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In a paper on 66 'Molecular Electro-Magnetic Induction," presented to the Royal Society (March 7, 1881, I gave a description of the induction currents produced by the torsion of an iron wire, and the method by which they are rendered evident. The electro-magnetic induction-balance there described is so remarkably sensitive to the slightest internal strain in anywise submitted to it, that I at once perceived that the instrument could not only determine any mechanical strain such as torsion or longitudinal stress, but that it might indicate the nature and cause of internal strains. question to it, Does the passage of electricity through a wire Upon putting the produce a change in its structure? the answer came, It does, and that to a very considerable extent; for an iron wire adjusted to perfect zero, and which would remain free from any strain for days, becomes instantaneously changed by the first passage of a current from a single cell of a Daniell's battery; the wire has now a permanent twist in a direction coinciding with that of the current, which can be brought again to zero by mechanically untwisting the wire, or undoing that which the passage of electricity has caused. Before describing the new phenomenon, I will state that the only modification required in the apparatus is a switch or key by means of which the telephone upon the wire circuit is thrown out of this circuit, and the current from a separate battery of two bichromate cells passed through the wire alone, at the same time, care being taken that no current passes through the coil, but that its circuit should remain open during the passage of the electric current through the wire under observation; an extra switch on this circuit provides for this. The reason for not allowing two currents to react upon each other, is to avoid errors of observation which may be due to this cause alone. When, however, we take an observation, the battery is upon the coil and the telephone upon the wire alone. An experiment thus consists of two operations. First all external communications interrupted, and an electric current passed through the wire; and, second, the electric currrent taken off the wire, and all ordinary communications restored. rapidly by means of the switches, very quick observations can As this is done be made, or if desired the effects of both currents can be observed at the same instant.

Now if I place upon the stress bridge a soft-iron wire millim. diameter, 25 centims. long, I find, if no previous strain existed in the wire, a perfect zero, and I can make it so either by turning it slightly backwards or forwards, or by heating the wire to a red heat. If I now give a torsion of this wire, I find that its maximum value is with 40° torsion, and that this torsion represents or produces electric currents whose value in sonometric degrees is 50; each degree of torsion up to 40 produces a regular increase, so that once knowing the value of any wire, we can predict from any sonometric readings the value in torsion, or the amount of torsion in the opposite direction it would require to produce a perfect zero.

If now I place this wire at zero, and thus knowing that it is entirely free from strain I pass an electric current through it, I find that this wire is no longer free from strain, that it now gives out induction currents of the value of 40, and although there is no longer any battery current passing through this wire that the strain is permanent, the outside coil neither increasing nor diminishing the internal strain it has received by the passage of an electric current through the wire; upon giving a torsion to the wire in one direction, I find the inductive force increase from 40 to 90, but in the other direction it is brought to zero, and the amount of torsion, some 35°, required to bring the wire again to zero represents exactly the twist or strain that had been produced instantaneously by the passage of an electric current. If I repeat the experiment, but reverse the battery current sent through the wire, I find an opposite twist of exactly the same value as previously, and that it now requires an opposite torsion to again bring the wire to zero. an equal opposite torsion on wire to bring the currents to zero, It is not necessary however to put on for as I have shown in my late paper, the sonometer not only allows us to measure the force and indicate its direction, but allows us to oppose an equal electric current of opposite name, thus producing an electrical zero in place of the mechanical one produced by torsion.

Evidently here there has been a sudden change in the structure of the wire, and it is a twist which we can both measure and reproduce. The question at once becomes, Has a molar twist been given to the wire such as would be detected by the arm or free end of the wire, or a molecular change leaving no trace upon its external form of what has passed?

[April 14, 1881

of torsion to annul the effects of a passage of an electric current, no visible movement nor any tendency of the free end to turn in the direction of the twist it has received can be observed. I believe however to have noticed a slight tremor or movement of half a degree, but as I could not always reproduce it, and as it is so slight compared with the 4c° of internal twist, I have not taken it into account, for if the wire is firmly fastened at both ends no molar torsion being possible, except an elastic one, which would instantly spring back to zero, the current on passing produces its full effects of twist and it is permanent. Thus the molecules have in some extraordinary way rearranged themselves into a permanent twist, without the slightest external indication of so great a change having taken place. An equally remarkable change takes place in aid of, or against (according to direction of current) an elastic permanent strain. Thus, if I first put the wire under 40° right-handed permanent torsion, I find its value to be and negative to fixed end, the induction currents rise at once in 50. Now, passing the positive of battery through its free end, value to 90; if, now, the negative is momentarily passed through the free end and positive to fixed end the induced currents at elastic torsion the wire no longer comes to zero, but has the full once fall to 10, and these effects remain, for on taking off the twist value produced by the current.

Tempered steel gave only one or two degrees against fifty for rigidity, I carefully brought the wire to zero, and then observed soft iron, but supposing this might be due to its molecular the first contact only. I found then that the first contact gave a bringing the wire back to zero by a momentary touch with a value of 40, but the second and following only one or two. By magnet a continued force of 40, or if constant reversals were similar great molecular change by the passage of a current in used instead of a simple contact, there was constant proof of a steel as well as iron.

I can find no trace of the reaction of the wire upon the magnetism of the earth, as in all positions the same degree of force was obtained, if great care is taken that the wire is absolutely free from longitudinal magnetism; there is however a slight reaction upon its own return wire if brought within I centim. distance of the wire, and this reduces the twist some 10°. The maximum effects are obtained when the return wire is not nearer reaction, but by direct action upon its internal structure. than 25 centims. ; thus the action is not one produced by a

I

believe, however, that a similar strain takes place in all conductors, Copper and silver wires so far show no trace of the action. however, to verify this, would require a different method of and I have obtained indirectly indications of this fact; in order, observation from the one I have described, and I have not yet perfected the apparatus required.

It seemed probable that if I approached a strong permanent magnet to the wire, I should perceive a twist similar to that proobserved. But it has a most remarkable effect of instantly duced by the passage of a current; but no such effects were bringing to zero a strain produced by the current, and, no matter which pole, the effect was the same. which remains a constant, instantly disappears upon the producThus, a strain of 50°, tion of longitudinal magnetism, and I have found this method of reducing an iron wire to zero of strain far more effective than any other method yet tried, such as vibrations, heat, twisting, &c. It will be seen from this that the molecular arrangement set up by magnetism is very different from that produced by the passage of an electric current. its own, else it would not have instantly destroyed the spiral It evidently has a structure of strain left by the passage of electricity if it had not taken up a new form, as rendered evident in the longitudinal magnetism, which we could at once perceive on the wire. This question, apparatus will aid me later in throwing some new light upon however, belongs to a separate investigation, and I hope the this subject.

of a current, is to keep the wire in a constant state of vibration. Another method of reducing the wire to zero, after the passage It requires in time about one minute to bring it to zero, but if, on the contrary, I set the wire vibrating during the passage of the current, the permanent twist becomes greater and more difficult to reduce to zero.

If a wire which has internal strains is heated to redness, these strains almost entirely disappear, and I can thus reduce by heat a strain which a current had produced, but heat, whilst allowing of greater freedom and motion of its molecules, does not prevent an internal strain being set up, for whilst heat can reduce the wire to zero, after the passage of the current, the effects are

It will be found that, notwithstanding that it requires some 40° | increased. If, during the time that the wire is at a red heat, the

current is passed in the same time, and at the same instant we take off the current and the external heat, the wire when cold will be found to have a higher degree of strain than previously possible with the wire when cold.

We have seen that both mechanical vibrations and heat can reduce the wire to a zero, but its action is very slow, several minutes being required; but the action of electricity in producing a permanent twist is exceedingly quick. I have found that a single contact, whose duration was not more than oor of a second, was equal to that of a prolonged contact of several minutes, and magnetism was equally as quick in reducing this strain to zero. And it is the more remarkable when we consider the very great mechanical force required by torsion of the wire to untwist the strain produced in an instant of time by

electricity.

The results I have given are those obtained upon soft iron wires of millim., but I have experimented with different sizes up to 3 millims. diameter. The results with 1 millim. diameter were quite as evident as the millim., but on the 3 millim. wire the strain was reduced to 25° instead of 50°, owing to the extreme rapidity and low electrical resistance compared with my small battery wires. On a telegraph line, the wire of which is almost entirely of iron, there must be a very great strain set up, which however would remain a constant, except where reversed currents are used, and in this case a constant movement of the molecules of the wire must be the result.

I believe it to be most important that we should determine, as far as we can by experimental research, the nature of all molecular changes produced by electricity and magnetism, and in this belief I am happy in being able to bring this paper before the Royal Society.

Chemical Society, April 7.-Dr. Russell in the chair.-The following papers were read :-On the organic matter in seawater, by W. Jago. The author concludes that the organic matter of sea-water is much more capable of resisting oxidising agents than that present in ordinary fresh water, and that it is probably organised and alive.-On the action of compounds inimical to bacterial life, by W. M. Hamlet. The cultivating fluids used comprised Pasteur's fluid, beef tea, hay infusion, urine, brewer's wort, and extract of meat; these were sterilised by boiling for ten minutes in Pasteur's flask, cooled with suitable precautions, and then seeded with hay solution, and the substance under examination added. Many gases, &c., were tried. Chlorine and hydric peroxide were fatal to bacteria, while chloroform, creosote, carbolic acid, salicylic acid, &c., hindered their development, but did not destroy them.

Anthropological Institute, March 22.-F. W. Rudler, F.G.S., vice-president, in the chair.-The election of George B. Waterhouse was announced.-Mr. R. W. Felkin exhibited a series of photographs of scenes and natives of Central Africa, taken by Herr Buchta.-Prof. Flower, F.R.S., exhibited a collection of crania from the Island of Mallicollo in the New Hebrides, which had been lately presented to the Museum of the Royal College of Surgeons by Mr. Luther Holden. The peculiar conformation of the heads of the people of this ísland attracted the attention of Capt. Cook and the naturalist Forster, who accompanied the great navigator on his second voyage, and who writes that "the depressed and backward inclining forehead causes an appearance in the looks and countenances of the natives similar to those of monkeys." Yet Cook bears testimony to the activity, intelligence, and honesty of this "ape-like nation," as he calls them. A few years ago Mr. Busk described some skulls collected in the island by the late Commodore Goodenough, and found that they all showed signs of having undergone alterations in form from pressure applied in infancy. The present collection corroborates Mr. Busk's views; some of the skulls being deformed to a remarkable degree, and closely resembling the well-known Peruvian crania from the neighbourhood of Lake Titicaca. This is the more remarkable, as on no other of the numerous islands of the neighbouring ocean is the practice known to exist. Besides the deformed crania the collection contained several monumental heads, said to be those of chiefs. In these the features are modelled in clay upon the skull, apparently with the intention of preserving a likeness of the dead person; the face is painted over with red ochre, artificial eyes introduced, and the hair elaborately dressed and ornamented with feathers. In one case the hair had been entirely removed, and a very neatly-made wig substituted. The head thus prepared is stuck upon a rudely-made figure of split bamboo and clay, and set up in the village temple, with the weapons and

small personal effects of the deceased. This is a custom not hitherto known to exist among the Mallicollese, and its motive is not completely understood, but it is obviously analogous to many others which have prevailed throughout all historical times and in many nations, manifesting itself, among other forms, in the mummified bodies of the Ancient Egyptians and the marble busts over the mouldering bones in Westminster Abbey.—Mr. Joseph Lucas read a paper on the ethnological bearings of the terms Gipsy, Zingaro, Rom, &c.

Zoological Society, April 5.-Prof. W. H. Flower, LL.D., F.R.S., president, in the chair.-Mr. Sclater exhibited five bird's skins obtained by the Rev. G. Brown, C.M.Z.S., on the Island of Rotumeh, and presented by him to the Challenger Expedition. Mr. Sclater also exhibited specimens of two new species of birds from New Britain, belonging to the Museum Godeffcoi, which he proposed to call Trichoglossus rufigularis and Ortygocichla rubiginosa -Mr. H. E. Dresser exhibited and made remarks on a specimen of Saxicola deserti killed in Scotland, and a specimen of Picus pubescens believed to have been killed in Normandy.—Mr. W. A. Forbes, F.Z.S., read some notes on the external characters and anatomy of the Californian Sea Lion (Otaria gillespii), and exhibited some coloured drawings of this animal.-Prof. Flower, F.R.S., read a note upon the habits of the Manatee, chiefly in reference to the question as to whether this animal had the power of voluntarily leaving the water for the purpose of feeding on the herbage of the banks, as stated by many authors, and as supported by a communication from the late Mr. R. B. Dobree, notwithstanding which Prof. Flower considered the evidence upon which the statement was based to be very unsatisfactory.-A paper was read upon the same animal by Miss Agnes Crane, consisting of observations upon the Manatees lately living in the Brighton Aquarium.Dr. A. Günther, F.R.S., read an account of the Amphisbænians and Ophidians collected by Prof. Bayley Balfour in the Island of Socotra. A new form of snakes allied to Tachymenis was named Ditypophis vivax, a new species of Zamenis was named Z. Socotra, and a new form of Amphisbænian Pachycalamus brevis.-Mr. W. T. Blanford, F.R.S., gave an account of six species of lizards which had been collected by Prof. Bayley Balfour in Socotra; of these the three following appeared to be undescribed:-Hemidactylus homæolepis, Pristurus insignis, and Eremias Balfouri.-Mr. Charles O. Waterhouse read a paper on the coleopterous insects which had been collected by Prof. Bayley Balfour in Socotra. The number of species of which examples were collected was twenty-four, and showed that the fauna of Socotra, judging from this collection, was distinctly African. Twelve of the species appeared to be new.-A communication was read from Prof. J. O. Westwood containing observations on two species of Indian butterfles, Papilio castor and P. pollux.-A communication was read from Mr. Edgar A. Smith, containing some observations on the shells belonging to the genus Gouldia of C. B. Adams.-Mr. Sclater read the fifth of his series of notes on the birds of the vicinity of Lima, Peru, with remarks on their habits by Prof. Nation, C.M.Z.S. new species of Buarremon, of which an example was in the collection, was proposed to be dedicated to its discoverer as B. Nationi.-Mr. G. E. Dobson read some notes on certain points in the muscular anatomy of the Green Monkey, Cercopithecus callithrix.

EDINBURGH

A

Royal Society, March 21.-Sir Wyville Thomson, vicepresident, in the chair.-Prof. Geikie communicated a paper by Mr. C. A. Stevenson, B.Sc., on the earthquake of November 28, 1880, in Scotland and Ireland. The main conclusions at which the author arrived were the following:-The centre of the disturbance was at a point some thirteen miles south-west of Fladda, in the continuation of the line of the fault that lies along the great glen which stretches in a south-westerly direction from Inverness. The disturbance was felt over an area of 19,000 square miles, extending as far east as Blair Athole, as far north as the Butt of Lewis, and as far south as Armagh in Ireland. The undulation was everywhere of an up-and-down character; its breadth was estimated at 1100 feet, and its velocity seemed to vary from 3'75 to 7'75 miles per minute, having a mean value of 6'75 over the sea and 4'68 over the land. The accompanying rumbling was not heard at all the stations, and appeared to have been best heard where but little soil covered the hard dense substratum of rock. The disturbance was felt better over the older rocks. Noises were not heard outside a radius of 38 miles from the centre, except in the north of Ireland, where however it was

suggested that the noise was due to the indirect action of the earthquake in causing a secondary local disturbance.-Mr. P. Geddes read his first communication on the classification of statistics. After pointing out the utter confusion that exists in many of the national classifications of the present time, the author criticised the arrangements suggested by Deloche and Mouat, which were equally unsatisfactory, because of their unscientific and artificial methods. Any classification, to be natural, must be based upon some broad principle common to all kinds of communities or societies. A fundamental meaning must therefore be attached to the word society-a definition given to it that will include societies of all kinds of organisms. Such a definition must obviously take account of the vital functions of organisms in relation to the matter and energy of the universe. We have thus matter and energy on the one hand, organisms on the other. Mr. Geddes, confining himself meanwhile to the first of these two great divisions, proceeded to classify the sources of energy, adopting the classification given by Prof. Tait in his Thermodynamics, and showing how naturally such things as food, fuel, machines, &c., fell into their places in such an arrangement. He then considered the classification of sources of matter used for other than energy-properties, taking for this purpose the well-known three-fold division into minerals, vegetables, and animals. The development of ultimate products through their successive phases of raw material, manufacture, exportation, trade, &c., and the classification of all products under the three chief headings of potential, me liate, and ultimate, completed the one aspect of the statistical method in so far as it related to the matter and energy of the universe. It still remained however to take account of the loss, or more properly the degradation or dissipation, suffered. The classification must indicate not only the kind of loss, e.g. whether in raw material, in manufacture, in trade, in ultimate product, or in remedial effort, but also the agency that was the direct cause of the loss, whether physical, as earthquake, flood, storm, &c.; or biological, as insects, fungi, &c.; or social, as crime, war, or folly.--Mr. T. Muir communicated three mathematical notes: on Prof. Cayley's theorem regarding a bordered skew determinant; on the law of extensible minors in determinants; and on a problem of arrangement.— Mr. J. Y. Buchanan read a short paper on the oxidation of ferrous salts.-Prof. Tait made a brief communication on some space loci.

PARIS

Academy of Sciences, April 4.-M. Wurtz in the chair. M. de Quatrefages presented an example of the Edwards Medal. -The following papers were read :-On micrometric measurements during the transit of Venus of 8 December, 1874, by M. Puiseux. These measurements (393 in number and in five categories) at St. Paul and Pekin fairly agree, though the conditions were unfavourable, and give for the parallax 9"05.-On the same subject, by M. Mouchez. He considers the method is to be strongly recommended for 1882.-Note on the methods of Wronski, by M. Villarceau.-On photographic photometry and its application to study of the comparative radiating powers of the sun and of stars, by M. Janssen. A shutter with triangular aperture is made to pass with uniform motion of known rate before a sensitised plate; this gives (with light) a series of shades on the plate, decreasing from the base side to the apex side. To compare the sensibility of two plates, differently prepared, or the photogenic intensity of two sources (using two like plates) the points of equal shade on the plates are noted. (The photographic intensity does not increase as rapidly as the luminous intensity.) For the sun he finds the time of action (with gelatine bromide of silver plates) must be reduced to sec. to give the most rapid variation in the opacity. The sides of the slit are curved (for a special reason). A series of circular images of stars are obtained by putting the plate a little out of focus.-On alcoholate of chloral, by M. Berthelot.-On lightning flashes without thunder, by M. d'Abbadie. He observed such quite near, in a fog, when in Ethiopia.-On the combinations of phtalic anhy dride with hydrocarbons of the benzene series, by MM. Friedel and Crafts.-Note on chalcomenite, a new mineral species (selenite of copper), by MM. des Cloizeaux and Damour. This is from near Mendoza in the Argentine Republic.-Researches on changes of state near the critical point of temperature, by MM. Cailletet and Hautefeuille. By colouring carbonic acid the liquid is rendered always visible. It is found that Andrews's undulatory striæ dissolve blue oil of galbanum, so that they are produced by streaks of liquefied carbonic acid. Neither in disappearance of a meniscus through compression, nor in change of state at the

critical temperature does matter pass by insensible degrees from the liquid to the gaseous state.-Magnetic anomaly of meteoric iron of Santa Catharina, by Prof. Lawrence Smith. Small fragments are very feebly affected by a magnet till they have been flattened on a steel surface with a steel hammer, or heated red hot.-Attenuation of effects of virulent inoculations by use of small quantities of virus, by M. Chauveau.-M. Jordan was elected Member in Geometry in room of the late M. Chasles.On the winter egg of phylloxera, by M. Lichtenstein.-Researches on the causes which enable the vine to resist phylloxera in sandy soils, by M. Saint-André. Weak capillary capacity of a soil seems to be the direct or indirect cause of the resistance of vines. On the bismuthine produced by coal-mines on fire, by M. Mayençon.-On functions proceeding from Gauss's equation, by M. Halphen.-On a new application and some important properties of Fuchsian functions, by M. Poincaré.-On the relations between solar spots and magnetic variations, by M. Wolf. Tables for 1880 are given. The solar curve is also shown to be quickly rising again; a maximum may be expected in 1882 to 1883. The increase of magnetic declination for 1879-80 is 1'18 by formula, o''99 by observation.-On the viscosity of gases, by Mr. Crookes.-Luminous intensity of radiations emitted by incandescent platinum, by M. Violle. From observations ranging from 775° to 1775° he constructs a formula.-On the change of volume accompanying the galvanic deposit of a metal, by M. Bouty. It is always possible in electrolysis of the same salt to diminish the intensity of current below a certain limit such that the compression produced by the deposit is then changed into attraction (the metal dilating instead of contracting in solidifying). On the voltaic conductivity of heated gases, by M. Blondlot. He describes an experiment made by way of putting the conductivity of gases beyond doubt, and in which all parts of the apparatus are constantly open to inspection.-On the internal discharges of electric condensers, by M. Villari. The laws of the phenomenon are enunciated.-On magical mirrors, by M. Laurent. A common silvered mirror of any thickness may be rendered magical by means of heat; e.g. applying the end of a heated brass tube to it. The section of the tube is imaged.—On hydrosulphite of soda, by M. Schutzenberger. On some new processes of desulphuration of alkaline solutions, by M. Scheurer-Kestner.-On application of the crystals of lead chambers, by M. Sulliot. For disinfection of rooms he places in them porous vessels containing nitrous sulphuric acid, and to attenuate the irritating action of the vapours the vessel is placed in another containing ethylic alcohol. In another case odorous gases are drawn through a column of coke moistened with nitrous sulphuric acid.-On secondary and tertiary amylamines from the active amylic alcohol of fermentation, by Mr. Plimpton.-Action of perchloride of phosphorus on isobutylic aldehyde, by M. Economidès.-Preparation of isobutylic acetal, by the same.-On the products of distillation of colophony, by M. Renard.-Artificial reproduction of diabases, dolerites, and meteorites of ophitic structure, by MM. Fouqué and Levy.-On the Devonian formation of Diou (Allier) and Gilly (Saône-et-Loire), by M. Jullien.

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THURSDAY, APRIL 21, 1881.

SIR WILLIAM HERSCHEL1

III.

"the promise that 2000l. would be granted for enabling him to make himself an instrument."

The forty-feet reflector, the chef d'œuvre of Herschel's optical and mechanical efforts, was commenced about the latter end of 1785, and, as Prof. Holden remarks, the history of the instrument extends from this date until the

IN the concluding chapter of his Memoir Prof. Holden year 1811. The work was carried on assiduously with no

presents a Review of the scientific labours of William Herschel designed to enable the general reader to follow the course of his work and discoveries, astronomical and physical, referring to the Analyse de la Vie et des Travaux de Sir William Herschel, published by Arago in 1842 for a more detailed and precise account suited to the professional astronomer; also to "A Subject-Index and a Synopsis of the Scientific Writings of Sir William Herschel," prepared by himself and Dr. Hastings, and forming one of the publications of the Smithsonian Institution.

Prof. Holden naturally commences his review with the improvements in optical instruments and apparatus effected by Herschel. Up to his time the principal aids to observation were the Newtonian telescopes of Short and the small achromatics of Dollond, the six-foot Newtonians of the former maker, aperture 9'4 inches, and the forty-six-inch achromatics of Dollond, aperture 3.6 inches, were much esteemed, and one of each class was in use at the Royal Observatory, Greenwich, in 1765. Herschel gives us some account of the progress of his manufacture of telescopes in his description of the forty-feet reflector presented to the Royal Society in 1795. When he resided at Bath, he tells us, he had long been acquainted with the theory of optics and mechanics, and wanted only that experience so essential in the practice of these sciences. This he gradually acquired by way of amusement in his leisure hours (we have seen that he was closely occupied in his profession as a teacher of music), and thus he made "several two-foot, five-foot, seven-foot, ten-foot, and twenty-foot Newtonian telescopes, besides others, of the Gregorian form of eight, twelve, and eighteen inches, and two, three, five, and ten feet focal length," in all, as already stated, he made not less than 200 seven-feet, 100 ten-feet, and about 80 twenty-feet mirrors, in addition to the Gregorian telescopes. The number of stands he invented for these instruments he states it would not be easy to assign. Proceeding further, as early as 1781 he had designed and commenced the construction of what he terms (6 a 30-feet aërial reflector," and invented and executed a stand for it; he cast the mirror, "which was moulded up so as to come out 36 inches in diameter," but "the composition of the metal being a little too brittle, it cracked in the cooling." It was cast a second time, but here the furnace gave way and the metal ran into the fire. These accidents and the discovery of Uranus, which introduced Herschel to the patronage of the king, put a temporary stop to the construction of a great telescope. In 1783 he finished "a very good twenty-feet reflector with a large aperture," and after two years observation with it, became so convinced of the advantages of such apertures, that he recurred to his previous intention of increasing them still further. Soon afterwards, by the representations of Sir Joseph Banks, president of the Royal Society, Herschel, as his sister relates, obtained Continued from p. 455.

VOL. XXIII.-No. 599

further interruption than was occasioned by the removal from Clay Hall to Slough, where, soon after arrival, Herschel began to lay the foundation of the whole structure, and the highly-polished speculum was put into the tube, and the first view through it was obtained on February 19, 1787. But he dates the completion of the instrument from a much later period, for the first speculum came out thinner than was intended, and from its weakress did not permit of a good figure being given to it; a second mirror, cast in January, 1788, cracked in cooling ; but in the next month it was re-cast and proved of the proper degree of strength. In October following a pretty good figure and polish had been assured, and Herschel says he observed the planet Saturn with it; he continued to work upon it till August 27, 1789, when upon trial on the fixed stars it gave a pretty sharp image, and on the following night he records, "Having brought the telescope to the parallel of Saturn, I discovered a sixth satellite of that planet, and also saw the spots upon Saturn, better than I had ever seen them before, so that I may date the finishing of the forty-feet telescope from that time." The diameter of the polished surface of the great mirror was 48 inches. In proof of the efficiency of the mechanism for giving horizontal and vertical motions to so large an instrument he mentions that in the year 1789 he had many times taken up Saturn two or three hours before meridian passage and kept the planet in view with the greatest facility till two or three hours after the passage. On the 17th of September a seventh satellite of Saturn, the minute object now called Mimas, was discovered with the forty-feet telescope, and though the instrument was used for various purposes till 1811, these discoveries of satellites constitute its most prominent additions to our knowledge. Sir John Herschel has stated that the entire cost of construction, including the apparatus for casting, grinding, and figuring the mirrors, of which two were constructed, amounted to 4000/., which sum was provided by King George III. His father observed the great nebula of Orion with the forty-feet telescope on January 19, 1811, and this was one of his latest observations. In 1839 the wood-work had so far decayed as to be dangerous, and Sir John Herschel pulled it down, but piers were erected upon which the tube was placed. Writing in March, 1847, he remarks that it was so well preserved that "although not more than one-twentieth of an inch thick, when in the horizontal position it sustained within it all my family, and continues to sustain inclosed within it, to this day, not only the heavier of the two reflectors, but also all the more important portions of the machinery."

As Prof. Holden remarks, and a similar opinion has been expressed previously, it is probable that the general public expected more from the forty-feet telescope than it actually performed; but Herschel gave valid reasons why he did not make more extended use of the instrument : the time required to get it into proper working order and

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the number of assistants necessary were impediments in the way of its being utilised for regular observation, and he assures us he "made it a rule never to employ a larger telescope when a smaller will answer the purpose." It is certain that the mirror which was in the tube in October, 1789, the month following that in which Herschel dates the completion of the telescope, was of excellent definition. On the 16th of that month he followed the sixth and seventh satellites (Enceladus and Mimas) up to the limb of the planet, and witnessed their occultation. Holden writes: "I have never seen so good definition, telescopic and atmospheric, as he must have had on these occasions."

Between the years 1796 and 1799 Herschel made an elaborate classification of stars visible to the naked eye according to their comparative brightness, which he communicated to the Royal Society in four papers published in the Phil. Trans. It formed the first general catalogue of the kind, exhibiting the exact state of the sky in his time. A reduction of Herschel's observations was undertaken by Mr. C. S. Peirce, and the results appear in vol. ix. of the Annals of the Observatory of Harvard College. So far as we know, their reduction had not been previously attempted. Instances of variability in the light of nakedeye stars were detected during the progress of the classification, the most notable discovery in this direction being perhaps that of the periodical fluctuations of a Herculis, in about sixty days. Another star in the same constellation he considered had totally disappeared in 1791, though he had seen it distinctly in 1781 and 1782.

Herschel was led to his numerous discoveries of double stars by his expectation of being able to determine the parallaxes of stars from measures made at opposite seasons of the year of the distances of pairs which appeared near together, and in the search for such pairs, his first catalogue of upwards of 200 double stars was formed and presented to the Royal Society in 1782. Long had previously measured stars upon a similar plan without success, but Herschel pointed out that his stars were not well chosen.

For the successful application of the method it is necessary that one of the pair of stars should really be situated at a much greater distance from us than the other, and as the most reasonable test of distance, Herschel assumed their difference of brightness, so that he sought for pairs where the components differed widely in this respect. The view therefore which he adopted at this time with respect to two stars seen in close proximity to each other was that one was in nearly the same line of sight as the other, but might be far more distant, thus constituting together what we now term an optical double star. From this beginning he was led to the discovery of revolving double stars, stars changing their relative position from year to year; and in 1803 he communicated to the Royal Society his memorable paper: "An account of the changes which have happened during the last twenty-five years in the relative situation of double stars, with an investigation of the cause to which they are owing." He was then satisfied that there were in the heavens pairs of stars which were physically connected with each other. The research for stellar parallax was not successful, but in place of it be discovered the exist ence of binary systems. He could not in his day decide

whether the motions of suns round suns was obedient to the laws of gravitation, but five years after his death the French astronomer Savary proved that one of these revolving double stars, discovered by Herschel, έ in Ursa Major, really was subservient to that law, and as every student of astronomy will be aware, the number of physically connected systems where the elements of the orbits have been determined, is now a large one, and is gradually increasing.

Following at present the order in which Prof. Holden refers to the scientific labours of Herschel, we now arrive at his researches on planets and satellites, respecting which the improvements he made in the construction of telescopes enabled him to advance knowledge so greatly. He was not particularly occupied with the inferior planets, but he determined the time of axial rotation of Mars with greater precision than before, and also the position of his axis. The times of the rotation of the satellites of Jupiter were found from observations on their changeable brightness, and Herschel also remarked the as yet imperfectly explained phenomena attending the transits of the satellites across the disk of the planet. Saturn, as Holden remarks, was the object of his constant attention : in addition to the discovery of the interior satellites Enceladus and Mimas, he left upon record an extensive series of observations of the seven attendants upon Saturn at that time known, and determined the time of rotation of the outer satellite Japetus upon its axis, by similar observations to those made upon the satellites of Jupiter. He ascertained the time of axial rotation of Saturn, and was the first who had succeeded in effecting this in a reliable manner. He also remarked the curious square-shouldered appearance which the globe of the planet has been suspected to present, and of which we still occasionally hear, though it was long ago proved by Bessel to be an illusion. It is remarkable that notwithstanding Herschel's frequent scrutiny of the planet, with all his experience of observation and the advantages of optical means surpassing by far those of his contemporaries, he does not appear to have at any time suspected the existence of the interior obscure ring. He proved beyond doubt that Uranus was attended by two satellites, and believed he had observed four others, and for a long time on his authority the planet was credited with six attendants.

In 1795 Herschel communicated to the Royal Society a memoir upon the nature and construction of the sun and fixed stars. As to the former he adopted a modified view of the theory which had been advanced by his friend Wilson of Glasgow; he regarded the sun as consisting of three essentially different parts: a solid and non-luminous nucleus, cool and perhaps capable of habitation, above it the atmosphere proper, and still higher the clouds or bodies which cause the sun's intense brilliancy. In this paper occurs a remark which, as Prof. Holden observes, has often been brought to bear, in consideration of the causes which maintain the solar light and heat. "Perhaps," he says, "the many telescopic comets may restore to the sun what is lost by the emission of light." We know that however credible in his day points in his theory have given way under our greatly advanced knowledge.

One of the discoveries, or perhaps we should rather say

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