spring one may catch any number of females of Halictus, but no males appear till the late {98}summer or autumn, and, unless one visits the same spot again when both sexes are out, it is impossible to associate males and females. I have at the present moment in my collection several males, which, being in doubt about myself, I have communicated to continental authorities, who have returned them to me as possibly the male of so and so! and we shall have to remain in uncertainty about them till some one happens to take both sexes together, when the mystery will be solved. In time of appearance the males always precede the females—in burrows, such as those of the leaf-cutting bees, etc., it may seem puzzling as to how this is arranged, as one cell is placed over the other so that those lower down in the tube cannot pass those higher up. This difficulty is got over by the arrangement that the first eggs laid by the mother bee are female and the last male, so that those at the top belong to this latter sex; these emerge as soon as the warmth of the sun is great enough to energize them sufficiently to break through their cell covering, when they emerge and wait for the appearance of their females. The males of {99}some species of Andrena seem to take great pleasure in flying rapidly up and down hedgerows, hardly ever settling, and apparently far away from their females, which are probably pollen collecting in dandelions or some such flowers in the neighbourhood. <hr class="short" /> {100} <h3>THE VAGARIES OF COLOUR AND STRUCTURE IN THE SEXES</h3> As a rule the male is rather smaller and especially slenderer than the female, but there are notable exceptions; in one genus of the fossors, Myrmosa for instance, the male is many times larger than the female. In this case the male is winged and the female is wingless. Also, if there is a difference in brightness of coloration between the sexes, as a rule the male is duller than the female—this is especially the case among the bees—but if there is any eccentricity in the form of the limbs it is almost sure to occur in the male, and I think one would not go far wrong in saying that when peculiar features occur in the female, the reason for them is more or less apparent, whereas for the eccentricities of the male there really often seems to be no assignable cause. These male eccentricities are often exceedingly marked. A very good {101}<ANTIMG style="width:100%" src="images/Fig23.png" alt="Fig 23. Antennae of wasps" title="Fig 23. Antennae of wasps"/>Fig. 23. <ANTIMG style="width:100%" src="images/Fig24.png" alt="Fig 24. Legs of wasps" title="Fig 24. Legs of wasps"/>Fig. 24. example of them occurs among the small "keyhole" wasps. All the British species are practically alike in coloration. They may vary in having a greater or less number of yellow bands on the body, but otherwise their distinctions rest on structure. In the females the antennæ are slightly thickened towards the apex, but otherwise they are simple. The males, however, are divided into three quite distinct groups. In the first of these, the end joints of the antennæ are rolled up in more or less of a spiral (fig. 23, 2); in the second, the apical joint is turned sharply back like a hook (fig. 23, 1); in the third, the end joints of the antennæ are simple and more or less like those of the female. Now if we examine the legs of the males in the first group we shall find still greater peculiarities; in two of our species there is a long yellow spine at the extreme base of the middle leg on the little joint by which it articulates on to the body (fig. 24, 2), and a curious pencil of hairs {102}on each side of the mouth. In two others, the femora, or thighs of the middle legs, are cut into two deep somewhat semicircular incisions (fig. 24, 1)—a most curious character; but here again the females have no corresponding peculiarities. There seems to be no explanation known for these vagaries, and yet one feels that there must be some object served by them. If we turn to the bees we shall find that in many species the face of the male is white to a greater or less extent, whereas that character is very rare in the female. The front feet are produced into a wide flattened form in some, in others the middle legs are extraordinarily developed, and provided with tufts of hairs, etc. Another form of male development lies in the form of the head. This is sometimes very much enlarged—often varying considerably in this respect in specimens of the same species; there is often a projecting tooth or spine on the mandible or jaw at its base, or frequently on the cheek just above it. Then in the fossors the males of the genus Crabro break out into numerous eccentricities; in some, two or more of the joints of the antennæ are soldered together and curved or cut out into {103}curious forms (fig. 26); in others the front shin or tibia is formed like a concave shield or shell (fig. 25), and all the joints of that leg more or less distorted; in another male (a rather doubtful native which has not been taken in this country for fifty years) the head is narrowed behind into an almost ridiculously small neck, being quite triangular in form, viewed from above, with the eyes projecting from its anterior angles (fig. 27, 1), the female head being of normal form (fig. 27, 2). <div class="figleft"> <ANTIMG style="width:100%" src="images/Fig25.png" alt="Fig 25. Tibia of Crabro cribrarius" title="Fig 25. Tibia of Crabro cribrarius" /> Fig. 25.</div> <div class="figleft"> <ANTIMG style="width:100%" src="images/Fig26.png" alt="Fig 26. Antennae of Crabro cribrarius" title="Fig 26. Antennae of Crabro cribrarius" /> Fig. 26.</div> <div class="figleft"> <ANTIMG style="width:100%" src="images/Fig27.png" alt="Fig 27. Heads of Crabro clypeatus" title="Fig 27. Heads of Crabro clypeatus" /> Fig. 27.</div> In the males of several species of fossors and bees the eyes are enormously developed, joining one another on the top of the head. This condition occurs also in the drone of the hive bee. The male of Astatus, which has this character, has also a peculiar habit. It sits basking in the sun on some bare sandy spot, and when disturbed makes a sort of circular detour and pitches down again exactly on the spot from which it started up. An {104}increased length of the antennæ is another male characteristic. This is carried to an extraordinary development in what is called the "long horned bee"; this bee, which is pretty common in some places, has antennæ which, when directed backwards, are almost as long as its body—the female has quite an ordinary pair. Another set of male characters which are of great value to systematists lies in the hidden apical segments of the underside; although these are hidden, being telescoped up inside the segments which close the apical opening of the body, they often assume most curious and beautiful forms, and are characters whereby the males of a species may be determined with certainty when the females defy all one's endeavours to discover their identity. <hr class="short" /> {105} <h3>THE DISTRIBUTION, RARITY, OR ABUNDANCE OF VARIOUS SPECIES</h3> There are few points about which we know less than the causes of distribution and rarity, although there are certain tolerably well recognized laws which govern the occurrence of some species in certain localities. What I mean is that marshy spots, say salt marshes for instance, attract certain beetles and bugs which are never found except in such places; certain kinds of flowers attract bees which never appear to visit any others, but these localities and kinds of flowers occur often at great distances from each other, and why—given a certain flower you probably find a certain bee peculiar to it; or given a certain kind of marsh you probably find a certain beetle, although the localities may be hundreds of miles apart—I think still awaits explanation. I will give an example with which I am personally well acquainted. {106}There is a rare little bee (Macropis labiata) which at one time was looked upon as an extreme rarity, having only occurred three or four times in this country. Mr. F. Enoch, comparatively lately, took a fair number on the flowers of the greater loose-strife (Lysimachia vulgaris) along the canal at Woking; now that its food-plant is known, it has occurred in several other places in numbers, and no doubt wherever the Lysimachia is abundant Macropis will probably occur, but how the little creature has been distributed over the places where this plant occurs, which are often far distant from each other, seems to me to be an unsolved problem. Then there is another puzzling point, and that is the extreme rarity of certain insects. No doubt in many cases this is due to ignorance of their habits, as it has frequently happened that species once considered of great rarity have occurred in abundance when their habits have been discovered, as in the case of Macropis, but there are some cases which do not seem to be explainable in this way. I will again give an example which has been specially under my own observation. Dufourea vulgaris, a little black bee, {107}which certainly might not be recognized from its outward appearance, as there are many which very closely resemble it, is still one of our greatest rarities, only three British examples having been recorded. The first was taken by Sir Sidney Saunders at Chewton, Hants, on the twelfth of August, 1879; this was a male; the second, a female, was taken by Mr. T. R. Billups at Woking, on the first of August, 1881; and the third by myself at Chobham (about four miles from Woking) on the first of August, 1891. I believe in all cases these were taken on yellow composite flowers. The flight and behaviour of the male I caught were so peculiar, as it wriggled itself into the flower, that I knew at once I had caught a rarity, and remarked to my companions that I believed I had got a Dufourea. I also hazarded the remark that it was "ten years since it had been taken." When I got home and looked up the former record it was ten years to a day. Now there are few places in England that have been better worked for the bee tribe than the Woking, Chobham, and Weybridge neighbourhood; it has been worked by experienced men who would see a difference {108}in the flight of an insect directly. The late Mr. F. Smith, in his day our leading authority, the Rev. F. D. Morice, than whom no one has probably worked the neighbourhood more thoroughly, Mr. T. R. Billups, Mr. E. B. Nevinson, and the late Mr. A. Beaumont, have all been over the ground again and again, and yet only these two Dufoureas! and these taken four miles apart. Here again is a problem which is very perplexing! What part in nature does this little rarity play? No doubt like everything else it has its duties, and its corner to fill, but beyond that one can suggest nothing. Other bees are often exceedingly abundant in one season and very rare the next, or they will entirely desert a locality where they have been abundant, and move somewhere else—the occasional scarceness is due probably to continued wet weather, which often appears to kill the larvæ. Cold winters seem to have no injurious effect, although at one time they were thought to determine the scarcity or otherwise of the bees of the following summer. It has, I think, been clearly shown that larvæ can stand almost any amount of cold, although they succumb to {109}the effects of mildew produced by wet, but there is often no apparent reason why a well established colony should migrate to quite new pastures. Sometimes the proximity of new buildings or the digging up of ground may disturb them, but I know of colonies that have gone from where I knew them a comparatively few years ago, and where I can detect no change likely to have affected them. On the other hand there are colonies which one has known all one's life and which still go on as strongly or more strongly than ever—the case quoted under Anthophora, p. 63, shows what persistence there can be in some. <hr class="short" /> {110} <h3>ON BEES' WINGS</h3> The Bees and the other stinging groups have four wings like all the Hymenoptera. These wings are almost always clear and transparent, at any rate amongst the British species, there being only one exception which I can call to mind in the female of the cuckoo of our large red-tailed humble-bee, which has the wings blackish; also they are never spotted, as in some flies. The hind or lower wings unite with the upper by a series of very beautiful hooks which extend along their upper margin and fix on to the posterior edge of the front wing, which is folded back on itself so as to receive them; in flight the two wings are united, but when at rest they separate; these hooks are beautiful objects under a microscope; their numbers vary; and in some cases this variation is useful in distinguishing closely allied species from one another. The hum of a bee is caused, to a great extent, by {111}the vibration of the wings, but it has been shown that a loud buzzing noise can be emitted by bees which have lost their wings; this proceeds from the spiracles or holes in the outer covering of the creature through which it breathes. It is therefore not always easy to say how much of the hum is caused by wing vibration and how much by the action of the spiracles. Some, in fact most, of our solitary bees are almost silent in flight, and their note can be heard only when large numbers are flying together; others have a very peculiar shrill hum, by which even the species can almost be recognized. In bright, hot, sunny weather their flight is more rapid and their note attains a higher pitch. The bees with the highest pitched hum with which I am acquainted are the two smaller species of Anthophora and Saropoda bimaculata. In early spring, when it is hot in the sunshine and cold when a cloud covers the sun, it is no unusual thing to see a bee drop to the ground. The cold seems to paralyze altogether their powers of flight. When at rest a bee folds its wings along the sides of its back, but only in the wasp tribe is there the arrangement for them to be {112}folded longitudinally. The shape of the wings varies very little, but the arrangement and number of their cells vary considerably. There are some very interesting genera in which the neuration of some of the cells is so slightly indicated that they are hardly visible, and can be seen only when the wing is held in certain lights; these faintly indicated cells are nearly always those towards the apex of the wing, the neuration of the basal part of the wing being as strong as in the other genera. There are a few moths in this country which very much resemble, both in the colour of their bodies and their clear wings, the wasp tribe, but they may be known by the brown band of scales at the apex of the wings and also by the absence of the narrow waist, which exists in all the stinging tribes. The only wingless forms which we know are to be found amongst the ants and the fossors, and as a rule are females, but in a few cases in the ants, and in some foreign species of the genus Mutilla, the male is apterous also. <hr class="short" /> {113} <h3>ON BREEDING ACULEATES, ETC.</h3> Any one who wishes to study the life-histories of these insects, and has leisure to do so, can easily obtain various larvæ by digging for them in suitable places. If, for instance, during the summer, bees, etc., have been noticed entering holes in a certain bank or sandy spot, their larvæ or nymphs can be got in the autumn by digging down for about a foot in the direction of the holes, and if they be brought home and put into glass-top boxes they will generally emerge at their right time without giving any further trouble; it must, however, be remembered that the grubs are very soft and tender skinned, and it is better to avoid handling them if possible; they should be moved with a small soft camel-hair pencil, and it is well to put something soft at the bottom of the box so that if they fall in they will not be damaged. If the wood-boring {114}species are being collected, care must of course be taken in splitting the wood; most of these make a pupa case over themselves, and are in that respect easier to deal with. A label should be put in each box to show where the larvæ, etc., were found. An old rotten stump of a tree will often produce a good number of species. Then there are the bramble-stem borers; these can be left in the stems. I have generally found it convenient, after arriving home, to split the stems down, to see if there are any living creatures in them, and, if there are, to close them up again, and, tie a little very fine net or gauze bag over the top of each stem; in this way one can find out exactly what insects come from what stem, and determine the cuckoos (if any) which belong to each. As the season advances towards May, it is well to give all the larvæ, etc., an occasional glimpse of the sun; they should not be left in the sun long enough for them to get dried up too much, but the sun is a very important factor in tempting them to emerge; naked larvæ and nymphs, in glass-top boxes, should be treated very carefully in this respect, as they are deprived of their {115}natural surroundings, in which the actual sunshine would never reach them—it would be better to place them in a sunny room, screened off from the actual rays of the sun, so that its warmth only would be felt. If they do not emerge the first year, it should not be taken for granted that they are dead, as very likely they will appear in the following spring. I have bred leaf-cutting bees several times with great success, and others I know have been successful with many species. The fear is to get them dried up too much; it is therefore not desirable to keep them in a very hot room. When first the insects emerge, their hairs are often more or less matted together, and they should be put in the sun in a larger box, so that they can crawl about and clean themselves; portions also of the skin in which they have been enveloped frequently adhere to them for some little time, but as a rule, unless the creature be too weak, these are very soon cleaned off. Breeding is a fascinating amusement, but it requires a great deal of attention when the emerging season begins, as the boxes want constant watching, or the insects will emerge unnoticed, and, if not given proper {116}air and sunshine, may die without cleaning themselves properly. If it is desired to preserve the specimens, they should be killed either with cyanide of potassium, ether, or chloroform. If the first of these agents is used, a piece of about the size of a small hazel nut should be put at the bottom of a bottle (for collecting purposes, an ordinary "Coleoptera bottle", which can be obtained from any naturalist's shop, is the most convenient) and should be kept down by a wad of blotting paper, well pressed down upon it; this prevents the cyanide, as it liquifies, from wetting the hairs, etc., of the insects. Over this a piece of white paper should be placed; this will get stained at once when there is much damp, and should then be changed. The objections to cyanide are its very poisonous nature, and the stiffness which is caused by its use to the specimens killed by it, and also its tendency to turn yellow colours red. I always use it myself as I think it is preferable to the other insecticides, notwithstanding its demerits, but then I do not extend the legs and wings of my specimens, but simply leave them in whatever position they happen to {117}die. Ether is a very favourite method of killing with many; a few drops in a bottle with some paper in it is sufficient to last for some hours; it however soon evaporates in hot weather, and it is necessary to carry a small phial of it in one's pocket to replenish the supply when exhausted; this makes one smell of ether perpetually, which is more than I can stand. But the insects killed in this way are beautifully supple, and, for those who wish to set their captures as they would Lepidoptera, it is an excellent medium, i.e. if they don't mind its smell; it has also the benefit of not affecting colour. Chloroform acts much as ether does. When killed, I strongly recommend collectors to pin their specimens through the thorax with a very fine pin (those used for micro-lepidoptera are the best), and then to pin this through a narrow strip of card, mounted on a long stout pin; in this way the insect can be moved about by the strong pin, and the thorax of the insect itself is not destroyed, as it often is in the case of the smaller species by the use of thicker pins. The cards should be cut as small as possible; they need not be more than a quarter of an inch long. The insect {118}should be pinned at right angles to the long axis of the card, and the long pin should be inserted on the right-hand side of the insect so as not quite to touch it. In this way the insects look quite as neat as if they were pinned direct. Locality labels, etc., should be affixed to the long pin, and the insects should be stored in cabinets or boxes. <hr class="short" /> {119} <h3>ON COLOUR</h3> There is but little tendency towards brilliant coloration amongst our native aculeates. No doubt our comparatively high latitude accounts for this to some extent, as also the fact that the aculeates do not, as a rule, elsewhere assume great brilliancy. Even in the tropics and other warm regions, where bright green, blue or coppery coloured species occur, they are comparatively few in number. In this country metallic colours are to be found in less than a dozen species, and in most of these it exists only as a tinge. Amongst our ants and wasps it does not exist at all, unless the slight bronziness of the typical form of Formica fusca be so considered. The fossors can exhibit only a bluish tint in Mutilla Europæa (pl. A, 4, 5), and a slight bronzy tinge in two of quite the smallest species, Miscophus maritimus and the ♂ of Crabro albilabris. The bees can do a little better; five species of Halictus have a distinctly {120}bronzy head and thorax, and in three the bronzy colour extends to the abdomen; there is also another with a very dull green tinge on the thorax; besides these there is a little bright blue bee, Ceratina (unfortunately a great rarity in this country) and two or three species of Osmia, showing more or less tendency to bronziness, and one which is distinctly bluish; but, considering our indigenous species number nearly 400, this is a very small, and compared with other countries I should think an abnormally small, proportion. Species with bodies banded like a wasp's are much more abundant—no less than eighty of our native kinds having this style of coloration. The bands may be reduced to lateral spots, but such cases, I think, are only modifications of the banded scheme. Black species with a more or less pronounced red band across the body number about seventy, and a general testaceous or yellowish colour occurs in a few ants, but not elsewhere among the British aculeates. Nearly all the rest are black or dark brown so far as the actual surface of the body is concerned; but amongst the bees {121}there is often a dense clothing of coloured hairs sometimes so dense that the surface of the body may be rendered invisible. These coloured hairs may be distributed into brilliant bands, as in the humble bees, or they may be uniformly black, as in some of their varieties and in the females of the spring species of Anthophora (pl. D, 25), or entirely red as in Andrena fulva (pl. B, 16), or black on the thorax and red on the abdomen as in Osmia bicolor (pl. D, 28), or vice versâ as in Andrena thoracica, etc., but the most usual condition is that where the hairs form more or less pale bands along the joints of the segments, either immediately above or below them or both; sometimes these bands are very obscurely indicated, and visible only in certain positions. At others they are vividly white; to a certain extent this banded condition recalls the waspy coloration. The hairs, however, of the bands are rarely yellow, but as a rule greyish or white, or of a grade of colour slightly paler than those of the disc. There are some rather interesting points which arise out of this rough analysis. Among the bees, all the species which have a waspy coloration are cuckoos, with only one exception (Anthidium) {122}(pl. D, 27), as are also nearly all those which have red bands. With the exception of the males of three species of Halictus, and both sexes of three or four species of Andrena, all the red-banded forms belong to the genus Sphecodes (pl. B, 11), which is a cuckoo genus. The red coloration occurs chiefly on nearly naked surfaces; this is specially noticeable in those bees which have two varieties, such as Andrena rosæ, one dull coloured and the other red-banded: in these cases the dull form is hairy and the red nearly naked. The greatest proportionate number of banded species occurs amongst the fossors, and these are seldom clothed with hairs to any extent. These bands seem to me probably to depend a good deal on retarded development. Dark and hairy bands, both as a rule, follow the joints of the segments, as stated above. I only say as a rule, as there are many where the banding does not follow this principle, but in far the larger majority the bands, whether of dark colour or hairs, are apical. As the segments overlap at the joints it is evident that their discs would tend to mature more rapidly than the overlapping bases and apices, {123}and the longer period spent in hardening and drying of the overlapping parts would favour the development of dark pigment and of hairs. Many species have the extreme apices of the segments pale, but with the apical integument so very thin, often looking nearly transparent and membranous, that its development would be very rapid. Again, in the case of red coloration, the red generally occurs on the discs of the segments, the apices and sides often being dark, and in cases where in one species both black and banded forms occur, with intermediate varieties, the last remnant of red colour is generally situated in the centre of the segment. By far the gayest effect is displayed by our humble bees, and, but for them and a few of the species of Andrena and the wasp-coloured species, our aculeates would be a very sombre lot. <hr class="short" /> {124} <h3>THE DEVELOPMENT OF INSECTS FROM THE EGG</h3> Although this and the following chapter may not be interesting to all my readers, I think it is only right to add some remarks on the structure and classification of insects, so that any one who wishes to follow up the subject may gather a few general ideas which may induce them to take up some technical and scientific work in which they will get fuller and more exact data on the difficulties which are involved in such simple questions as "What is an insect?" "How are the different orders of insects distinguished from each other?" "What is a species?" etc. To realize the characters of an insect in its perfect or "imago" state, we may for the moment forget what often seems to be its most important features, and which are frequently its most extensive parts, viz. its limbs or {125}appendages; by limbs are meant its wings, legs, horns or antennæ, jaws or mandibles, etc.: strip these all off, and we have a limbless trunk, which many would not recognize as belonging to an insect at all; still this limbless trunk possesses characters which assert its insect nature, as it may be known from other limbless trunks by being divided into three parts by two great transverse divisions; in most insects these are extremely well marked, and in all they have a very real existence. The parts thus divided off are known by the names of head, thorax, and abdomen. Anybody knows how easy it is to break off the head or body of a dried insect. Now the head or body breaks off at one of these divisions, and it is this partitioning of the body into three sections which makes one of the strongest characters in the definition of an insect. The three parts, thus divided off, each possesses special functions in the life of the creature. In the head are contained the principal organs of sense and brain; in the thorax, the organs of locomotion; and in the body those of digestion, reproduction, etc. This division into three parts does not however {126}always hold good in the early stages of the insect's life, and we must remember that the creature commences life on leaving the egg, and not merely on its emergence from the chrysalis, so that we have to reckon with caterpillars, grubs and all sorts of curious immature forms in our conceptions of an insect. These early stages do not as a rule interest the public much, but it is well to bear in mind that the "perfect insect" stage is reached by some insects along apparently a very different road from that travelled by others. Some leave the egg as caterpillars or grubs, and after various changes of skin become apparently lifeless chrysalids, from which they emerge as perfect insects. Others leave the egg as diminutive likenesses of their parents, and run or hop about much as they do, attaining the perfect insect stage simply by a series of changes of skin, without any definite quiescent or chrysalis condition. The observation, therefore, which one often hears that insects never grow, has to be taken with caution; all insects grow in their early stages, but it is an obvious truth that insects do not {127}grow after they attain the imago or "perfect insect" condition. A small fly will never become a large fly, nor a small beetle a large beetle. This is only because we do not recognize their caterpillars or grubs as flies and beetles; but a grasshopper we know grows, because its early stages are of the same general form as the perfect insect, and we see the little ones hopping about in some places, and if we visit the same place later on we notice that they have grown, but as soon as they cast their last skin and obtain the free use of their wings, growth ceases, as it does in a fly or a beetle or in any other insect. It must not be supposed that the limbs of insects are of no value in their identification. We only removed them in order to emphasize the great importance of the character derived from the regional constrictions of the body, which is considered to be certainly one of the most, if not the most, important of any. Besides this character every perfect insect should have six legs, four wings, and various appendages on the head, such as antennæ, mandibles, maxillæ, labium, etc.; some of these may be so modified as hardly to {128}be recognizable, but they are hardly ever absent altogether; for instance, the two fore wings of a beetle are modified into what are called wing cases, and fold over its back, protecting the two hind wings, which are more or less membranous, as are those of a bee. They have not the functions of locomotive organs, and are used in flight as poisers. Again in the case of a fly, the hind wings seem to be absent, but they are considered to be represented by two little projecting organs which look like large headed pins or nails, but which are quite useless for locomotive purposes. The organs of the mouth are especially liable to modification, and on these the older authors used to frame their classification. Insects were divided by them, primarily, into two great divisions, viz. those which had a biting and those which had a sucking mouth; treated in this way, the following orders fall into the division with biting mouths:— Coleoptera, or beetles; Hymenoptera, or bees, wasps, ants, etc.; Orthoptera and Neuroptera, which include the grasshoppers, earwigs, cockroaches, dragonflies, May flies, etc. {129} And into the division with sucking mouths:— Lepidoptera, or butterflies and moths; Diptera or flies, gnats, etc.; Hemiptera, or bugs, including the plant-lice, etc. These divisions, however, have not been found to be very satisfactory, although very simple when dealing only with the perfect insect stage. In the first place, being framed on this stage only, they are not always applicable to the earlier phases of the insect's life—for instance, although a butterfly or moth has a sucking proboscis, their caterpillars have strong biting jaws, as any gardener well knows. Also bees, wasps, etc., rather upset the arrangement, as they have not only a sucking mouth but also strong biting jaws. This system of classification has therefore been discarded by most entomologists in favour of that based on the difference between those insects which pass through the distinctive stages of caterpillar and chrysalis on the one hand, and those which emerge from the egg as diminutive likenesses of their parents on the other. In this arrangement, the Coleoptera, Hymenoptera, Lepidoptera, Diptera and Neuroptera, fall into the {130}first division, or Heteromorphæ as they are called; and the Hemiptera and Orthoptera into the second or Homomorphæ. The dragonflies are the only slightly discordant elements in this arrangement, as, although their larvæ have six legs and walk about under the water and never assume an actual chrysalis condition, still they can hardly be said to resemble their gorgeously coloured parents which fly about so majestically over our ponds, etc.; still this is only one of the many cases which show that nature cannot be held down by any of the arbitrary rules we make for her classification. The Hymenoptera are therefore characterized and distinguished from other insects by having both a biting and sucking mouth, four clear wings, and by passing through the distinctive liveries of caterpillar or grub, and chrysalis or nymph. It is with this order only with which we have been dealing. To distinguish the aculeate section from the many other forms of the Hymenoptera is too complex a task to undertake here, but the presence of a narrow waist between the thorax and the body, the number of joints in the antennæ never exceeding thirteen in {131}the male, twelve in the female, and the presence of a sting capable of ejecting poison in this latter sex, are the most prominent features by which the aculeates may be recognized. <hr class="short" /> {132} <h3>ON STRUCTURE</h3> Although in the foregoing chapter a little has been said on this subject, there is a great deal more that a student should learn about the general form of these creatures. They begin life as white or nearly colourless grubs, which, after various changes of skin, assume what is called the nymph or pupa stage, during which a change occurs, believed to be peculiar to the Hymenoptera; the fifth segment of the larval body is transferred to the mass which is called the thorax, so that a portion of what looks like thorax is really the first segment of the abdomen. Continental writers call this portion sometimes the first abdominal segment and sometimes the median segment, but Newman gave it a definite name, the "propodeum", and the most convenient method seems to be to call it so, and treat it as a part of the thorax, calling the first or basal segment of the abdomen {133}that which immediately follows the regional constriction, which occurs between the propodeum and the abdomen. <div class="figleft"> <ANTIMG style="width:100%" src="images/Fig28.png" alt="Fig 28. Parts of an aculeate" title="Fig 28. Parts of an aculeate" /></div> <blockquote class="b1s"> Fig. 28. a Head. a1 Antennæ. a2 Ocelli. a3 Compound eyes. b1 Prothorax. b2 Scutum of Mesothorax. b3 Scutellum of Mesothorax. b4 Post-Scutellum of Metathorax. b5 Propodeum. c1 c2, etc., Segments of Abdomen. Legs. d1 Coxa. d2 Trochanter. d3 Femur. d4 Tibia. d5 Tarsi. d6 Calcaria or Spurs. d7 Unguiculi or claws. d8 Pulvillus. e Front wing. 1 Costal nervure. 2 Post Costal nervure. 3 Median nervure. 4 Posterior nervure. 5 Basal nervure. 6 Cubital nervure. 10 1st Recurrent nervure. 11 2nd Recurrent nervure. f. Hind wing. 7 Anterior nervure. 8 Median nervure. 9 Posterior nervure. Cells. A Marginal. B Upper basal. C Lower basal. D 1st Submarginal. E 2nd Submarginal. F 3rd Submarginal. G 1st Discoidal. H 2nd Discoidal. I 3rd Discoidal. J 1st Apical. K 2nd Apical. </blockquote> <div style="clear: both"></div> {134} The perfect insect when it emerges has therefore a head, a thorax of four segments, and an abdomen of seven visible dorsal segments in the male, and of six in the female. The ♂ has six ventral segments exposed, and often the apex of the eighth, which is frequently elongate, the seventh being almost always short and hidden; the eighth dorsal segment can be discovered hidden under the seventh, but it is very rarely exposed. The head (a) bears numerous appendages; a pair of antennæ (a1), usually of thirteen joints in the male and of twelve in the female; two compound eyes (a3), composed of many facets; three simple eyes (or ocelli) (a2), which are situated on its vertex; two mandibles; two maxillæ, bearing palpi on each side, of a varying number of joints; and a labium, or tongue, which also bears at its base two four-jointed palpi (cf. fig. 20). The thorax, as we are considering it, consists of four segments—the prothorax (b1), which bears the two front legs; the mesothorax (b2), which bears the intermediate pair of legs and the anterior pair of wings; and the metathorax (b3), which bears the posterior pair of wings and the hind legs. The {135}propodeum has no appendages. The mesothorax above has two parts, a larger portion in front called by some the scutum (b2), and a smaller portion behind called the scutellum (b3). These are separated from each other by a transverse impression, and the scutellum is often raised into a sort of little shield; behind this is another little elevation called the post-scutellum (b4); this is really the dorsal apex of the metathorax, and behind this lies the propodeum (b5). Each leg is composed of various parts, and articulates into a cavity of the thorax called the acetabulum. The first two joints of the leg, the coxa (d1) and the trochanter (d2), are very short; then follows the femur or thigh (d3); then the tibia or shin (d4); and finally the tarsi (d5), which compose the foot. At the apex of the tibia are usually two spines called the calcaria (d6). The tarsi are five-jointed, the joints following each other in a linear arrangement, and in the Anthophila the basal joint is more or less dilated; the apical joint bears two claws (unguiculi, d7) which are sometimes toothed, and between them, in some genera, there is what is called a pulvillus (d8) or cushion; this is very large and dilated in some of the fossors. {136} The wing neuration is always rather troublesome, as various authors use different names for the veins and cells. To begin with the anterior wing (e), there are four nerves which start from the base and run horizontally; the first of these, which forms the anterior margin of the wing, is called the costal nervure (1); immediately below this, and running almost parallel to it with scarcely any space between them, is the post-costal nervure (2); these end in the stigma (s), a dark in-crassation towards the apex of the wing; from the stigma a nerve, curving first downwards and then up to the anterior margin of the wing, encloses the marginal cell (A). Below the post-costal nervure, and situated about the centre of the wing, is the third longitudinal nervure called the median nervure (3); behind this again runs the posterior nervure (4), and behind that the actual margin of the wing which is not provided with a protecting nervure, but is only folded back so as to receive the hooks of the posterior wing. Across the wing at, roughly, about a third of its length from the body runs the basal nervure (5); this extends in a somewhat zigzag line from the post-costal to the posterior nervure crossing the median, and {137}thereby enclosing two cells, the upper basal cell (B) and the lower basal cell (C). From the centre of the apical nerve of each of these cells extends a longitudinal nervure; the upper of these runs out nearly to the apical margin of the wing and is called the cubital nervure (6); this is united to the nervure of the marginal cell by one, two, or three cross nervures, enclosing thereby one, two, or three cells called the first (D), second (E), and third (F) submarginal cells. The nervure from the lower basal cell is a short one, as it is met by a cross nervure called the first recurrent nervure (10), which runs from the cubital to the posterior, thereby enclosing two cells, the first (G) and second (H) discoidal. The second recurrent (11) leaves the cubital nearer the apex of the wing than the first, meeting a nervure which, springing from the outer posterior angle of the second discoidal, closes the third discoidal (I), and, curving slightly upwards, nearly reaches the apical margin of the wing. Beyond the second recurrent, and behind this last nervure which we have been talking about, are two spaces not actually enclosed, but called the first (J) and second (K) apical cells. The posterior wings have very few cells. {138}Like the anterior pair they have three longitudinal nervures; the anterior (7), which runs close and parallel to the anterior nerveless margin, and often touches it at about half the length of the wing; the median (8) and posterior (9) run in diverging lines from the base towards the exterior margin of the wing, the anterior and median nervures being almost always joined by a cross nervure, and the median usually united to the posterior by a cross or curved nervure. The actual base of the anterior wing is covered by a little convex somewhat shell-like cap, called the tegula (T). The abdomen is composed of a series of segments in linear arrangement (c1 c2, etc.). These call for no special remark, beyond what has been said in the chapter on males and females, but those who wish to investigate the very interesting questions connected with the terminal segments of these creatures should consult some more technical work.[3] The arrangements of the mouth parts and of the apical segments of the Hymenoptera afford perhaps the most important structural {139}characters of the order, but they involve an amount of dissection and study which can only be undertaken by those who are inclined to give themselves up to this subject as a speciality. <hr class="full" /> {141} <h3>INDEX</h3> <div class="poem"> <div class="stanza"> Abdomen, 125 Acetabulum, 135 Ammophila, 22 Andrena, 9, 12, 15, 48, 77, 79, 122, 139 — fulva, 121 — rosæ, 138 — thoracica, 121 Antennæ, 101, 103, 134 Anthidium, 50, 121 Anthophila, 6 Anthophora, 48, 61, 82, 93, 109, 111, 121 — pilipes, 61 — retusa, 62 Ants, 28, 31, 88 Aphides, 88 Apis, 16 Astatus, 103 </div> <div class="stanza"> Banded bodies, 120 Beetles, 20 Biting, 3, 32 Black Species, 120 Bombus, 16 — terrestris, 41, 42 Brain, 125 Bramble Stems, 12 Breeding, 113 Broods, 13 Burrows, 9 </div> <div class="stanza"> Calcaria, 70, 135 Carder Bees, 40 Cardines, 75 Carpenter bee, 55 Caterpillar, 19, 20 Cells, 10, 12, 28, 29, 40, 58 — hexagonal, 28 — pitcher-shaped, 58 — waxen, 29, 40 Ceratina, 47, 128 Chimneys, 25 Chloroform, 118 Chrysis, 27 Cilissa, 48 Cleaning hairs, 68 Clover fertilization, 39 Cockroaches, 128 Cocoons, 33, 58 Coleoptera, 128, 129 Colletes, 44 Colonies, 5, 63 Colour, 100 Colour schemes, 22 Combs, 23, 68, 69 Corbicula, 67 Coxæ, 135 Crabro, 95, 102 — albilabris, 119 Cuckoos, 3, 14, 30, 54 — flight of, 85 Cyanide, 116 </div> <div class="stanza"> Dasypoda, 48 Development, 124 Digestion, 125 Diggers, 6, 7 {142} Diptera, 129 Distribution, 105 Domestication, 41 Drone flies, 3 Dufourea, 106 </div> <div class="stanza"> Earwigs, 128 English names, 55 Epeolus, 45 Ether, 117 Eyes, 134 </div> <div class="stanza"> Females, 95 Femur, 135 Figwort, 36 Figure of insect, 133 Flies, 3, 129 Flower lovers, 6 Flute, 57 Food, 6, 28 Foot, 135 Formica, 34, 59 — fusca, 119 — sanguinea, 89 Formicoxenus, 96 Fossors, 6, 7 </div> <div class="stanza"> Galleries, 28 Grasshoppers, 19, 128 Growth, 126 Guests of Ants, 89 </div> <div class="stanza"> Hairs, 65, 71 Halictus, 13, 15, 17, 77, 94, 97, 119, 122 Head, 125 Hemiptera, 129, 130 Heterogyna, 28, 31 Heteromorphæ, 130 Hive bee, 2, 16 Homing instinct, 21 Homomorphæ, 130 Honey pots, 29 Hornets, 35 Humble bees, 39 — mutilated, 41 Hymenoptera, 128, 129 </div> <div class="stanza"> Ichneumons, 21 Inquilines, 3 </div> <div class="stanza"> Jewel flies, 21, 27 </div> <div class="stanza"> Keyhole wasps, 101 Killing bottles, 126 Knife-like hairs, 68 </div> <div class="stanza"> Labels, 118 Labial palpi, 5 Labium, 127, 134 Larva, 11, 13 Lasius niger, 91 — flavus, 91 Latin names, 55 Lawn bee, 9 Leaf-cutting bees, 52 Lepidoptera, 129 Ligula, 75, 134 Limbs, 125, 127 Locomotion, 125 Lodgers with ants, 89 Lomechusa, 89 Long-horned bee, 104 Lora, 74 Lysimachia, 106 </div> <div class="stanza"> Macropis, 106 Males, 95 Male wasp, 2 — hornet, 2 Mandibles, 127, 129 Mason bee, 55 Maxillæ, 75, 127, 134 Mayflies, 128 {143} Melecta armata, 61 — luctuosa, 62 Mentum, 74 Met&oelig;cus paradoxus, 38 Mimicking flies, 94 Miscophus, 119 Moss, 29 Mouse's nest, 29 Mouth, 128 Mutilla, 112, 119 Myrmica, 34 Myrmosa, 100 </div> <div class="stanza"> Nests, 24, 26, 31, 35, 45, 49 — in bramble stems, 45 — Humble bees, 40 — of leaves, 53 — of paper, 37 — in wren's nest, 41 Neuration, 136 — figure and explanation of, 133 Neuroptera, 128, 129 Nodes, 33 Nomada, 15, 48 Non-predaceous hymenoptera, 3 Nymph, 11 </div> <div class="stanza"> Odynerus, 24 Orthoptera, 128, 130 Osmia, 48, 56, 120 — bicolor, 59, 121 — inermis, 58 — leucomelana, 57 — parietina, 58 — rufa, 56 Ovaries, 4 Ovipositer, 1 Oxybelus, 86 </div> <div class="stanza"> Palm, 82 Palpi, 134 Panurgus, 49 Paper, 37 Paraglossæ, 76 Paralytics, 18 Plant lice, 19 Poison bags, 1 Pollen collecting, 65 Pompilus, 87 Ponera, 33 Porterage, 34 Post-scutellum, 135 Predaceous species, 3 Preservation, 116 Propodeum, 132, 135 Prosopis, 44, 46 — cornuta, 47 Pulvillus, 135 </div> <div class="stanza"> Queens, 4 </div> <div class="stanza"> Rarity, 105 Ray, John, 63 </div> <div class="stanza"> Sallows, 82 Sandy bank, 83 Saropoda, 93, 111 Scale, 33 Scrophularia, 36 Scutellum, 135 Scutum, 135 Segments, 96 Setting, 117 Sexual structure, 100 Shin, 135 Snail shells, 12, 57 Social species, 3, 4, 28 Solitary species, 3, 4, 6 Spade-like hairs, 69 Sphecodes, 13, 15, 17, 48, 97, 122 Spiders, 19 Stinging, 2, 38 Stings, 2, 32 Stipes, 74 {144} Straws, 12 Structure, 132 Stylops, 77 Submentum, 74 Swarming, 29 </div> <div class="stanza"> Tarsi, 135 Tegula, 133, 138 Thigh, 135 Thorax, 125, 129 Tibia, 135 Tomtit, 42 Tongues, 15, 39, 44, 49, 66, 72 Trochanter, 135 Tubular entrance, 25 </div> <div class="stanza"> Unguiculi, 135 </div> <div class="stanza"> Vagaries of structure, 104 Velleius dilatatus, 38 Vespa sylvestris, 36 </div> <div class="stanza"> Walls, 12 Wasps, social, 35 — solitary, 24 Waspy coloration, 120, 121 Wings, 110 — cells, 112, 133 — folded, 24, 28 — hooks, 110 — nervures, 133 Workers, 4 Wrens' nests, 41 </div> <div class="stanza"> Yellow-coloured species, 120 </div> </div> <hr class="full" /> <h3>NOTES</h3> <div class="note"> [1] In this case, only the actual tongue (or ligula) and its paraglossæ are figured. [2] The Guests of Ants and Termites, by E. Wasmann, S. J., translated by H. Donisthorpe, F.Z.S. (Ent. Record, Vol. xii., 1900.) [3] cf. Transactions of the Entomological Society of London, 1884, p. 251 et seq.: Hymenoptera Aculeate of the British Islands, etc. </div>   <div class="figright"> <ANTIMG style="width:100%" src="images/pmark2.png" alt="Printers Mark" title="Printers Mark" /></div> <div style="break-after:column;"></div>

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