the English form of the Latin Euxinus, the classical name of the Black Sea. The original designation of the sea was Azenum or Inhospitable, from the fierceness of the storms with which it was believed to be periodically visited, and also from the ferocity of the nations which dwelt around its shores. By the later Greeks its name was changed into Enicium or Hospitable, as being a word of better omen.

EVAGRIUS, surnamed SCHOLASTICUS and EX-PREFECTUS, was born at Epiphania in Syria, A.D. 356. From his surname he is known to have been an advocate, and it is supposed that he practised at Antioch. He was the legal adviser of Gregory, patriarch of that city; and through this connection he was brought under the notice of the Emperor Tiberius, who honoured him with the rank of quaestorian. His influence and reputation was so considerable that, on the occasion of his second marriage, a public festival was celebrated in his honour, which, however, was interrupted by a terrible earthquake, said to have destroyed 60,000 persons. Evagrius' name has been preserved by his Ecclesiastical History, extending over the period from the third general council (that of Ephesus, A.D. 431) to the year 594. Though not wholly trustworthy, this work is tolerably impartial, and appears to have been compiled from original documents, though it is disfigured by the unquestioning credulity characteristic of the age. The best edition is that contained in Reading's Greek Ecclesiastical Historians, Cambridge, 1720. It is also translated in Bagster's work bearing the same title.

EVANDER, in Greek and Roman Mythology, a son of Mercury and an Arcadian nymph called in the Greek traditions Themis or Nicostrate, and in the Roman Tiburtis, or more commonly Carnute. In consequence of civil broils, in the course of which Evander was worsted, he left his native city of Pallantium in Arcadia, and sailed for Italy, where he settled at the foot of the Palatine Hill, and was hospitably received by king Turnus. The town of Pallantium, which he is said to have built on the spot where he disembarked, was subsequently incorporated with Rome, and gave name to the Palatine Hill, Palatium, &c. Among the other arts which traditions describe him as diffusing among the Italians, was that of writing, which he had himself learned from Hercules. Virgil describes Evander as still alive when Æneas landed in Italy, and as forming an alliance with that chief against the Rutuli.

EVANGELISTS (from εὐ, well, and ἀγγέλος messenger, or messenger of good tidings). This term is applied in the New Testament to a certain class of Christian teachers who were not fixed to any particular spot, but travelled either independently, or under the direction of the Apostles, for the purpose of propagating the gospel. In the Epistle to the Ephesians (iv. 11) the Evangelists are expressly distinguished from the pastors and teachers, who were persons stationed at particular places to confirm and instruct the converts stately and permanently. Such is the representation given by Eusebius (Hist. Eccles., iii. 37). Referring to the state of the church in the time of Trajan, he says, "Many of the disciples of that time, whose souls the Divine word had inspired with an ardent love of philosophy, first fulfilled our Saviour's precept by distributing their substance among the poor. Then travelling abroad they performed the work of evangelists, being ambitious to preach Christ, and deliver the scripture of the Divine Gospels. Having laid the foundations of the faith in foreign nations, they appointed other pastors, to whom they entrusted the cultivation of the parts they had recently occupied, while they proceeded to other countries and nations." The term evangelist is also applied in a more limited sense to the authors of the canonical Gospels.

EVAPORATION is that process by which liquids and solids gradually assume the gaseous form, or by which, in certain circumstances, an invisible vapour or gas is continually detached from the surface of water, and perhaps of every other liquid, as also from the surfaces of many, if not every solid. From this process being generally found to lower the temperature of the evaporating body, an effect which might have been expected from the doctrine of latent heat, it is probable that heat enters largely into the constitution of every vapour, and is therefore supposed to be the principal agent. At a given temperature, a cubic foot or other determinate space incumbent over a liquid, cannot contain above a certain quantity of the same kind of vapour; and when it contains that maximum, it is said to be saturated. If, therefore, after this is the case, any additional vapour continue to be thrown off, it must either fall back immediately into the liquid, or, if slightly cooled, may apparently remain suspended in the visible form of a cloud, which, however, is not properly vapour, but minute drops, formed by the cooling of it, and which successively fall back into the liquid. For evaporation continues to go on under the pressure of air or other gas however dense; but ceases in the presence of any gas, however rare, if already saturated with the same vapour, unless such gas be colder than the evaporating body; in which case, however, the vapour being partly condensed into drops, becomes cloudy, as was just mentioned; and sometimes liquids, while in the act of ebullition, which is rather an extreme case of evaporation, throw up small drops, which may be seen alternately rising and falling in the vapour. Such is a summary of a few of the leading facts, several of which we shall have occasion to touch on more fully, along with other particulars, whilst briefly noticing, as we shall now do, some steps in the history of this inquiry, before proceeding farther.

The spontaneous disappearance of water, and the drying Historical of humid bodies, or the tendency which moisture has to sketch of escape from them and diffuse itself in the atmosphere, and afterwards to descend as rain, snow, dew, &c., must have been familiar to mankind in every age, condition, or climate; but anything like an approach to a rational expla- Evaporation

Evaporation of the facts seems to be of very modern date. Some of the ancients, particularly Aristotle, conjectured that fire was concerned in the process; but such of their notions as have come down to us are so little to the purpose, that they need not now be dwelt upon. Halley supposed that aqueous vapour consisted of small hollow sphe- rules, filled with something so very light, that they readily ascended and floated in the air,—a theory not altogether such as might have been expected from the known sagacity of its author; for, though Descartes seems to have hinted at the same thing long before, it scarcely appears to have had the least shade of truth in it. But so completely was Kratzenstein's imagination filled with this doctrine, that he fancied he could see these vesicles with a microscope, and even discern them to be hollow, notwithstanding their being supposed to form a transparent vapour. If he really saw any thing, it was more probably minute drops of water descending in the air. Nay, almost up to the close of the last century, we find many eminent men, and among these the late able mathematician Mr George Atwood, maintaining and speculating on this vesicular theory, as it was called. Halley, it is true, hinted at another theory, which not a few embraced, and for which some have still a predilection, namely, that air holds moisture united to it by chemical solution or affinity; but the first idea of this seems to be due to Hooke. A different explanation was attempted by Desaguliers, who, after pointing out the defects of former theories, showed that water is capable of being converted into a transparent elastic fluid, which he supposed to be many times lighter than air, and that it could therefore ascend and float in the atmosphere; but he some time afterwards inclined to ascribe the ascent of vapour to an electrical attraction of the air. Desaguliers was no doubt greatly mistaken regarding the specific gravity of steam, which, under the same pressure and temperature, is now known only to fall short of that of air in the ratio of five to eight; but he was perhaps the first who thought of identifying pure steam with the attenuated aqueous vapour diffused in the atmosphere. It would seem that prior to Desaguliers advancing this notion, it was not known that steam is always generated in a transparent state, although minute drops of water may be passing or falling through it; and indeed some are scarcely aware of this at the present day. The fact is, that steam or aqueous vapour preserves its transparency so long as it has neither lost heat nor had its volume enlarged; but so soon as its temperature is lowered, whether from losing heat or from enlargement of volume, it is more or less condensed into minute drops of water, which of course render it opaque. For we cannot on no account admit the very generally received doctrine of M. Clement, that equal weights of steam, if in contact with water, contain equal quantities of heat, whatever be their volumes or temperatures. On the contrary, we cannot help believing that a given weight of steam requires more heat to maintain it in the transparent elastic form, when under a greater volume, than under a less; and in proof of this, we presume it is only necessary to adduce the following fact. If we open a stop-cock in the cover of a boiler when the pressure is only one atmosphere, the steam which issues preserves its transparency till it get to some distance from the orifice; but when the pressure within amounts to two or three atmospheres, the steam, if allowed to issue freely, is opaque from the very orifice. This clearly shows that the same quantity of heat (we do not mean temperature) which had been amply sufficient to maintain the steam in the transparent form under a smaller volume within the boiler, is quite inadequate to do so when the steam is allowed to enlarge its volume under a reduced pressure. A more palpable or satisfactory proof than this, which has been long before the public, is scarcely to be wished; yet we find Dr Lardner subsequently reading a paper to the Royal Society on the heat of steam, and which has for its foundation the untenable theory of Clement. Indeed M. Clement's mode of experimenting was so fallacious, that it would have given him the same results whether his theory had been true or not. For when the stream of steam is very small, and of course passes through the stop-cock with difficulty, as it must have done in his experiments, it has, while in the act of dilating from under a force of two or three to that of one atmosphere, the opportunity of absorbing heat from the metal of the scarcely open stop-cock, then much hotter than 212°, the temperature to which the dilating is supposed to reduce the steam. No wonder then that equal weights of steam, at first so different in density, should, when received in equal quantities of cold water, produce equal rises of temperature; as is pointed out more particularly in the Philosophical Magazine for July 1826, p. 38. It is likewise to be remembered, that though in the other experiment the steam must have been absorbing some little heat from the stop-cock, this did not enable it to preserve the transparent form. We have been the more particular in clearing up this point, because we shall shortly have occasion to refer to it.

From the time of Halley and Desaguliers to about 1770, a variety of essays on evaporation made their appearance, which, however, tended but little towards elucidating the subject, because they were either not founded on experiments at all, or on such as were not sufficiently elementary. Some of these sought to establish the vesicular system, while others advocated that of chemical solution and electrical attraction. At length, in 1783, came forth the well known Essais sur l'Hygrometrie of Mr de Saussure, who, though he did not labour so much to establish new theories as to blend together or combine some of those already mentioned, certainly added considerably to the stock of facts. But he at the same time greatly indulged his fancy in supposing aqueous vapour to be capable of existing in four different forms. When it alone occupied a space, he called it pure elastic vapour; when diffused in a transparent state in the air, he named it dissolved elastic vapour, imagining it to be chemically dissolved by the air; but after the air was quite saturated with this sort, he thought some of it assumed the form of residuval vapour, only differing from that of Halley in being visible. To these he added concrete vapour, which consisted of liquid drops, such as form clouds and fogs; a real form of moisture to be sure, but one which is not properly vapour at all. In these Essais we have an account of a variety of experiments, most of them having the advantage of being executed on a great scale; but, on the other hand, they were often deficient in that elementary simplicity which is so important in a research of this nature, if we would avoid sources of fallacy. By inclosing a known weight of caustic alkali in a very large glass balloon, previously filled with thoroughly damp air, Saussure endeavoured to find what quantity of moisture this air contained, from the increase of weight which it communicated to the alkali; and conversely, by weighing a bit of wet linen, and suspending it in the balloon filled with dry air, he estimated how much moisture had evaporated from the linen to render the air thoroughly damp. These two methods not only gave him nearly the same result, but did so whether he used pure hydrogen or carbonic acid in the balloon, and even when he employed a mixture of these gases. During these experiments he also observed, by means of a gauge, what change of pressure took place within the balloon from the change of humidity.

By operating at different temperatures, he obtained re- results from which different conclusions might be drawn to suit different theories; for instance, that the quantity of vapour which could exist in the balloon varied in geometrical progression for equal intervals of temperature, and nearly as the square root of the air's density; and that air of the ordinary density could contain five times as much vapour as a vacuum did; all of which conclusions are now known to be incorrect. Prior to this, Lambert had, from his experiments, drawn a very different but still more erroneous conclusion, that the quantity of moisture varied as the square of the air's density.

It was natural to think that the great discordance between the results of these celebrated philosophers should have raised doubts whether they might not both have deceived themselves by too complex a mode of operating, and, therefore, that neither of them was likely to be correct. Accordingly we find M. Deluc, in his *Idees sur la Meteorologie*, hinting at an incomparably more simple theory, which he afterwards developed more fully in the *Philosophical Transactions* for 1792, viz., that the quantity of vapour which can exist in a given space depends upon the temperature alone, and is independent of the presence or density of air, or of any other elastic fluid with which the vapour forms no chemical combination, being the same as if nothing but the vapour occupied that space. In this speculation he also maintained, as Desaguliers had done, that pure steam and the attenuated aqueous vapour diffused in the air are the same. Something similar to this theory was advanced by M. Pictet in his *Essai sur le Feu*, and still more so by Dr Dalton in his *Meteorological Essays*; and it is not improbable that each might have hit upon the same theory before knowing what the others had done. By including his hygrometer along with a little water under a receiver, Deluc found that the indications of that instrument were the same whatever was the density of the included air, or however much he exhausted it; and the same thing held true with other gases. Volta, likewise, from a great variety of experiments, was led to acquiesce in the theory of Deluc.

The theory was farther investigated, in a much more elementary way, by Dr Dalton, as detailed in the *Manchester Memoirs*, vol. v.; but preparatory to noticing it, we shall subjoin his manner of expressing himself on the subject in his *Essays*, p. 201, where, from certain experiments and observations, he infers "that the vapour of water, and probably of most other liquids, exists at all temperatures in the atmosphere, and is capable of bearing any known degree of cold without a total condensation, and that the vapour so existing is one and the same thing as steam or vapour of 212° upwards. The idea, therefore, that vapour cannot exist in the open atmosphere at a lower temperature than 212°, unless chemically combined therewith, I consider as erroneous; it has taken its rise from a supposition that air pressing upon vapour condenses the vapour equally with vapour pressing upon vapour; a supposition we have no right to assume, and which, I apprehend, will plainly appear to be contradictory to reason and unwarranted by facts; for when a particle of vapour exists between two particles of air, let their equal and opposite pressures upon it be what they may, they cannot bring it nearer to another particle of vapour, without which no condensation can take place, all other circumstances being the same; and it has never been proved that the vapour in a receiver from which the air has been exhausted is precipitated upon the admission of perfectly dry air. Hence, then, we conclude, till the contrary can be proved, that the condensation of vapour exposed to the common air does not in any manner depend upon the pressure of the air." The method which Dr Dalton took to clear up this question is distinguished by an elegant simplicity. In the first place, he determined by experiment the expansive force of dry air for each degree of temperature between 32° and 212°; and was the first who did so with anything like accuracy. He at the same time found that 1000 cubic inches of air at 32° expanded to 1376 on being heated to 212°, which comes surprisingly near 1375, the result published by M. Gay Lussac shortly after. But through some inadvertency Dr Lardner (on Heat, p. 57) makes Dr Dalton's result 1325, and then gravely adds, that "the latter (Gay Lussac's) determination has been proved by subsequent experiments to be the more correct." Secondly, Dr Dalton ascertained the force of pure steam in contact with water for each degree throughout the same range; and, thirdly, he found at what rate dry air expanded, when put in contact with water, and then heated through the various degrees of that range. The result was, that at any particular temperature, the expansive force of dry air in the first case, added to the force of vapour in the second, was exactly equal to their joint expansive force in the third. From this it is obvious that there is either no chemical combination between the air and vapour, or that such combination, if it exist, is quite inert, or goes for nothing so far as this research is concerned. Dr Dalton found, that when other gases were substituted for air, the vapour gave the same results; and similar results were obtained when other vapours were treated as steam. M. Desormes, likewise, by Researches operating in a manner very different from that of Dr Dal- of M. Desoton, found the quantity of vapour to be independent of the presence of air or other gases. The question was also examined experimentally by M. Gay Lussac, with his well-known accuracy and ability, and his results precisely agreed with those of Dr Dalton. Still more recently Professor Danielli has made a great variety of interesting experiments on mixtures of gases and vapours, in a manner similar to that employed by Deluc, but with the help of an incomparably better hygrometer; and his researches, too, corroborate the theory completely.

Several objections have been made to this theory; but all of them with which we are acquainted are so nugatory and irrelevant that we do not think they require any refutation. There is, however, a point which the foes as well as the friends of the theory have taken for granted, and which, though extremely probable, it would, for any thing we can see, be very difficult to prove in a direct and unexceptionable manner; viz., that the expenditure of heat in forming a given weight of vapour is the same, whether the process take place in air or other gas, or in a vacuum. Since in most combinations heat is given out, it is a wonder that those who contend for the solution of vapours in gases have not founded some objection on this; for we presume it is the only point on which a doubt could be palmed respecting the theory. It is generally taken for granted too, that the expenditure of heat in forming a given weight of vapour is the same at every temperature; but this assumption we cannot help regarding as very erroneous, because to us it appears quite clear that the expense of heat is greater when the vapour is rarer; and this we maintain for the following reason. The density of steam at 212°, for instance, is about 109 times greater than at 32°, and Fahrenheit; and we have already seen that steam loses in the expenditure of a considerable degree the elastic form by being dilated by heat being two or three times its bulk; how much more then if dilated 109 times? Hence steam rarefied to such a degree would need a large addition of heat to enable it to maintain the gaseous form; in other words, much more heat must be expended or become latent in forming a given weight of vapour at 32° than at 212°. If steam, when kept separate from water, have its temperature raised by compression at the same rate as air has, it might be shown that the expense of heat in forming vapour at 32° would be to that at 212° as thirteen to eight nearly, that is, in the Evaporation.

Vapours and gases agree in so many of their properties, that there seems no doubt of their being but one and the same form of matter. Thus, so far as has been examined, every vapour, when kept separate from any sensibly evaporating liquid, expands by heat at the same rate as air and other gases do; and, like gases too, it observes the law of Boyle, by having the force at a given temperature proportional to the density. But since the density of a vapour in contact with its generating liquid increases with the temperature, its force, when so situated, increases much more rapidly than that of air or a mere gas does. However, the precise law which connects the temperature with the density or force seems to be as yet unknown. Dr Dalton having, as already mentioned, ascertained by experiment the force of aqueous vapour between the temperatures of $32^\circ$ and $212^\circ$, deduced from the results what he considered to be the relation between the force and temperature, and for some time it was supposed that by means of it the force could be had for temperatures beyond both limits of that range. Accordingly on this principle he constructed a table which extended from — $40^\circ$ F. up to $325^\circ$; and indeed he was pretty fortunate in the extension below $32^\circ$, because the half of it has since been so nearly confirmed by the very accurate experiments of M. Gay Lussac, which were carried down almost to — $20^\circ$ cent. or — $4^\circ$ F., but above $212^\circ$ the supposed law was soon found to give the force too small, and the more so as the temperature is higher. Yet Dr Lardner, in his separate treatise on heat, gives this part of the table expressly as the result of Dalton's "accurate experiments," and not as it really was, a mere extension by means of a formula; nor does he warn us of its erring almost two atmospheres at the upper extremity. It is likewise curious that Dr Lardner, while he notices performances of far less merit, is totally silent respecting the labours of the Committee of the Royal Academy of Sciences at Paris in 1829; though they executed by far the most extensive and accurate experiments that ever were made on steam at high temperatures, as will be found detailed in the Annales de Chimie for January 1830. All the English abstracts from this which we have seen are very incorrect. Dr Dalton has more recently published another table of the force of vapour adapted to some of his theoretical views; but from its differing considerably from the results of others, especially those of Gay Lussac, we do not consider it so correct for low temperatures as his first one, part of which is given farther on in this article.

The method employed by M. Gay Lussac to determine experimentally the force of vapour at low temperatures is particularly commendable, and yet its merits seem to have been very much overlooked, even by those who were engaged in similar researches. It may therefore be useful to give a brief account of it here. Other philosophers had either not carried their experiments below $32^\circ$ at all, or had mismanaged the matter by allowing water to freeze in the tube in such a manner as to obstruct the free motion of the mercury, and likewise to render its altitude ill-defined and difficult to be seen. These inconveniences were dexterously avoided by Gay Lussac, who still employed a barometer tube, but one so much longer than ordinary that a considerable part of it next the sealed end was above the mercury, and a portion of this, being bent to about an angle of $60^\circ$, was immersed in a cold mixture along with a thermometer. The consequence of this arrangement was, that neither the mercury nor the small portion of water on its top necessarily required to be cooled down at all; because, however moderate their temperature might be, the force of every portion of the included vapour being in equilibrium with the force of that which touched the coldest part of the tube, was just the same as if the whole vapour had been at the temperature of the freezing mixture. A farther advantage was, that after the apparatus had been allowed to remain for a short time in the state now described, the water entirely disappeared from the top of the mercury, having been transferred by evaporation or distillation to the sealed end of the tube, where it was quickly frozen. By this means the mercury became almost as free from moisture as if none had been in the tube. It is, besides, evident that this method could be carried down, not only to and below the freezing point of mercury, but to any temperature, however low, to which the extremity of the tube could be cooled; and that it is applicable to every sort of vapour which does not act upon mercury. In fine, Gay Lussac having placed a barometer tube filled with dry mercury beside and in the same cistern with the one which contained both mercury and moisture; read off the difference in the heights of their mercurial columns with great precision, by means of a microscope which could be shifted up and down a graduated pillar, and the difference was obviously the force of the vapour. Although mercury evaporates at all temperatures, as appears from a bit of gold-leaf becoming white if long suspended over it in a phial, and from the noxious effects of breathing air which has been for some time in contact with a large surface of mercury, yet the force of its vapour is so very small compared with that of steam, that it could not sensibly affect these experiments. Indeed it seems to be a general law, that the forces of vapours from liquids which have high boiling points, are quite inappreciable at low temperatures.

The most important problem connected with the evapo-

Resear-

ration of water is to determine the rate at which, under cer-

tain circumstances, it escapes from a given surface at a par-

ticular temperature. Many cases of this problem are still

very imperfectly solved. The experiments of Dr Halley, de-

tailed in No. 189 of the Philosophical Transactions, seem to

be among the earliest which were employed for this purpose.

He found that water salted to the state of sea water, and

exposed to a heat equal to that of a summer's day, did, from

a circular surface of eight inches diameter, evaporate at

the rate of six ounces in twenty-four hours. Hence he

concludes, that a square degree of sixty-nine miles will eva-

porate 33,000,000 tons in a day; and supposing the Me-

diterranean to contain 160 square degrees, it would evapo-

rate 5,280,000,000 tons daily. This quantity he considers

sufficient to supply all the rains, springs, dews, rivers, &c.

It would however be of little use to rehearse the whole of

this speculation, because the data, as we shall afterwards

see, were too loose, and the experiment was on too small

a scale, for such a comparison. Dr Lardner, in touch-

Water car-

ing on this subject in his treatise on heat, says, that in re-

died in by

the Straits of Gibraltar, instead of an outward current, the cur-

rent at

there is a rapid and never-ceasing inward flow of water,

Gibraltar

and that he is therefore compelled to conclude that the

evaporation from the surface of this sea carries off the enor-

mous quantity of water supplied from this and other sources, by evapo-

Such doctrine from so respectable a quarter rather sur-

prises us; since it is quite well known that, besides the

inward current, which is principally in the middle of the

surface, there are generally outward currents, likewise at

the surface, next the coasts, particularly the south one, and

most probably also in the immense deep beneath. It has been

alleged, but erroneously, that the water sometimes flows out-

wards even in mid-channel on the surface. Had there

been no outward current, the Mediterranean must long

ago have become as salt as the brine of the Dead Sea; or

rather perhaps have become a rock of salt, as Dr Thomas

Young remarked; for, as we shall afterwards see, no common

salt or other muriate rises from the sea by evaporation. order that the same degree of saltness may continue, the outward currents must just bear away as much salt as the inward current and other sources supply, with the very slight exception of what the wind carries off in the form of spray, water spouts, &c. The waters of the Mediterranean being, as is well known, specifically heavier, especially at a great depth, than those of the Atlantic, will naturally incline to buoy them up, and flow out beneath them in the infathomable depth of the Straits.

A series of experiments on the evaporation of water at natural temperatures was continued for four years, beginning with 1772, by Dr Dobson, at Liverpool, as detailed in the Philosophical Transactions, vol. lxvii. He took a cylindrical vessel twelve inches in diameter, and having nearly filled it with water, exposed it beside his rain-gauge of the same aperture; and by adding or withdrawing water, as occasion required, he kept the surface at nearly the same height. By comparing the total quantities thus added or taken away with the proceeds of the rain-gauge, the amount of evaporation was ascertained. The mean monthly evaporation for the four years was, in January, 1-5 inches; February, 1-77; March, 2-64; April, 3-3; May, 4-34; June, 4-41; July, 5-11; August, 5-01; September, 3-18; October, 2-51; November, 1-51; December, 1-49. In all, 36-78 inches. The mean rain for the same time was 37-48. For a great deal more in this way, and on the evaporation of ice and snow, see Howard's excellent treatise on The Climate of London. That ice and snow evaporate, appears from their losing weight, Evaporation even disappearing altogether, if long enough exposed to a brisk and dry wind during frost. But sometimes snow is rendered so much colder by radiation than the incumbent still air, that it condenses the vapour of that air into hoarfrost, and by that means augments its own weight or bulk.

But the experiments of Dr Dalton and Mr Hoyle, though rather of local application, were no doubt far more accurate for evaporation from the soil. Having got a cylindrical vessel three feet deep and ten inches in diameter, two pipes were joined to it, and turned downwards for the surplus rain-water to run off into bottles; the one pipe being near the bottom, the other an inch from the top. The vessel was filled up for a few inches with gravel and sand, and the remainder with good fresh soil. It was then put into a hole in the ground, and the space around filled up with earth, except on one side, for the convenience of afterwards joining bottles to the pipes, and registering their contents. The earth in the vessel was now saturated with moisture, by pouring in water till some of it escaped from the pipes; and, lastly, the bottles were put to. During the first year the soil was bare at top; but for the next two years it was covered with grass, like any green field. A regular register was kept of the rain-water which ran off through the upper pipe, and also of what sunk down through the earth to the lower pipe. A rain-gauge of the same diameter was kept close by, to register the quantity of rain for any corresponding time.

| Water through the two Pipes | Mean Rains | Mean Evaporation from Ground | Mean Evaporation from Water | |-----------------------------|------------|----------------------------|---------------------------| | 1796 | 1797 | 1798 | Mean | Mean | Mean | | Inch. | Inch. | Inch. | Inch. | Inch. | Inch. | | January | 1-897 | 0-680 | 1-774 | 1-450 | 2-458 | 1-008 | 1-5 | | February | 1-778 | 0-918 | 1-122 | 1-273 | 1-801 | 0-528 | 2- | | March | 0-431 | 0-070 | 0-335 | 0-279 | 0-902 | 0-623 | 3-5 | | April | 0-320 | 0-295 | 0-180 | 0-232 | 1-717 | 1-485 | 4-5 | | May | 2-027 | 2-443 | 0-010 | 1-493 | 4-177 | 2-684 | 4-959 | | June | 0-171 | 0-726 | ... | 0-299 | 2-483 | 2-184 | 6-487 | | July | 0-153 | 0-025 | ... | 0-059 | 4-154 | 4-095 | 5-628 | | August | ... | 0-504 | ... | 0-168 | 3-554 | 3-386 | 6-058 | | September | ... | 0-976 | ... | 0-325 | 3-279 | 2-954 | 3-898 | | October | ... | 0-680 | ... | 0-227 | 2-899 | 2-672 | 2-351 | | November | ... | 1-044 | 1-594 | 0-879 | 2-934 | 2-055 | 2-042 | | December | ... | 0-900 | 3-077 | 1-878 | 1-718 | 3-202 | 1-484 | 1-5 |

From these experiments it appears, 1st, That the mean annual quantity of water evaporated in the above circumstances is twenty-five inches of rain, to which if we add five for dew, will give thirty inches of water raised annually; 2ndly, That the evaporation increases nearly, though not exactly, in the same ratio as the rain; thus 1797 gave most rain, and the greatest evaporation, &c.; 3rdly, That there is little difference between the evaporation from bare earth of sufficient depth, and that from ground covered with grass. It is however to be observed, that the numbers in the last or right hand column belong to the years 1799, 1800, and 1801; and that on account of accidents with the frost, these numbers are partly conjectural for January, February, March, April, and December. The mean annual evaporation during the same three years from ground covered with grass, exclusive of dew, was 23-5 inches, which falls a little short of that for the other three, which was twenty-five.

But there is reason to suspect that a less depth of soil in the vessel would have allowed more water to escape into the bottles, and vice versa. It is therefore in some degree a matter of conjecture that this apparatus indicated the true evaporation from the adjacent fields. Labrie having filled a vessel eight feet deep with soil, and sunk it into the earth, left it there for fifteen years. It had an opening at the bottom for the escape of the water, but never a drop came through. The quantity of rain, to be sure, being less at Paris than at Manchester, will so far account for this.

In such an article as this it might be expected that, in conformity with custom, we should state the mean evaporation for all England, and a number of other principal countries. This however we are unable to do, because we are persuaded that to obtain even an approximate estimate would require experiments, such as those of Dr Dalton from the soil, to be made at least within every square mile of surface. The usual estimates being only derived from Evaporation.

A vessel with water, as will be noticed more particularly afterwards, afford no measure of evaporation from the soil.

The following relation between the temperature and the rate of evaporation from water, was discovered by Dr Dalton. Having, as above mentioned, determined experimentally the force through a considerable range, he was naturally led to examine whether the quantity of water evaporated in a given time bore any proportion to the force of vapour of the same temperature, and was agreeably surprised to find that they corresponded in every part of the range examined. Thus the forces of vapour at $21^\circ$, $180^\circ$, $164^\circ$, $152^\circ$, $144^\circ$, and $138^\circ$, are equal to $30$, $15$, $10$, $7\frac{5}{6}$, $6$, and $5$ inches of mercury respectively; and the grains of water evaporated per minute are in the same ratio. This Dr Dalton considers as quite in conformity with the laws of mechanics; for the atmosphere seems by its inertia to obstruct the diffusion of vapour, which would otherwise be almost instantaneous, as in vacuo; but this obstruction, which is greater as the air is more dense, is overcome in proportion to the force of the vapour. Did the obstruction arise from the weight of the atmosphere, it would prevent any vapour from rising at temperatures lower than $21^\circ$; but according to Dr Dalton it is caused by the inertia of the particles of air, and is similar to that which water meets with in descending among pebbles.

The theory of evaporation was thus far settled so much the more easily, because the force of vapour already in the open air being very small compared with what is produced from water at high temperatures, did not sensibly affect the result; but Dr Dalton found, that if the theory was to be verified by experiments for low temperatures, regard must be had to the force of vapour already in the atmosphere. For instance, if water of $59^\circ$ were the subject, the force of vapour at that temperature being a sixtieth of the force at $21^\circ$, one might expect the quantity of evaporation to be a sixtieth also; but if it should happen, as it sometimes does in summer, that an aqueous atmosphere to that amount does already exist, the evaporation, in place of a sixtieth, would be nothing at all. On the other hand, if the previously existing vapour were the 120th, corresponding to $38^\circ$ F., then the effective evaporating force would be the 120th of that from boiling water. In short, Dr Dalton found that the evaporating force must in every case be equal to that at the temperature of the water diminished by that already existing in the air. To find the force of the aqueous atmosphere, Dr Dalton revived the method which had been employed by Leroy long before. He used in summer to take a tall glass jar, and fill it with cold spring water, fresh from the well. If dew was immediately formed on the previously dry outside, he poured the water out, let it stand a little to rise in temperature, wiped dry the outside of the jar, and then poured the water in again. The like process is to be repeated till dew cease to be formed, and at that instant the temperature of the water is to be carefully noted, for the purpose of obtaining, from a table like that which shortly follows, the corresponding force of vapour. Such temperature is called the dew point, or the point of deposition; because the air, if cooled to it, would be in a state of saturation with moisture, and of course ready to deposit dew, especially on anything in the least colder than itself. This operation should be performed in the open air, or at an open window, because the air within is generally more humid than without. Spring water in this country being generally within a degree or two of $50^\circ$, will mostly answer the purpose during the three hottest months; in other seasons an artificial cold mixture may be used. But Leslie's or Daniell's hygrometer would be still more convenient at all seasons.

To observe the evaporation at atmospheric temperatures, Dr Dalton had two light tin vessels; the one six inches diameter and half an inch deep, the other eight inches diameter and three fourths of an inch deep, and both made to be suspended from a balance. Water being put in one of these and weighed, it was placed in an open window or other exposed situation for ten or fifteen minutes, and again weighed to ascertain the loss from evaporation. The temperature of the water was at same time observed, the force of the aqueous atmosphere ascertained as above, and the velocity of the current of air noticed; for with the same evaporating force, a strong wind, by quickly changing the air in contact with the water, will double the effect produced in still air. From a great variety of experiments made during both winter and summer, and when the evaporating force was strong and weak, even in the case of ice, the results were found perfectly conformable with the theory. The same quantity is evaporated with the same evaporating force thus determined as near as can be judged, whatever be the temperature of the air. Thus, if the dew point be $40^\circ$ while the air is at $60^\circ$, the evaporation is the same as if the dew point were at $60^\circ$ and the air at $72^\circ$; for $-524 - 263$, which is the difference of the forces of vapour at $60^\circ$ and $40^\circ$, is nearly equal to $-770 - 524$, the difference of the forces at $72^\circ$ and $60^\circ$; but two such differences could be had exactly equal by using fractions of degrees of temperature, and interpolating between the other numbers.

The following table exhibits the ratios and quantity of water evaporated at different temperatures, derived from the preceding theory, and confirmed by experiments. The first column is the temperature; the second the force of vapour; the rest give the number of grains evaporated from a surface six inches in diameter, supposing the air to be previously dry. The third column is calculated on the supposition that at the temperature of $21^\circ$ the evaporation per minute from the said surface is 120 grains; the fourth, that it is 154 grains; the fifth, 189, according to the strength of the wind; for if the air in contact with the water be continually changed, so that the recently moistened portion may be speedily removed and drier air substituted for it, the process will be proportionably expedited. These columns present the extremes and mean of evaporation likely to be noticed when the process goes on in air of the ordinary density. The effects of different densities will be considered afterwards.

| Temperature | Force, Inch. | Evaporating Force in Grains | |------------|-------------|---------------------------| | 20 | -129 | -52 | | 21 | -134 | -54 | | 22 | -139 | -56 | | 23 | -144 | -58 | | 24 | -150 | -60 | | 25 | -156 | -62 | | 26 | -162 | -65 | | 27 | -168 | -67 | | 28 | -174 | -70 | | 29 | -180 | -72 | | 30 | -186 | -74 | | 31 | -193 | -77 | | 32 | -200 | -80 | | 33 | -207 | -83 | | 34 | -214 | -86 | | 35 | -221 | -90 | | 36 | -229 | -92 | | 37 | -237 | -95 | | 38 | -245 | -98 | | 39 | -254 | -102 |

Table of the Force of Evaporation. ### Table of the Force of Evaporation continued.

| Temperature | Force, Inches | Evaporating Force in Grains | |-------------|--------------|-----------------------------| | 40 | .263 | 1·05 | | 41 | .273 | 1·09 | | 42 | .283 | 1·13 | | 43 | .294 | 1·18 | | 44 | .305 | 1·22 | | 45 | .316 | 1·26 | | 46 | .327 | 1·31 | | 47 | .339 | 1·36 | | 48 | .351 | 1·40 | | 49 | .363 | 1·45 | | 50 | .375 | 1·50 | | 51 | .388 | 1·55 | | 52 | .401 | 1·60 | | 53 | .415 | 1·66 | | 54 | .429 | 1·71 | | 55 | .443 | 1·77 | | 56 | .458 | 1·83 | | 57 | .474 | 1·90 | | 58 | .490 | 1·96 | | 59 | .507 | 2·03 | | 60 | .524 | 2·10 | | 61 | .542 | 2·17 | | 62 | .560 | 2·24 | | 63 | .578 | 2·31 | | 64 | .597 | 2·39 | | 65 | .616 | 2·46 | | 66 | .635 | 2·54 | | 67 | .655 | 2·62 | | 68 | .676 | 2·70 | | 69 | .698 | 2·79 | | 70 | .721 | 2·88 | | 71 | .745 | 2·98 | | 72 | .770 | 3·08 | | 73 | .796 | 3·18 | | 74 | .823 | 3·29 | | 75 | .851 | 3·40 | | 76 | .880 | 3·52 | | 77 | .910 | 3·65 | | 78 | .940 | 3·76 | | 79 | .971 | 3·88 | | 80 | 1·00 | 4·00 | | 81 | 1·04 | 4·16 | | 82 | 1·07 | 4·28 | | 83 | 1·10 | 4·40 | | 84 | 1·14 | 4·56 | | 85 | 1·17 | 4·68 |

As an example of the use of the table, let the dew-point be 52°, the temperature of the air 65°, with a moderate breeze, to find the evaporation per minute from a vessel six inches in diameter. The number in the fourth column opposite 52° in the first, is 2·06, and that opposite 65° is 3·16; the difference, 1·1 grain, is the evaporation required. Again, if the evaporation per minute, with a brisk wind, be 1·7 grain, while the air is at 62°, required the weight of the aqueous atmosphere, and the dew-point. In the fifth column the number opposite 62° is 3·52, being the whole evaporating force at that temperature in perfectly dry air, from which 1·7 being deducted, leaves 1·82, which, in the fifth column, is opposite to 294 inch of mercury in the second, the weight of the column of vapour, and to 43° the temperature or dew-point. That is by using the nearest numbers in the table. Greater exactness may be had by interpolating between them. In this case, for instance, the weight should more correctly be 290, and the dew-point 42°-6. Such estimates, however, are liable to uncertainty, where any doubt remains respecting the velocity of the wind.

Dr Dalton found that the same theory held with regard to the evaporation of other liquids, and was even more easily verified by experiment in their case than in that of water, on account of the air previously containing little or none of their vapours. In short, the evaporation in their case is similar to that of water in perfectly dry air.

Since vapours, so long as they maintain the gaseous form, expand and contract by change of temperature precisely at the same rate as air does in like circumstances, and since mixtures of air and vapour do the same, it follows, that if at any temperature above the dew-point the pressure of the unconfined air have to that of the vapour in it a certain ratio, it will have the same ratio to it at any other temperature not lower than the dew-point. Hence, because the entire pressure is constant, the force of vapour at the actual temperature of the air is exactly equal its force at the dew-point or temperature at which the air under the original pressure becomes saturated with moisture, and at which all the moisture in it just barely maintains the gaseous form.

Dr Anderson, in giving a table of the weight and force of aqueous vapour in vacuo (Edin. Enegy. xi. 578), says, it is adapted to a pressure of thirty inches, and that when the barometer differs from thirty, the numbers in the table (none of which denote atmospheres, but grains and inches) must be altered in the same ratio as the pressure. It is difficult to conceive how he could fall into such a palpable mistake. Vapour in vacuo being protected from atmospheric pressure, has obviously nothing to do with its changes or amount; and we have already seen that the maximum force and density of vapour in air, as well as in vacuo, depend solely on the temperature. Yet Dr Anderson (ibid. p. 581) makes the maximum weight of vapour which can exist in a cubic inch of air at a given temperature to be proportional to the barometric pressure, which is remarkable, considering his professed adherence to Dalton's theory. It is farther curious that the doctor, not perceiving that the actual force of vapour in the open air must be exactly equal to its force at the dew-point, gives (on same page) a formula for reducing the one force to the other; and he even takes it for granted that Dr Dalton is in the same error, though the very reverse appears from all his writings, and especially those already quoted.

The rate of evaporation is very different in air of different densities, being greater when the density is less, and of the density versa. Some experiments on this subject are given by Professor Daniell, in the second and much improved edition of his valuable Meteorological Essays, published in 1827, page 493, from which we make the following brief abstract:—Upon the plate of an air pump was placed a Mr. Daflat dish 7·5 inches diameter, containing sulphuric acid, niell's ex- and covered by a receiver which but just passed over it, so that the base of the included air rested everywhere on the acid. In the middle of the dish was a stand supporting a vessel 2·7 inches diameter, and 1·3 deep, which was filled with water to the depth of an inch, and had a delicate thermometer resting on its bottom. The water, having been previously freed from air, was weighed with a very sensible balance, and then exposed to the action of the sulphuric acid. Its temperature was 45°, and the barometer at 30·4 inches. At the end of half an hour it was again weighed, and found to have lost 1·24 grain by evaporation. Having been replaced, and the air rarefied till the gauge stood at 15·2 inches, it was found to have lost in half an Evaporation hour 272 grains, and to have had its temperature reduced to 45°. By repeating the process, continually diminishing the pressure one half, the successive losses from evaporation in intervals of half an hour each, were as follow:

| Pressure | Temperature | Loss | |----------|-------------|------| | 30-4 | 45° | 1-24 | | 15-2 | 45° | 2-87 | | 7-6 | 45° | 5-49 | | 3-8 | 45° | 8-80 | | 1-9 | 45° | 14-80| | -9-5 | 45° | 24-16| | -47 | 45° | 39-40|

When the exhaustion was pushed to the utmost, which was .07 inch, the evaporation in the half hour was 87-22 grams. During this last experiment the water was frozen in about 8 minutes, while the thermometer under the ice was at 37°. There must, however, be some inadvertency respecting the loss from evaporation in the second experiment; because in the table it is 2-87, and in the account before it only 2-72, which last, we presume, is the more correct of the two.

Before inferring from these experiments the rate of evaporation under different pressures, Mr Daniell applied to the results a correction for the variation of temperature. Taking the evaporation as proportional to the elasticity of the vapour, he estimated the latter from the mean of the temperatures at the beginning and end of each experiment, and calculated the amount for a fixed temperature. This might have been supposed to give a near approximation, were it not evident from the last experiment, that, owing to the bulb of the thermometer not being close at the evaporating surface, it indicated often too high a temperature; but the following table presents the results computed on that principle for the temperature of 45°; and here again we suspect the second number 2-97, being computed from 2-87, is too great.

| Pressure | Grains | |----------|--------| | 30-4 | 1-24 | | 15-2 | 2-97 | | 7-6 | 5-68 | | 3-8 | 9-12 | | 1-9 | 15-92 | | -9-5 | 29-93 | | -47 | 50-74 | | -07 | 112-32 |

Notwithstanding the slight irregularity of the series, Mr Daniell thinks we can run no risk in concluding that the amount of evaporation is, ceteris paribus, in exact inverse proportion to the elasticity of the incumbent air. But perhaps it would be more correct to say, that, ceteris paribus, the rate of evaporation is inversely as the density of the air; for that is Dr Dalton's view of the matter, and is equally conformable to these experiments. It may however be observed, that the rate of evaporation in the first case, which is in air of the ordinary density, is much smaller than that given by Dr Dalton; but the process going on in so small a volume of still and confined air, seems a sufficient reason for this.

It was hinted above, that evaporation tends to lower the temperature of an evaporating surface, by abstracting heat from it for the formation of vapour. For, from the well-known fact, that in the formation of aqueous vapour as much heat is absorbed as would raise the temperature of 1000 times its weight of water one degree, it follows, that were it not for the heat derived from surrounding bodies, the vaporization of the 1000th part of a mass of water would lower the temperature of the whole one degree; so that by the time the 100th part had evaporated, the temperature of the whole would have fallen ten degrees. But evaporating surrounding bodies, particularly the air, by participating in the cooling effects, supply heat in such a manner to the water, that a limit is soon set to the fall of temperature. Although this cooling influence has been long known in a general way, it is remarkable how few experiments have been made, or, so far as we know, published, to show the extent of cold produced in different circumstances; and still more remarkable, that those few results of different experimenters should differ so widely, as we shall presently see they do. Dr Anderson, in the article Hygrometry, in the Edinburgh Encyclopaedia, gives the following as the results of his experiments on the cold produced by the evaporation of water in air of different densities. For this purpose he placed Leslie's hygrometer, along with a cup of sulphuric acid, under a receiver of the air pump.

| Pressure | Temperature | Loss | |----------|-------------|------| | 29-6 | 48°-5 | 43°-64 | | 23-6 | 48°-5 | 42°-38 | | 17-6 | 48°-5 | 40°-58 | | 11-6 | 48°-5 | 37°-34 | | 5-6 | 48°-5 | 32°-12 |

The first column is the pressure in inches, the second the Fahrenheit temperature of the dry bulb, the third that of the moist, the fourth their difference or the depression, and the fifth the same depression in degrees of Leslie's hygrometer. The third and fourth columns, though not in the original, are obviously obtained from the others, and inserted in degrees of Fahrenheit, for the sake of comparison with those which follow.

In an article on hygrometers and evaporation, in the Edinburgh Philosophical Journal for October 1826, Mr Meikle gives the two following series of similar experiments, which were not made with Leslie's hygrometer, but with what was reckoned preferable for the purpose, two common thermometer tubes fitted upon one broad and doubly graduated scale; the one bulb being dry and the other covered with wet linen. The columns respectively denote the same things as the first four in Dr Anderson's.

| Pressure | Temperature | Loss | |----------|-------------|------| | 29-7 | 48°-2 | 36°-6 | | 19-4 | 47°-3 | 33°-2 | | 17-2 | 47°-2 | 32°-5 | | 13-3 | 47°-0 | 31°-2 | | 8-8 | 46°-4 | 27°-2 | | 29-9 | 60°-6 | 45°-5 | | 20-0 | 59°-5 | 41°-0 | | 10-0 | 58°-9 | 34°-1 | | 5-6 | 58°-5 | 28°-0 |

All sealed thermometers stand too low when the pressure of the atmosphere is removed from their bulbs. The two just mentioned were found to be each 1°-5 too low in an exhausted receiver. Hence most of the numbers in the second and third columns still require to be more or less corrected for this, according to the degree of exhaustion; but since both thermometers were equally affected, the depressions have nothing to do with it. However, the included air seems to have been really a little cooled from the influence of the cold wet bulb.

We have always been puzzled to account for the extreme smallness of Dr Anderson's depressions in the fourth column. Perhaps he had used very weak sulphuric acid, or too small a surface of it; or he might not be aware that the full effect in a single case is seldom attained in less than half an hour. The pressure and temperature in his first case are nearly the same as in Mr Meikle's; and yet the depression 4°-86 is not half of 11°-6. From many trials we know that the weather is by no means very doughty, if a wet thermometer do not fall more than 4°-86, when only exposed in the open air at 48°-5, without any sulphu- Evaporation.

To increase the cold in a wet thermometer, Dr Lardner recommends exposing it to the sun. But whoever takes the trouble of properly trying this, will find that the sun has quite the contrary effect; and therefore the doctor is just in the same delusion, only on a greater scale, when he directs his readers to wrap wine bottles in wet cloth, and expose them to the sun as a source of greater cold! The sun, like the fire, aids evaporation, by supplying heat, which will more or less counteract the cooling effect, and may even raise the temperature; but common sense revolts at the very idea of the heating rays of the sun being a source of cold.

In 1827, Professor Daniell published, in the second edition of his Essays, p. 499, a series of experiments on the cooling effects of evaporation, and which, like Mr Meikle's, were made by means of two common thermometers, the one dry and the other moist; but he seems only to have read off to the nearest half degree; and his depressions, though not so deficient as those of Dr Anderson, still lean considerably to the same side. The following are his results, arranged as the preceding:

| Temperature | Evaporation | |-------------|------------| | 30°-2 | 50° | | 15°-1 | 49° | | 7°-5 | 49 | | 3°-7 | 49-5 | | 1°-8 | 49-5 | | .9 | 49 | | .4 | 49 |

From repeated experiments we have found that at the temperature of 50°, and under a pressure of about thirty inches, a wet thermometer, when inclosed in a receiver along with a sufficiently large surface of strong sulphuric acid, should fall 12°-1 or 12°-2, in place of 9°, as Mr Daniell has it. The rest of his depressions are still more deficient; but when we attend to the disposition of his apparatus, our surprise rather is that the depressions should be so great as they are. What we particularly object to is his not only inclosing a vessel with water under the receiver, but interposing it directly between the wet bulb and the sulphuric acid. This he did for the purpose of occasionally dipping that bulb in the water; a precaution which was not only unnecessary, but which, by rendering the air moist and obstructing the drying of the bulb, must obviously have rendered the whole of his depressions much smaller than they should have been in perfectly dry air. When Mr Meikle made his experiments, and they were published before those of Mr Daniell, he satisfied himself that if the thermometer was properly covered and moistened at first, no renewal of moisture was necessary. This he ascertained by repeating, in a retrograde order, the different cases when he had just completed a series of these experiments; for on finishing with the case in which the air was most rarefied, he readmitted as much air as just brought back the gauge to the next case, which being repeated, he readmitted more air for the next, and so on, till he had got back over the whole series. In every case, the wet thermometer was found to be as much depressed in the backward process as in the forward, a clear proof that there was no lack of moisture. Neither Dr Anderson nor Professor Daniell say whether they made any allowance for the effects of pressure on the bulbs of their thermometers.

Oil of turpentine is well known to evaporate very quickly, but we have as yet failed to detect any cold that it produces, though we do not therefore suppose it forms any exception to the general law. Some liquids, as alcohol, ether, sulphuret of carbon, &c. both evaporate more rapidly than water does, and produce a greater cold; but the expenditure of heat is greater in vaporizing a given weight of water than of any other liquid yet examined; a fact from which it had often been concluded that alcohol could be vaporized with so much less fuel than water, that its vapour would be an economical substitute for steam as a first mover; nay, this had become a standard doctrine in almost every scientific compilation. It however involved a fatal oversight, as was first pointed out by Mr Meikle in the Philosophical Magazine for July 1826, p. 41, and afterwards by Mr Ainger in Brande's Journal of Science for March 1830; for it is not with equal weights, but with equal volumes of these vapours, that the comparison falls to be made; and when this is done, the greater rarity of steam puts it on at least an equal footing with alcoholic vapour, so far as regards the economy of heat. In other respects, steam is decidedly preferable; for, independently of the enormous expense of alcohol, the density of its vapour, being about 2½ times that of steam, would prevent it from moving with the same facility through the pipes, valves, &c.

Perhaps it may not be altogether foreign to our subject Mode of mention, that Mr Hutton froze alcohol by condensing freezing air on it in a strong vessel, which being very much cooled by freezing mixtures, was next suddenly opened, when the dilatation of the air, and the consequently rapid evaporation and re-expansion of the alcohol, absorbed so much heat as induced a cold sufficient to freeze it.

The bad effects of damp clothes, beds, &c. are usually ascribed to the cold attending the evaporation of the damp; clothes, but since considerable injury often follows where scarcely any cold is felt, we suspect the chief cause lies rather in the perspiration suppressing the natural evaporation from the skin. The heavy smell which accompanies most dogs, and the fetid grease upon their hair, show that they perspire in some other shape besides what some suppose the only one from their tongues.

Various instruments have been employed to measure the rate at which moisture escapes into the atmosphere. We have already alluded to the method of exposing water in a vessel, and noting the loss. The vessel is generally circular, with a roof a little above it to keep off the rain, &c.; and, for greater accuracy, the contents may either be weighed from time to time, or measured in a graduated tube. When the vessel is brim full, the wind is apt to blow some of the water over; and when not full, the water is in some measure sheltered from the drying effects of the wind. The only use of such an instrument or gauge is to give us a very vague idea of the drying power of the air. It affords no measure whatever of the evaporation from the ground; for when the soil is exceedingly parched, and consequently has next to no moisture to give off, the gauge generally shows the greatest evaporation of all. Yet in stating the particulars of the climate of a place, it is usual to mention the amount of evaporation derived most probably from no better source. But it cannot even be a measure of the evaporation from a lake, because in that case the indications of the gauge depend very much on the direction of the wind; for it is obvious that if a previously dry wind traverse an extensive lake before reaching the gauge, it may by that time have become so humid as to show little or no drying power at all upon the gauge. When, on the other hand, the wind passes first over the gauge, its indications are to be suspected of erring in excess, because the farther a wind continues to traverse the surface of a lake, the more will its drying power be impaired, and therefore the average rate of evaporation will be less than at the side next the gauge. For this reason the evaporation from a smaller surface of water is, ceteris paribus, greater in proportion to the area than from a larger. Whether any general rule could readily apply to this, we are unable to say. Perhaps something like an approximation to the relation between the area and evaporation in such circum- stances would be had by dividing the area by some root of its mean linear dimension taken in the direction of the wind, and multiplying by a constant. But this would not in the least rectify the indications of the gauge. Since similar objections must obviously attach to all gauges employed for this purpose, it would be of little use to give any farther account of them, or of the registers of evaporation with which many works otherwise valuable are so often encumbered.

It had been long supposed that muriatic acid vapour existed in the atmosphere incumbent over the ocean or on the sea coasts; and various effects were ascribed to its presence. But from experiments detailed in the Journal de Pharmacie for November 1833, it appears that such effects are solely owing to minute drops of salt water or spray which have been swept into the atmosphere by the wind; and that, with the exception of the salt drops thus raised, though only when the sea is ruffled by the wind, sea-air contains neither muriates nor uncombined muriatic acid. At first sight we had some doubt whether this would account for the injurious effects of sea-air on vegetation; because the presence of common salt, if not in excess, is known to be beneficial. But perhaps the salt when united with the soil may operate as a cordial to the roots, while it may be noxious when in immediate contact with the stem or leaves, as is often the case with manure injudiciously applied close to the roots of plants.

In the method of forming ice in India by exposing water during the night to the aspect of a clear sky, the effect was for some time ascribed to evaporation; but Dr Wells ascertained that the water thus exposed gained in place of losing weight. Now it could only gain by being cooled below the dew point of the incumbent air; for it is only in that state that the air could yield a portion of its moisture to the water; and therefore the cold must be the effect of radiation, and not of evaporation. This was farther evident from the circumstance that wind which ought to have increased the evaporation prevented the freezing altogether. But independently of these considerations, water exposed in the open air could never be cooled to the freezing point by evaporation alone in a hot climate. Where such a thing occurs, the air must be unusually dry, even after its temperature scarcely amounts to 40°, or the atmospheric pressure must be very small; because the utmost evaporation that can be produced artificially under the ordinary pressure will little more than cool a wet thermometer from 40° to 32°; and the cooling effect on a vessel with water is not nearly so great, especially in the open air, if care be taken to avoid the influence of radiation under the aspect of a clear sky. It is true that, at Benares for instance, the surface of the ground, after becoming very cold by radiation, sometimes renders the incumbent still air also pretty cold; but this, by bringing the air to a state of saturation with moisture, totally unfitting it for aiding the freezing by evaporation.

So great is the difference of opinion respecting the influence of electricity on evaporation, that we suspect it has not yet been sufficiently investigated. The use of evaporation in the arts and manufactures will be found under the respective articles. In addition to the various works noticed in this article, see Dr Thomas Young's Natural Philosophy; Wells on Dew; Pouillet's Éléments de Physique et de Météorologie. A variety of articles on this subject will be found in the different volumes of the Philosophical Transactions, and other scientific journals.

EVE, the mother of the human race. See ADAM.

Evection. See Astronomy, iv. 36.

EVELYN, John, author of the Sylea Memoirs, &c., was born in 1620 at his father's seat of Wotton in Surrey. He was educated at the free school of Southover, near Lewes, whence he removed in 1637 to Balliol College, Oxford; on leaving which he began the study of law in the Middle Temple. In 1641 he went to Flanders, where he served for a short time as a volunteer; but soon returning home, he joined the king's army in the struggle now begun with the parliament. The following year saw him once more bent on foreign travel, and he accordingly set out with an old college companion on a tour through France, Italy, and Switzerland, in which countries he spent the next seven years of his life, studying men and manners, statistics and science, polite literature and the fine arts. In 1647 he married a daughter of Sir Richard Browne, the English ambassador at the French court; and when that gentleman's estate of Sayes Court was sequestered by parliament, Evelyn was allowed to become the purchaser of it. Here he lived in strict retirement during the period of the Protectorate, engaged in laying out the grounds and gardens, and turning to profitable account the results of his continental studies. During this period also he published a translation of the first book of Lucretius; Chrysostom's Golden Book for the education of Children; and the French Gardener and English Vineyard. At the Restoration, however, he began to take an honourable though not conspicuous part in public affairs; was appointed one of the commissioners for taking care of the sick, wounded, and prisoners, during the Dutch war; commissioner for the rebuilding of St Paul's after the great fire (of which an admirable account will be found in his Journal); and a member of the Board of Trade. He was also made a member of the Council of the Royal Society, to whose Transactions he continued all his life to contribute papers on the subjects towards which his early studies had been directed. His favourite pursuits were gardening and planting, upon which he wrote a number of treatises, appended to the fifth edition of the Sylea, or a Discourse on Forest Trees, and the Propagation of Timber in His Majesty's Dominions, published in 1644 by order of the Royal Society. The object of this treatise was to encourage planting throughout Great Britain, and it produced the desired effect in a manner very gratifying to the author. In 1699, on the death of his elder brother without children, Evelyn succeeded to the family estate of Wotton, to which he removed from Sayes Court, where he had lived happy and respected for upwards of forty years. He was succeeded in the occupancy of that house by the Czar Peter, who with his suite made sad havoc among Evelyn's well-trimmed yew-hedges and elaborate parterres. Evelyn did not live very long to enjoy his new position as head of his family; he died February 27, 1705, in the eighty-sixth year of his age. In the humbler walks of science Evelyn was a successful and persevering inquirer; a valuable pioneer, as he himself used to say, in the service of the Royal Society. His moral character was irreproachable, though he lived at a time when vice was an almost indispensable passport to favour and promotion; and the purity of his morals, his piety, his schemes of active benevolence, and the intellectual nature of his pursuits, were all such as to earn for him the respect even of the court-profligates, to whom his example was a standing rebuke. Altogether our history affords few better specimens of the accomplished and well-principled English gentleman. The most valuable of Evelyn's works (leaving out of account the Sylea already mentioned), is his Diary and Correspondence, and the Memoirs of his Life and Writings, which are valuable not only on account of their literary merits, but also as throwing much light on the times in which their author lived. His other works, which have long since been for the most part superseded, embrace treatises on Sculpture, Architecture, Painting, Numismatics, and certain social questions. A very detailed list of them will be found in Watt's Bibliotheca.

EVEMERUS or EUHemerus, a Sicilian mythographer, who flourished in the latter half of the fourth century B.C.