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Walker Prizes in Natural History. You

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CHARAKA SAMHITA. F. A. Hassler..

THE CAPABILITIES OF PHOTOGRAPHY NOT UNLIMITED FOR ILLUSTRATING ALL CLASSES OF OBJECTS. O. G. Mason....

LETTERS TO THE EDITOR.

20

Worms on the Brain of a Bird. G. H. French. 20 The International Botanical Congress at Madison. H. J. Webber

A Plea for a Fair Valuation of Experimental
Physiology in Biological Courses. J. Chris-
tian Bay

Mr. McGee and the Washington Symposium.
Carl Barus...

The Lac de Marbre Trout, A New Species.
S. Garman

Tucumcari. Robt. T. Hill..
Chloropia. E. W. Scripture

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1. The relations of inflorescence to cross-fertiliza tion illustrated by the plants of Eastern Massa. chusetts.

2. What depths of formerly overlying rocks, now removed by denudation, may be inferred from the structure of various rocks in Eastern Massachusetts ?

3. Experiments affording evidence for or against the theory of evolution.

Each memoir must be accompanied by a sealed envelope enclosing the author's name and superscribed by a motto corresponding to one borne by 23 the manuscript, and must be handed to the Secretary on or before April 1, 1894. Prizes will not be awarded unless the memoirs are of adequate merit.

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Trees as a Factor in Climate. J. W. Slater. Mineral Wax. C. D. Hiscox

BOOK REVIEWS...

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NEW METHOD OF PROTECTING BUILDINGS FROM LIGHTNING. SPARE THE ROD AND SPOIL THE HOUSE! Lightning Destroys. Shall it be Your House or a Pound of Copper?

PROTECTION FROM LIGHTNING.

What is the Problem?

IN seeking a means of protection from lightning-discharges, we have in view two objects, the one the prevention of damage to buildings, and the other the prevention of injury to life. In order to destroy a building in whole or in part, it is necessary that work should be done; that is, as physicists express it, energy is required. Just before the lightning-discharge takes place, the energy capable of doing the damage which we seek to prevent exists in the column of air extending from the cloud to the earth in some form that makes it capable of appearing as what we call electricity. We will therefore call it electrical energy. What this electrical energy is, it is not necessary for us to consider in this place; but that it exists there can be no doubt, as it manifests itself in the destruction of buildings. The problem that we have to deal with, therefore, is the conversion of this energy into some other form, and the accomplishment of this in such a way as shall result in the least injury to property and life.

Why Have the Old Rods Failed?

When lightning-rods were first proposed, the sclence of energetics was entirely undeveloped; that is to say, in the middle of the last century scientific men had not come to recognize the fact that the different forms of energy heat, electricity, mechanical power, etc.- were convertible one into the other, and that each could produce just so much of each of the other forms, and no more. The doctrine of the conservation and correlation of energy was first clearly worked out in the early part of this century. There were, however, some facts known in regard to electricity a hundred and forty years ago; and among these were the attracting power of points for an electric spark, and the conducting power of metals. Lightning-rods were therefore introduced with the idea that the electricity existing in the lightning-discharge could be conveyed around the building which it was proposed to protect, and that the building would thus be saved.

The question as to dissipation of the energy involved was entirely ignored, naturally; and from that time to this, in spite of the best endeavors of those Interested, lightning-rods constructed in accordance with Franklin's principle have not furnished satisfactory protection. The reason for this is apparent when it is considered that the electrical energy existing in the atmosphere before the discharge, or, more exactly, in the column of dielectric from the cloud to the earth, above referred to, reaches its maximum value on the surface of the conductors that chance to be within the column of dielectric; so that the greatest display of energy will be on the surface of the very lightningrods that were meant to protect, and damage results, as so often proves to be the case.

It will be understood, of course, that this display of energy on the surface of the old lightning-rods is aided by their being more or less insulated from the earth, but in any event the very existence of such a mass of metal as an old lightning-rod can only tend to produce a disastrous dissipation of electrical energy upon its surface,-"to draw the lightning," as it is so commonly put.

Is there a Better Means of Protection ?

Having cleared our minds, therefore, of any idea of conducting electricity, and keeping clearly in view the fact that in providing protection against lightning we must furnish some means by which the electrical energy may be harmlessly dissipated, the question arises, "Can an improved form be given to the rod, so that it shall aid in this dissipation ? "

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As the electrical energy involved manifests itself on the surface of conductors, the improved rod should be metallic; but, instead of making a large rod, suppose that we make it comparatively small in size, so that the total amount of metal running from the top of the house to some point a little below the foundations shall not exceed one pound. Suppose, again, that we introduce numerous insulating Joints in this rod. We shall then have a rod that experience shows will be readily destroyed-will be readily dissipated - when a discharge takes place; and it will be evident, that, so far as the electrical energy is consumed in doing this, there will be the less to do other damag→

The only point that remains to be proved as to the utility of such a rod is to show that the dissipation of such a conductor does not tend to injure other bodles in its immediate vicinity. On this poin: I can only say that I have found no case where such a conductor (for instance, a bell wire) has been dissipated, even if resting against a plastered wall, where there has been any material damage done to surrounding objects.

Of course, it is readily understood that such an explosion cannot take place in a confined space without the rupture of the walls (the wire cannot be boarded over); but in every case that I have found recorded this dissipation takes place just as gunpowder burns when spread on a board. The objects against woich the conductor rests may be stained, but they are not shattered, I would therefore make clear this distinction between the action of electrical energy when dissipated on the surface of a large conductor and when dissipated on the surface of a comparatively small or easily dissipated conductor. When dissipated on the surface of a large conductor, a conductor so strong as to resist the explosive effect,-damage results to objects around. When dissipated on the surface of a small conductor, the conductor goes, but the other objects around are saved

A Typical Case of the Action of a Small Conductor. Franklin, in a letter to Collinson read before the London Royal Society, Dec. 18, 1755, describing the partial destruction by lightning of a church-tower at Newbury, Mass, wrote, "Near the bell was fixed an irou hammer to strike the hours; and from the tail of the hammer a wire went down through a small gimlet-hole in the floor that the bell stood upon, and through a second floor in like manner; then horizontally under and near the plastered celling of that second floor, till it came near a p'astered wall; then down by the side of that wall to a clock, which stood about twenty feet_below the bell. The wire was not bigger than a common knitting needle. The spire was split all to piece by the lightning, and the parts flung in all di:ections over the square in which the church stood, so that nothing remained above the bell. The lightring passed between the hammer and the clock in the above-mentioned wire without hurting either of the floors, or having any effect upon them (except making the gimlet-holes, through which the wire passed, a little bigger), and without hurting the plastered wall, or any part of the building, so far as the aforesaid wire and the pendulum-wire of the clock extended; which latter wire was about the thickness of a goose-quill. From the end of the pendulum, down quite to the ground, the building was exceedingly rent and damaged. No part of the aforementioned long, small wire, between the clock and the hammer, could be found, except about two inches that hung to the tail of the hammer, and about as much that was fastened to the clock; the rest being exploded, and its particles dissipated in smoke and air, as gunpowder is by common fire, and had only left a black smutty track on the plastering, three or four inches broad, darkest in the middle, and fainter towards the edges, all along the ceiling, under which it passed, and down the wall." One hundred feet of the Hodges Patent Lightning Dispeller (made under patents of N. D. C. Hodges, Editor of Science) will be malled, postpaid, to any address, on receipt of five dollars ($5).

Correspondence solicited. Agents wanted. AMERICAN LIGHTNING PROTECTION CO., 874 Broadway, New York City.

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Littell's Living Age,

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BRENTANO'S, Union Square, New York, Chicago, Washington, London, Paris. 1869. 1893.

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THE WRENS OF TRAVIS COUNTY, TEXAS.

BY CHARLES D. OLDRIGHT, AUSTIN, TEXAS.

1. Catherpes Mexicanus conspersus, Cañon Wren. This bird is an “endemic" species, its occurrence in any district depending on the topographic features. The great rock walls of the Colorado River, and the numerous side cañons form an ideal dwelling-place for this little bird, and here it may be found at all seasons, and its loud, ringing song re-echoes from cliff to cliff in the dreary days of November as well as in April's sunshine. But it penetrates into the city, and every morning this year one of the first sounds that I have heard has been the matutinal song of a cañon wren whose nest was in a cranny of an unoccupied house standing next to mine.

The cañon wren (as active a busy-body as the rest of his tribe) seems to be never too tired to sing. Reclining on the soft grass at the margin of the rivulet you look up the great frowning cliff and see a tiny bird, now clinging to the perpendicular rock, now disappearing in some crevice of the cliff and then perching on a projecting fragment, he utters a succession of clear bell-like notes in a descending scale

As this wren usually nests in some crevice far up in the cañon wall its eggs are often safe from the hands of the oölogist. Many times have I gazed longingly at a few straws projecting from a hole, while the owner of the nest watched me complacently. In such cases "tis distance lends enchantment to the view." However, I have had the pleasure of examining several nests containing eggs and young, and as I have never seen any detailed account of the nidefication of this species, I will give some particulars about them.

This bird begins building early in the season, a nest with hatching eggs in it having been taken on the 30th day of March. In 1890 fresh eggs were found April 3, 4 and 11.

The nest is placed in some cranny or hole of convenient size, always in the face of the cliff; other situations are on a rafter in a barn, under the cornice on a veranda and in the chimney of an uninhabited house.

The nest is composed of grass and weeds and lined warmly with hair, wool and cotton. The complement of eggs varies from three to five, four being perhaps more usual than either of the other numbers.

The eggs always have a clear white ground, while the markings vary from a very slight sprinkling of brown pin-points to numerous large blotches and spots of reddish-brown and lilac, forming a confluent ring encircling the crown; this is the most common pattern of coloration. Their shape is ovate or rounded ovate, but I have seen one pyriform egg in the nest with three other normally shaped eggs.

2. Phryathorus ludovicianus, Carolina Wren. An abundant bird in the bottom lands along brooks and in all heavily timbered country. The Carolina wren is another fine singer, but spends too much of its time in scolding owls, crows and men. But often, especially in the spring and at sunset on a summer's day, one of these birds will perch on the topmost twig of a tall shrub and will, with his tail drooping and head thrown back, call "sweet William " until the woods resound. By the way, "sweet William " does not express the exact sound of the bird's notes to me, but I am so hopeless of expressing birds' voices by English words that I will not attempt to amend it.

This bird cannot be called particular in its choice of a nestingplace, for their nests have been found in hollow logs, under the cornice of a house, in a tin can placed in a tree, in a hole in a rock wall and on the window sill of a farmhouse. The hollow log is, I believe, the most usual situation. The nest is made to fit the cranny in which it is built and generally fills it. Twigs,

grass weeds. leaves, hair, cotton, wool, rags, paper and even other materials enter into its composition. In shape it is more or less rounded, with an entrance in the side. The eggs are four, five or six in number, five being most common.

There is not much variation in the eggs; the markings being in some heavier than in others. The ground color is white, spotted thickly and finely with specks of reddish-salmon color and lilac, generally forming a poorly defined ring around the crown. The ground color is usually well concealed.

Fresh eggs may be found from April 1 to May 15, the height of the breeding season being during the middle of April. 3. Thryothorus bewickii murinus, Baird's Wren. Probably our co:umonest wren, found in all kinds of country, bottoms or uplands, forest or prairies, mountains or plains. I believe, however, that Baird's wren prefers a broken country, little patches of prairie and mesquite groves alternating with the timber.

A number of these birds must spend their whole lives in the city of Austin, for in nearly every garden one may find a pair.

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They are fussy little creatures hardly ever silent for a moment but keeping up a lively chatter or querulous "chee, chee, chee." But all through the spring, even as early as January, the males are great singers, and early on an April morning one cannot go far without hearing the sweet and cheerful song of one of these little birds. At such times one finds the bird perched in a tree-top, but on other occasions he will be hopping amongst the bushes or along a rail fence. flirting his long tail, uttering a continuous chirp, chirp," and at each third "chirp" stopping a moment to pour forth his little ditty. This is kept up for hours at a time. In February the wrens become restless and may be seen promenading the back yards in pairs peering into every hole and bird-box. They seem to be often un lecided as to a nesting p'ace, for I have known of a pair starting four different nests within a week, without any apparent cause for their fickleness. Any place seems good enough for this bird to start a nest-though as I have just stated they are more particular about its final location. Many people here have put small wooden boxes at their gates for the reception of mail matter, and I verily believe that each one is looked into once a year by a Baird's wren, with a view to building in it, and indeed many are chosen as nesting sites.

The nest is simply a mass of rubbish-but always warmly and softly lined with feathers or cotton. Six is a common complement of eggs, but as many as eight or as few as four may constitute a full set. The eggs are white, more or less speckled with brown of varying shades and lilac, sometimes the specks of reddish brown are thickly and uniformly distributed, again they are collected into a ring surrounding the crown or else rather larger specks of chocolate brown and lilac shell markings are more sparingly disposed.

Two "albino" eggs came under my notice last spring; one was immaculate white, the other had a very faint speckling on the crown; both these eggs were with other normally colored eggs. I also found a peculiar "runt" egg of this species, it is of normal coloration but measures only .55 by .44, being thus the size of a humming bird's egg. I found it one day in a hole in a telephone pole, and left it thinking that more eggs might be laid, as I saw the birds at hand; but when, after the lapse of several days, none were deposited, I took it. Why the bird laid no more I do not know. Surprise at the first one may have had something to do with it.

4. Troglodytes aëdon aztecus, Western House Wren.

Of this member of the family I can say but little, for during his winter stay with us he is very silent and indeed shy.

I am aware that he, like his kinsmen, can scold with remarkable vehemence, for I have heard him. While he remains with us he is to be found in the creek bottoms wherever there are

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thickets of brush wood. He remains with us until late in the spring, indeed the other wrens have young ones before he thinks of leaving for his northern summering place." Last year I saw some on the 22nd of April. I sent one of them to Washington where the "bird doctors" pronounced it "aztecus."

5. Salpinctes obsoletus, Rock Wren.

This bird hardly deserves a place to itself, being quite uncommon and differing little in appearance and mode of life from the Cañon wren, which seems to represent it with us. It is more common further west. Indeed, this is the most easterly record in Texas of its occurrence.

METALLIC CARBIDES.

BY F. P. VENABLE, CHAPLE HILL, N. C.

THIS name is given to compounds formed by the direct union of carbon with the metals. They are not numerous nor do they seem to be easy of formation and it is very difficult to prepare them in a pure and definite form. Consequently they have been but little studied so far. None of them are known to occur in minerals of terrestrial origin.

Interest in these bodies has been heightened of late by the discovery of new ones, and by the instructive decompositions of some of them.

First as to the general mode of formation. They are usually formed by the action of intense heat upon the metal in the presence of carbon. The form of this carbon is capable of being greatly varied. Graphite, amorphous carbon and many hydrocarbons can be used. The carbide is especially formed when the metal is being extracted from its compounds, that is, in the nascent state. Several metals thus unite with carbon in the process of manufacture, as zinc, copper and notably iron, and the presence of the carbides renders the metal hard and brittle. The purification and analysis of these bodies is not at all an easy problem, and hence little or nothing is known of their formulas or chemical constitution. Five or more formulas have been assigned to iron carbide, and, of course, several may exist, still the correctness of any of these formulas is questionable.

The heat of the ordinary furnace is sufficient to form the carbides of the metals already mentioned. For others, more recently discovered, as the carbides of aluminium, of calcium, of barium, etc., the intense heat of the electric furnace is necessary. The first of these, aluminium carbide, is a most interesting body, of a light golden yellow color, it can be gotten from the electric furnace in a mass of corundum and metallic aluminium. It was described first by Sterry Hunt. Though it will stand intense heat in the air without appreciable change, yet really it is undergoing change all the time as is proved by the odor of hydrocarbons corning from it and the fact that left to itself in air it crumbles in a few weeks into a mass of white alumina. A few shining golden scales of the pure substance can be separated, but so far no analysis has been given to the world.

All of these carbides, under certain conditions, give off their carbon in the form of hydrocarbons. The same smell can be detected in all during their decomposition. In some cases, as iron and zinc, the decomposition is caused by the action of an acid.

The carbides of the earths decompose in moist air and more rapidly in water. Calcium carbide decomposes the most energetically of them all. The evolution of the hydrocarbons would be called violent. Of course, the hydrogen needed for the reaction comes from the decomposition of the water or from the hydrogen acid.

A

A most interesting fact recently published in the scientific journals, is that the calcium carbide on decomposition yields lime and pure acetylen gas. The acetylen seems very pure. thousand cu. cm. of the evolved gas was passed into an ammoniacal solution of copper chloride, and not a bubble went through. All was absorbed and precipitated. This is very important because the modes of preparing acetylen in common use are tedious or expensive, and hence this important hydrocarbon has not been as carefully studied as it otherwise might have been. The formation of hydrocarbons by the decomposition of iron carbide has furnished a basis for one of the theories as to the origin

of petroleum. If great quantities of iron carbide existed beneath the earth's surface and were subjected to decomposing influences, such oils and gases as are found in petroleum regions might very easily be formed.

So far there has been little utilization of these carbides commercially. One of the purer forms of iron carbide is used in a process for preparing metallic sodium, and the iron carbide in cast iron confers upon it many of its useful properties. If these bodies can be produced cheaply enough, however, there is strong probability that certain of them will prove very useful.

PHILOSOPHY IN THE COLLEGE CURRICULUM.

BY HOLMES DYSINGER, CARTHAGE COLLEGE, CARTHAGE, ILL. STUDIES under the name of philosophy are to be found in almost every college curriculum. Either because the subject is too vague or abstruse for the comprehension of the average student, little more than elementary [sychology, which is rightly regarded as a necessary part to the introduction to the subject. proper, and a brief discussion of practical ethics, are taught in most of the schools outside of the few real universities. While the number of subjects advocated for introduction into the college course is increasing constantly, one so fundamental as philosophy should not be neglected. Apart from its theoretical value, it has practical bearings upon the intellectual range of a man, regardless of the system he adopts, that commend it to the thoughtful consideration of educators.

The subject-matter with which philosophy deals bears a peculiar relation to all other subjects in the course, in as much as its office is, partly at least, to systematize and explain all the principles of the particular sciences. This gives the unity so desirable in a course of study, and so essential to the thoroughly-trained mind. From this it serves the highest purpose in education and deserves a prominent place in every course of liberal culture.

The philosophical powers of man are last in order of development. The subject-matter makes it necessarily so. It is the most abstruse of all forms of knowledge. The mind in its unfolding passes up through perception and conception to the realm of widest generalizations and the discovery of the principles that are assumed in all our thinking. Philosophy deals with forms of knowledge that stand at the farthest remove from that furnished in so-called presentation - the first development in the mind's unfolding.

When the mind reaches that stage of development in which it apprehends the principles fundamental to all knowledge, it turns in upon itself and critically examines its own processes and assumptions to determine the certainty of being and the validity of our knowledge. This is the highest stage in man's intellectual ascent. Here he stops. He has completed the circuit of the globe of knowledge. He started with the facts furnished in sense and consciousness, and ends in the principles that underlie and embrace all knowledge. These stand accredited in his own thinking. Beyond this the mind of man cannot penetrate.

That many students cannot attain this stage of knowledge is evident to all who have taught the upper classes in our colleges; that but few who attempt it get further than the outer court, is to be expected; but that all are greatly benefitted intellectually would not be denied by those who have looked into the merits of the case and examined the evidence with impartiality. A few additional facts will give our reasons for this conclusion.

Notwithstanding its abstruseness, as a discipline in thinking and in logical method, philosophy has no equal. Facts as furnished by the senses and distinguished from principles are not dealt with in philosophy, but the relation of facts to one another and to all things else. All these in a system of philosophy deserving of study or worth elaboration must be included in their relations of coördination and subordination. The unity of all bing is the ultimate problem of philosophy. A nairower range and lower ideal may satisfy science, but it cannot attain to that which comprehends all knowledge. Only the mind well disciplined in logical method can grasp the facts, but the one who attempts to do so will develop a power that is the possession of few and the desire of all

This apprehension of facts as related is essential and necessarily precedent to the discovery of principles which govern these relations. In this respect practical fruit is to result from the study of philosophy. Not simply philosophers, but even the students of philosophy, must get a more comprehensive grasp of facts and principles, as each is assigned its place in the whole system of knowledge. Truth is apprebended in its harmonies and wholeness. It is seen in its proportions.

If more attention were given to a careful study of philosophy as a system, rather than in its history, much of the conceit of knowledge which is so prevalert to-day would be unheard of. The specialist would soon discover that he was occupying a very small niche in the universe of knowledge; the broadest scholar that his horizon included but an infinitesimal portion of the sphere of truth.

BRITISH STONE CIRCLES. — III. DERBYSHIRE CIRCLES.' BY A. L. LEWIS, TREASURER ANTHROPOLOGICAL INSTITUTE, LONDON,

ENGLAND.

THE Peak district of Derbyshire, so justly famed for its scenery, possesses also many attractions for the archæologist, among which are two stone circles.

The larger of these, called Arbor Lowe or Arbe Lowe, is about six miles from Bakewell, and consists of an oval ring, the diameters of which were about 126 and 115 feet, the precise lengths being difficult to ascertain in consequence of the stones, which doubtless originally stood upright, being now all flat, and having fallen, some outside, some inside, and some across their original positions, while others are broken into fragments or buried in the soil. There were perhaps about forty stones, of which nearly thirty remain entire or in fragments, the largest being about twelve feet long, six broad, and four thick. The longest diameter of the oval ran nearly northwest and southeast, and somewhat more to the west and east, two of the stones seem to have stood back outside the regular line of the oval. Within the oval, and on the line of the longest diameter, but not in the centre of it (the distances from the northwest and southeast ends being in about the proportion of three to two), are the remains of some large stones - one fourteen feet long - which were apparently three in number, forming a "cove," _, like that in the centre of the northern circle at Abury, the central stone of which faced the rising sun on Midsummer Day. Like the circles at Abury, the stones at Arbelowe are surrounded by a ditch, which is about seven feet deep and fifteen wide at the bottom, outside of which is an embankment, formerly perhaps ten feet high and eight wide at the top; Sir G. Wilkinson says somewhat more, but it may be that he took the maximum and I took the minimum of the measure. This embankment is now very irregular, and in one place a tumulus has been formed from the materials composing it, in which were found two Celtic vases and a bronze pin. This tumulus could hardly have formed part of the original plan of the monument, and would therefore seem to have been made after the latter had fallen into disuse. The embankment, like that at Abury, is not a true circle, and there is much similarity in the irregularities of both, but that may be quite accidental. There are two entrances, one southeasterly, in the same direction as the Kennet entrance at Abury, and one to the northwest, but not quite opposite to the other; altogether Abury and Arbelowe, notwithstanding the great difference between them in size, have more points in common than any other circle has with either. Just outside the southeast entrance are two small stones, quite as likely to have been taken from the interior as to be in their original places. Nearly three hundred yards to the southwest is a tumulus, called Gib Hill, about twenty feet high and as wide at the top, in which a small cist was found, two feet under the surface, which contained a vase, two worked flints, and an iron fibula with places for stones- probably a secondary interment. A bank of earth of doubtful antiquity runs from the embankment for some distance in a direction south of Gib Hill. These various

1 No. 1, Abury, appeared in No. 529, Varch 24; No. 2, Stonehenge, appeared in No. 537, May 19. To those who may wish for more minute details of measurements than can be given in a short article, I would recommend "Stonehenge," by Professor Flinders Petrie, D.C.L. (Stanford, London).

earthworks have been supposed to give the form of a serpent to the monument, but Sir Gardner Wilkinson's plan shows this idea to be quite incorrect; this is a point for the visitor to verify. On the moors at the top of the hills above Eyam is a small circle of a different character from Arbelowe; it is called the "Wet Withins," and consists of a bank of earth, about six feet wide and two high, inside which, but close to the bank, was formerly a ring of small stones about two feet high and of proportionate size, of which ten remain, out of perhaps twenty or more. The diameter of this circle is about one hundred feet, and some sixty feet to the north-northeast there is a barrow, eighty-three feet long (from northeast to southwest) and forty-six feet wide.

There are some other small remains of a similar character in Derbyshire, but I have not seen them myself, and doubt whether they are worth the trouble of a visit.

CHARAKA SAMHITA.

BY F. A. HASSLER, M.D., PH D., SANTA ANA, CAL. THE student of Hindu literature has before him an ever-widening field of research. He must be prepared for glimpses and magnificent views of learning and wisdom which will astonish and delight him at every turn. The thoughts and the meth d of expression are different from those of other nations, and there is scarcely a subject, except, perhaps, electricity and steam, that has not been discussed by these ancient sages. The philosopher will find his theories, the anarchist his ideas, probed to the bottom, and thestudent of the supreme soul, high, noble thoughts, and even from this grand subject down to the every day question of mistress and maid, we do not think of any matter that will not be found fully investigated in the pages of the Mahabharata.

So the physician of our day will find in the Charaka and other works of ancient India many views of health, disease, and remedies which he fondly imagined were jewels in the crown of modern science. When a young man wishes to study medicine,

he may receive a little instruction from his pr ceptor, but places his chief reliance upon the teachings of some medical school from which he receives his diploma. This was not the custom in ancient India. There were no colleges. Every student became a part of his preceptor's household, was lodged and fed by him, and beyond a few light services was not asked for any return. It is plain that such teachers could not instruct all their scholars by word of mouth. This accounts for the immense number of medical works of ancient India.

We cannot tell the age of the Charaka, it is based upon a work of Agniveca, which carries us back to almost mythical times. The very name of this supposed author sounds like the mystery of long past ages, for it may be translated "the dwelling-place of fire." Ten years of study of the Mahabharata has led me to quite certain conclusions as to the time when that great work was written, and I should say that the style, of the first part at least, of the Charaka corresponds with that portion of the Mahabharata which I think was written about the sixth century before Chri-t, or, in other words, about the time of the rise of Buddhism. Whatever its age may be, this we know, it is exceedingly ancient. It is mentioned by Avicenna, Rhazes, and others, and is supposed to have been translated by the early Persian and Arabian writers on medicine. But we forget its age when we read its pages. The work is immense. An English translation, now being published by Doctor Kiviratna, the learned editor of several Sanscrit works and of a medical journal in Bengali, will probably cover from fourteen to fifteen hundred royal octavo pages. But it is not its size to which I wish to call attention, it is the wisdom and learning found in it that make it so valuable and interesting.

In a short article like this I cannot expect to do more than give the reader a glimpse of the work and a quotation here and there. We are told that in the earliest times some fifty-odd learned men assembled to study the science of life and the causes of disease; in fact, it was a medical convention similar to those of our day. The first conclusion they arrived at was that "Freedom from disease is the excellent root of religion, profit, pleasure, and salvation. Diseases are depredators thereof, as also of happy life. This, therefore, is a great enemy of men that hath appeared.

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