See also:

• AETHER, or ETHER (Gr. deli p, probably from caeca, I burn, though Plato in his Cratylus (410 B)

AETHER, or See also:

• ETHER, (C2H5)2O

ETHER (Gr. deli p, probably from caeca, I See also:

• BURN, RICHARD (1709-1785)

burn, though See also:

• PLATO

Plato in his Cratylus (410 B)  derives the name from its perpetual See also:

• MOTION (Lat. motio, from movere, to move)
• MOTION, LAWS OF

motion-ore ael See also:

• BEL

Bel 7repi rdv /Epa biwv, aea0er)p &Kaiws &v xa\oiro), a material substance of a more subtle See also:

• KIND (O. E. ge-cynde, from the same root as is seen in " kin," supra)

kind than visible bodies, supposed to exist in those parts of space which are apparently empty . " The See also:

• HYPOTHESIS (from Gr. inrorcOivat, to put under; cf. Lat. suppositio, from sub-ponere)

hypothesis of an See also:

• AETHER, or ETHER (Gr. deli p, probably from caeca, I burn, though Plato in his Cratylus (410 B)

aether has been maintained by different speculators for very different reasons . To those who maintained the existence of a plenum as a philosophical principle, nature's abhorrence of a vacuum was a sufficient See also:

• REASON (Lat. ratio, through French raison)

reason for imagining an all-surrounding aether, even though every other See also:

• ARGUMENT

argument should be against it . To See also:

• DESCARTES, RENE (1596-1650)

Descartes, who made See also:

• EXTENSION (Lat. ex, out ; tendere, to stretch)

extension the See also:

• SOLE (Solea)

sole essential See also:

• PROPERTY

property of See also:

• MATTER

matter, and matter a necessary See also:

• CONDITION (Lat. condicio, from condicere, to agree upon, arrange; not connected with conditio, from condere, conditum, to put together)

condition of extension, the See also:

• BARE

bare existence of bodies apparently at a distance was a See also:

• PROOF (in M. Eng. preove, proeve, preve, &°c., from O. Fr . prueve, proeve, &c., mod. preuve, Late. Lat. proba, probate, to prove, to test the goodness of anything, probus, good)

proof of the existence of a continuous See also:

• MEDIUM

medium between them . But besides these high metaphysical necessities for a medium, there were more mundane uses to be fulfilled by aethers . Aethers were invented for the See also:

• PLANETS, MINOR

planets to swim in, to constitute electric atmospheres and magnetic effluvia, to convey sensations from one See also:

• PART

part of our bodies to another, and so on, till all space had been filled three or four times over with aethers . It is only when we remember the extensive and mischievous See also:

• INFLUENCE (Late Lat. influentia, from influere, to flow in)

influence on See also:

• SCIENCE (Lat. scientia, from scire; to learn, know)

science which hypotheses about aethers used formerly to exercise, that we can appreciate the horror of aethers which sober-minded men had during the 18th See also:

• CENTURY (from Lat. centuria, a division of a hundred men)

century, and which, probably as a sort of hereditary See also:

• PREJUDICE (Lat. praejudicium)

prejudice, descended even to See also:

• JOHN
• JOHN (1167–1216)
• JOHN (1290-c. 1320)
• JOHN (1296-1346)
• JOHN (1371–1419)
• JOHN (1468-1532)
• JOHN (1801-1873)
• JOHN (Heb. llni')
• JOHN (ZAPOLYA) (1487-1540)
• JOHN, 4TH MARQUESS OF TWEEDDALE (c. 1695-1762)
• JOHN, DON (1545-1578)
• JOHN, DON (1629–1679)
• JOHN, GOSPEL OF ST
• JOHN, or HAYS (1513–1571)
• JOHN, THE APOSTLE
• JOHN, THE EPISTLES OF

John See also:

• STUART, ARABELLA (1575-1615)
• STUART, GILBERT (1755-x828)
• STUART, JAMES EWELL BROWN (1833-1864)
• STUART, JOHN
• STUART, MOSES (1780-1852)
• STUART, SIR JOHN, COUNT

Stuart See also:

• MILL
• MILL (O. Eng. mylen, later myln, or miln, adapted from the late Lat. molina, cf. Fr. moulin, from Lat. mola, a mill, molere, to grind; from the same root, mol, is derived " meal;" the word appears in other Teutonic languages, cf. Du. molen, Ger. muhle)
• MILL, JAMES (1773-1836)
• MILL, JOHN (c. 1645–1707)
• MILL, JOHN STUART (1806-1873)

Mill . The disciples of See also:

• NEWTON
• NEWTON, ALFRED (1829–1907)
• NEWTON, JOHN (1725-1807)
• NEWTON, JOHN (1823-1895)
• NEWTON, SIR CHARLES THOMAS (1816-1894)
• NEWTON, SIR ISAAC (1642-1727)

Newton maintained that in the fact of the mutual See also:

• GRAVITATION (from Lat. gravis, heavy)

gravitation of the heavenly bodies, according to Newton's See also:

• LAW
• LAW (0. Eng. lagu, M. Eng. lawe; from an old Teutonic root lag, " lie," what lies fixed or evenly; cf. Lat. lex, Fr. loi)
• LAW, JOHN (1671—1729)
• LAW, WILLIAM (1686-1761)

law, they had a See also:

• COMPLETE

complete quantitative See also:

• ACCOUNT
• ACCOUNT (through O. Fr. acont, Late Lat. comptum, cornputare, to calculate)

account of their motions; and they endeavoured to follow out the path which Newton had opened up by investigating and measuring the attractions and repulsions of electrified and magnetic bodies, and the cohesive forces in the interior of bodies, without attempting to account for these forces . Newton himself, however, endeavoured to account for gravitation by See also:

• DIFFERENCES, CALCULUS OF (Theory of Finite Differences)

differences of pressure in an aether; but he did not publish his theory, ` because he was not able from experiment and observation to give a satisfactory account of this medium, and the manner of its operation in producing the See also:

• CHIEF (from Fr. chef, head, Lat. caput)

chief phenomena of nature.' On the other See also:

• HAND
• HAND (a word common to Teutonic languages; cf. Ger. Hand, Goth. handus)
• HAND, FERDINAND GOTTHELF (1786-185r)

hand, those who imagined aethers in See also:

• ORDER
• ORDER (through Fr. ordre, for earlier ordene, from Lat. ordo, ordinis, rank, service, arrangement; the ultimate source is generally taken to be the root seen in Lat. oriri, rise, arise, begin; cf. " origin ")
• ORDER, HOLY

order to explain phenomena could not specify the nature of the motion of these See also:

• MEDIA

media, and could not prove that the media, as imagined by them, would produce the effects they were meant to explain . The only aether which has survived is that which was invented by See also:

• HUYGENS, CHRISTIAAN (1629-1695)
• HUYGENS, SIR CONSTANTIJN (1596-1687)

Huygens to explain the See also:

• PROPAGATION

propagation of See also:

• LIGHT

light . Theevidence for the existence of the luminiferous aether has accumus lated as additional phenomena of light and other radiations have been discovered; and the properties of this medium, as deduced from the phenomena of light, have been found to be precisely those required to explain electromagnetic phenomena." This description, quoted from See also:

• JAMES
• JAMES (Gr. 'IlrKw,l3or, the Heb. Ya`akob or Jacob)
• JAMES (JAMES FRANCIS EDWARD STUART) (1688-1766)
• JAMES, 2ND EARL OF DOUGLAS AND MAR(c. 1358–1388)
• JAMES, DAVID (1839-1893)
• JAMES, EPISTLE OF
• JAMES, GEORGE PAYNE RAINSFOP
• JAMES, HENRY (1843— )
• JAMES, JOHN ANGELL (1785-1859)
• JAMES, THOMAS (c. 1573–1629)
• JAMES, WILLIAM (1842–1910)
• JAMES, WILLIAM (d. 1827)

James Clerk See also:

• MAXWELL
• MAXWELL, JAMES CLERK (1831–1879)

Maxwell's See also:

• ARTICLE (from Lat. articulus, a joint)

article in the 9th edition of the See also:

• ENCYCLOPAEDIA

Encyclopaedia Britannica, represents the See also:

• HISTORICAL

historical position of the subject up till about 1860, when Maxwell began those constructive speculations in See also:

• ELECTRICAL
• ELECTRICAL (or ELECTROSTATIC) MACHINE

electrical theory, based on the influence of the See also:

• PHYSICAL

physical views of See also:

• FARADAY, MICHAEL (1791-1867)

Faraday and See also:

• LORD
• LORD (O. Eng. hldford, i.e. hldfweard, the warder or keeper of bread, hlIf, loaf; the word is not represented in any other Teutonic language)
• LORD, JOHN (1810-1894)

Lord See also:

• KELVIN, WILLIAM THOMSON, BARON (1824-1907)

Kelvin, which have in their subsequent development largely transformed theoretical physics into the science of the aether . In the See also:

• REMAINDER, REVERSION

remainder of the article referred to, Maxwell reviews the See also:

• EVIDENCE (Lat. evidentia, evideri, to appear clearly)

evidence for the See also:

• NECESSITY (Lat. necessitas)

necessity of an aether, from the fact that light takes See also:

• TIME (0. Eng. Lima, cf. Icel. timi, Swed. timme, hour, Dan. time; from the root also seen in " tide," properly the time of between the flow and ebb of the sea, cf. O. Eng. getidan, to happen, " even-tide," &c.; it is not directly related to Lat. tempus)
• TIME, MEASUREMENT OF
• TIME, STANDARD

time to travel, while it cannot travel as a substance, for if so two interfering See also:

• LIGHTS, CEREMONIAL USE OF

lights could not See also:

• MASK (Fr. masque, apparently from med. Lat. mascus, masca, spectre, through Ital. maschera, Span. mascara)

mask each other in the dark fringes (see INTERFERENCE OF LIGHT) .

Light is therefore an influence propagated as See also:

• WAVE

wave-motion, and moreover by trans-See also:

• VERSE (from Lat. versus, literally a line or furrow drawn by turning the plough, from vertere, and afterwards signifying an arrangement of syllables into feet)

verse undulations, for the reasons brought out by See also:

• THOMAS
• THOMAS (c. 1654-1720)
• THOMAS (d. 110o)
• THOMAS, ARTHUR GORING (1850-1892)
• THOMAS, CHARLES LOUIS AMBROISE (1811-1896)
• THOMAS, GEORGE (c. 1756-1802)
• THOMAS, GEORGE HENRY (1816-187o)
• THOMAS, ISAIAH (1749-1831)
• THOMAS, PIERRE (1634-1698)
• THOMAS, SIDNEY GILCHRIST (1850-1885)
• THOMAS, ST
• THOMAS, THEODORE (1835-1905)
• THOMAS, WILLIAM (d. 1554)

Thomas See also:

• YOUNG
• YOUNG, A
• YOUNG, ARTHUR (1741-1820)
• YOUNG, BRIGHAM (1801-1877)
• YOUNG, CHARLES MAYNE (1777–1856)
• YOUNG, EDWARD (1683–1765)
• YOUNG, JAMES (1811-1883)
• YOUNG, THOMAS (1773-1829)

Young and Augustin See also:

• FRESNEL, AUGUSTIN JEAN (1788-1827)

Fresnel; so that the aether is a medium which possesses See also:

• ELASTICITY

elasticity of a type analogous to rigidity . It must be very different from See also:

• ORDINARY (med. Lat. ordinarius, Fr. ordinaire)

ordinary matter as we know it, for waves travelling in matter constitute See also:

• SOUND
• SOUND, THE (Danish Oresund)

sound, which is propagated hundreds of thousands of times slower than light . If we suppose that the aether differs from ordinary matter in degree but not in kind, we can obtain some See also:

• IDEA (Gr. Ibia, connected with i&eiv, to see; cf. Lat. species from specere, to look at)

idea of its quality from a knowledge of the velocity of See also:

• RADIATION, THEORY OF

radiation and of its possible intensity near the See also:

• SUN
• SUN (0. Eng. sonne, Ger. sonne. Fr. soleil, Lat. sol, Gr. ijXior, from which comes helio- in various English compounds)

sun, in a manner applied See also:

• LONG, GEORGE (1800-1879)
• LONG, JOHN DAVIS (1838– )

long ago by Lord Kelvin (Trans . R . S . Edin. xxi . 1854) . According to See also:

• MODERN

modern measurements the See also:

• SOLAR, SOLLER (Lat. solarium, Fr.• galetas, Ital. solaio)

solar radiation imparts almost 3 gramme-calories of See also:

• ENERGY (from the Gr. ivipyela; iv, in, ipyov, work)

energy per See also:

• MINUTE
• MINUTE (Lat. minutes, small; minuere, to make less)

minute per square centimetre at the distance of the See also:

• EARTH
• EARTH (a word common to Teutonic languages, cf. Ger. Erde, Dutch aarde, Swed. and Dan. jord; outside Teutonic it appears only in the Gr. 'pq'e, on the ground; it has been connected by some etymologists with the Aryan root ar-, to plough, which is seen in
• EARTH, FIGURE OF
• EARTH, FIGURE OF THE

earth, which is about 1.3 X toe ergs per sec. per cm .2 The energy in sunlight per cubic cm. just outside the earth's See also:

• ATMOSPHERE (Gr. fir µ6r, vapour; orkaipa, a sphere)

atmosphere is therefore about 4Xro s ergs; applying the law of inverse squares the value near the sun's See also:

• SURFACE

surface would be 1.8 ergs . Let E be the effective elasticity of the aether; then E = pct, where p is its See also:

• DENSITY (Lat. densus, thick)

density, and c the velocity of light which is 3)(10 10 cm./sec . If t= A cosh (t-x/c) is the linear vibration, the stress is E d/dx; and the See also:

• TOTAL

total energy, which is twice the kinetic energy ap(d/dt)2dx, is zpn2A2 per cm., which is thus equal to 1.8 ergs as above . Now X= 27rc/n, so that if A/X=k, we have 2p(27rck)2=1.8, giving p=ro-22k-2 and E =10-1k2 . Lord Kelvin assumed as a See also:

• SUPERIOR

superior limit of k, the ratio of See also:

• AMPLITUDE (from Lat. amplus, large)

amplitude to wave-length, the value ro-2, which is a very safe limit .

It follows that the density of the aether must exceed 1018, and its elastic modulus must exceed ro3, which is only about 10 8 of the modulus of rigidity of See also:

• GLASS
• GLASS (O.E. glees, cf. Ger. Glas, perhaps derived from an old Teutonic root gla-, a variant of glo-, having the general sense of shining, cf. " glare," " glow ")
• GLASS, STAINED

glass . It thus appears that if the amplitude of vibration could be as much as 10-2 of the wave-length, the aether would be an excessively rare medium with very slight elasticity; and yet it would be capable of transmitting the See also:

• SUPPLY (through Fr. from Lat. supplere, to fill up)

supply of solar energy on which all terrestrial activity depends . But on the modern theory, which includes the See also:

• PLAY

play of electrical phenomena as a See also:

• FUNCTION

function of the aether, there are other considerations which show that this number 10-2 is really an enormous overestimate; and it is not impossible that the co-efficient of ultimate inertia of the aether is greater than the co-efficient of inertia (of different kind) of any existing material substance . The question of whether the aether is carried along by the earth's motion has been considered from the See also:

• EARLY
• EARLY, JUBAL ANDERSON (1816-1894)

early days of the undulatory theory of light . In reviving that theory at the be. ginning of the 19th century, Thomas Young stated his conviction that material media offered an open structure to the substance called aether, which passed through them without hindrance " like the See also:

• WIND
• WIND (a common Teut. word, cognate with Skt. vats, Lat. ventus, cf. " weather," to be of course distinguished from to " wind," to coil or twist, O.Eng. windan, cf. "wander," "wend," &c.)

wind through a See also:

• GROVE (O.E. graf, cf. O.E. gr(efa, brushwood, later" greave "; the word does not appear in any other Teutonic language, and the New English Dictionary finds no Indo-European root to which it can be referred; Skeat considers it connected with " grave," to
• GROVE, SIR GEORGE (182o-1900)
• GROVE, SIR WILLIAM ROBERT (1811-1896)

grove of trees." Any convection of that medium could be tested by the See also:

• CHANGE (derived through the Fr. from the Late Lat. cambium, cambiare, to barter; the ultimate derivation is probably from the root which appears in the Gr. «a urmu', to bend)

change of effective velocity of light, which would be revealed by a See also:

• PRISM (Gr. rrpivµa, properly a thing sawn, Irpii"ety, to saw)

prism as was suggested by F . J . D . See also:

• ARAGO, DOMINIQUE FRANCOIS JEAN (1786-1853)

Arago . Before 1868 Maxwell conducted the experiment by sending light from the illuminated See also:

• CROSS

cross-wires of an observing See also:

• TELESCOPE

telescope forward through the See also:

• OBJECT

object-glass, and through a See also:

• TRAIN (M. Eng. trayn or trayne, derived through Fr. from Late Lat. trahinare, to drag, draw, Lat. trahere, cf. trail, trace, ultimately from the same source)

train of prisms, and' then reflecting it back along the same path; any influence of convection would conspire in altering both refractions, but yet no displacement of the See also:

• IMAGE (Lat. imago, perhaps from the same root as imitari, copy, imitate)

image depending on the earth's motion was detected . As will be seen later, modern experiments have confirmed the entire See also:

• ABSENCE (Lat. absentia)

absence of any effect, such as convection would produce, to very high precision . It has further been verified by See also:

• SIR

Sir See also:

• OLIVER, ISAAC (c. 1566--1617)
• OLIVER, PETER (1594-1648)

Oliver See also:

• LODGE
• LODGE, EDMUND (1756-1839)
• LODGE, H
• LODGE, HENRY CABOT (1850– )
• LODGE, SIR OLIVER JOSEPH (1851– )
• LODGE, THOMAS (c. 1558–1625)

Lodge that even in very narrow spaces the aether is not entrained by its surroundings when they are put into rapid motion . A train of ideas which strongly impressed itself on Clerk Maxwell's mind, in the early stages of his theoretical views, was put forward by Lord Kelvin in 1858; he showed that the See also:

• SPECIAL

special characteristics of the rotation of the See also:

• PLANE

plane of polarization, discovered by Faraday in light propagated along a magnetic See also:

• FIELD (a word common to many West German languages, cf. Ger. Feld, Dutch veld, possibly cognate with O.E. f olde, the earth, and ultimately with root of the Gr. irAaror, broad)
• FIELD, CYRUS WEST (1819-1892)
• FIELD, DAVID DUDLEY (18o5-1894)
• FIELD, EUGENE (1850-1895)
• FIELD, FREDERICK (18o1—1885)
• FIELD, HENRY MARTYN (1822-1907)
• FIELD, JOHN (1782—1837)
• FIELD, MARSHALL (183 1906)
• FIELD, NATHAN (1587—1633)
• FIELD, STEPHEN JOHNSON (1816-1899)
• FIELD, WILLIAM VENTRIS FIELD, BARON (1813-1907)

field, viz. that it is doubled instead of being undone when the light retraces its path, requires the operation of some directed agency of a rotational kind, which must be related to the magnetic field .

Lord Kelvin was thereby induced to identify magnetic force with rotation, involving, therefore, angular momentum in the aether . Modern theory accepts the See also:

• DEDUCTION (from Lat. deducere, to take or lead from or out of, derive)

deduction, but ascribes the momentum to the revolving ions in the molecules of matter traversed by the light; for the magneto-optic effect is See also:

• PRESENT

present only in material media . Long previously Lord Kelvin himself came nearer this view, in offering the See also:

• OPINION (Lat. opinio, from opinari, to think)

opinion that See also:

• MAGNETISM
• MAGNETISM, TERRESTRIAL

magnetism consisted, in some way, in the angular momentum of the material molecules, of which the energy of irregular See also:

• TRANSLATIONS

translations constitutes See also:

• HEAT (0. E. haktu, which like " hot," Old Eng. hat, is from the Teutonic type haita, hit, to be hot; cf. Ger. hitze, heiss; Dutch, hitte, heet, &c.)

heat; but the essential idea of moving electric ions of both kinds, See also:

• POSITIVE (or PORTABLE) ORGAN

positive and negative, in the molecules had still to be introduced . The question of the transparency of the See also:

• CELESTIAL, OR STELLAR

celestial spaces presents itself in the present connexion . Light from stars at unfathomable distances reaches us in such quantity as to suggest that space itself is absolutely transparent, leaving open the question as to whether there is enough matter scattered through it to absorb a sensible part of the light in its See also:

• JOURNEY (through O. Fr. jornee or journee, mod. Fr. journee, from med. Lat. diurnata, Lat. diurnus, of or belonging to dies, day)

journey of years from the luminous See also:

• BODY

body . If the aether were itself constituted of discrete molecules, on the See also:

• MODEL (0. Fr. modelle, mod. modele; It. modello, pattern, mould; from Lat. modus, measure, standard)

model of material bodies, such transparency would not he conceivable . We must be content to treat the aether as a plenum, which places it in a class by itself; and we can thus recognize that it may behave very differently from matter, though in some manner consistent with itself—a remark which is fundamental in the modern theory . See also:

• ACTION

Action across a Distance contrasted with Transmitted Action.—In the See also:

• MECHANICAL

mechanical processes which we can experimentally modify at will, and which therefore we learn to apprehend with greatest fulness, whenever an effect on a body, B, is in causal connexion with a See also:

• PROCESS

process instituted in another body, A, it is usually possible to discover a mechanical connexion between the two bodies which allows the influence of A to be traced all the way across the intervening region . The question thus arises whether, in electric attractions across apparently empty space and in gravitational attraction across the celestial regions, we are invited or required to make See also:

• SEARCH, or VISIT AND SEARCH

search for some similar method of continuous transmission of the physical effect, or whether we should See also:

• REST (O. Eng. rest, reste, bed, cognate with other Teutonic forms, e.g. Ger. Rast, Riiste, rest, and probably Gothic Rasta, league, i.e. resting or stopping place)

rest content with an exact knowledge of the See also:

• LAWS

laws according to which one body affects mechanically another body at a distance . The view that our knowledge in such cases may be completely represented by means of laws of action at a distance, expressible in terms of the positions (and possibly motions) of the interacting bodies without taking any heed of the intervening space, belongs to modern times . It could hardly have been thought of before Sir See also:

• ISAAC (Hebrew for " he laughs," on explanatory references to the name, see ABRAHAM)

Isaac Newton's See also:

• DISCOVERY

discovery of the actual facts regarding universal gravitation . Although, however, gravitation has formed the most perfect instance of an influence completely expressible, up to the most extreme refinement of accuracy, in terms of laws of See also:

• DIRECT

direct action across space, yet, as is well known, the author of this ideally See also:

• SIMPLE

simple and perfect theory held the view that it is not possible to conceive of direct mechanical action See also:

• INDEPENDENT

independent of means of transmission .

In this belief he differed from his See also:

• PUPIL (Lat. pupillus, orphan, minor, dim. of pupus, boy, allied to puer, from root pm- or peu-, to beget, cf. "pupa," Lat. for " doll," the name given to the stage intervening between the larval and imaginal stages in certain insects)

pupil, See also:

• ROGER (d. 1139)
• ROGER (d. 1181)

Roger See also:

• COTES, ROGER (1682-1716)

Cotes, and from most of the See also:

• GREAT

great mathematical astronomers of the 18th century, who worked out in detail the task sketched by the See also:

• GENIUS (from Lat. genere, gignere)

genius of Newton . They were content with a knowledge of the truth of the principle of gravitation; instead of essaying to explain it further by the properties of atransmitting medium, they in fact modelled the whole of their natural See also:

• PHILOSOPHY (Gr. gthos, fond of, and vo4 (a, wisdom)

philosophy on that principle, and tried to See also:

• EXPRESS (through the French from the past participle of the Lat. exprimere, to press out, by transference used of representing objects in painting or sculpture, or of thoughts, &c. in words)

express all kinds of material interaction in terms of laws of direct mechanical attraction across space . If material systems are constituted of discrete atoms, separated from each other by many times the See also:

• DIAMETER (from the Cr. &a, through, µErpov, measure)

diameter of any of them, this simple See also:

• PLAN
• PLAN (from Lat. planes, flat)

plan of exhibiting their interactions in terms of direct forces between them would indeed be exact enough to apply to a wide range of questions, provided we could be certain that the laws of the forces depended only on the positions and not also on the motions of the atoms . The most important example of its successful, application has been the theory of capillary action elaborated by P . S . See also:

• LAPLACE, PIERRE SIMON, MARQUIS DE (1749—1827)

Laplace; though even here it appeared, in the hands of Young, and in complete fulness afterwards in those of C . F . See also:

• GAUSS, KARL FRIEDRICH (1777-1855)

Gauss, that the definite results attainable by the hypothesis of mutual atomic attractions really reposed on much wider and less special principles—those, namely, connected with the modern See also:

• DOCTRINE

doctrine of energy . Idea of an Aether.—The wider view, according to which the hypothesis of direct transmission of physical influences expresses only part of the facts, is that all space is filled with physical activity, and that while an influence is passing across from a body, A, to another body, B, there is some dynamical process in action in the intervening region, though it appears to the senses to be See also:

• MERE
• MERE, ADALBERT (1838-1909)

mere empty space . The problem is whether we can represent the facts more simply by supposing the intervening space to be occupied by a medium which transmits physical actions, after the manner that a continuous material medium, solid or liquid, transmits mechanical disturbance . Various analogies of this sort are open to us to follow up: for example, the way in which a fluid medium transmits pressure from one immersed solid to another—or from one vortex See also:

• RING (O.E. hring; a word common to Teutonic languages; and probably cognate with the Lat. circus, Gr. KtpKOS or KpLKOS, Skt'. chakra, wheel, circle, cf. also " harangue "); in art, a band of circular shape of varying sizes, made of any material and used f

ring belonging to the fluid to another, which is a much wider and more suggestive See also:

• CASE
• CASE, JOHN (d. 1600)

case; or the way in which an elastic fluid like the atmosphere transmits sound; or the way in which an elastic solid transmits waves of transverse as well as See also:

• LONGITUDINAL

longitudinal displacement . It is on our familiarity with modes of transmission such as these, and with the exact analyses of them which the science of mathematical physics has been able to make, that our predilection for filling space with an aethereal transmitting medium, constituting a universal connexion between material bodies, largely depends perhaps ultimately it depends most of all, like all our physica conceptions, on the intimate knowledge that we can ourselves exert mechanical effect on outside bodies only through th, agencies of our limbs and sinews .

The problem thus arises Can we See also:

• FORM (Lat. forma)

form a consistent notion of such a connecting medium ? It must be a medium which can be effective for transmitting al the types of physical action known to us; it would be worse than no See also:

• SOLUTION (from Lat. solvere, to loosen, dissolve)

solution to have one medium to transmit gravitation, another to transmit electric effects, another to transmit light, and so on . Thus the See also:

• ATTEMPT (Lat. adtemptare, attentare, to try)

attempt to find out a constitution for the aether will involve a See also:

• SYNTHESIS (Gr. a6vOeacs, from avvrcBivac, to put together)

synthesis of intimate correlation of the various types of physical agencies, which appear so different tc us mainly because we perceive them through different senses . The evidence for this view, that all these agencies are at bottom connected together and parts of the same See also:

• SCHEME (Lat. schema, Gr. oxfjya, figure, form, from the root axe, seen in exeiv, to have, hold, to be of such shape, form, &c.)

scheme, was enormously strengthened during the latter See also:

• HALF

half of the rgth century by the development of a relation of simple quantitative equivalence between them; it has been found that we can define quantities See also:

• RELATING

relating to them, under the names of mechanical energy, electric energy, thermal energy, and so on, so that when one of them disappears, it is replaced by the others to exactly equal amount . This single principle of energy has transformed physical science by making possible the construction of a network of ramifying connexions between its various departments; it thus stimulates the belief that these constitute a single whole, and encourages the search for the complete scheme of interconnexion of which the principle of energy and the links which it suggests form only a single feature . In carrying out this scientific See also:

• PROCEDURE (Fr. procedure, from Lat. procedere, to go for-ward)

procedure false steps will from time to time be made, which will have to be retraced, or rather amended; but the See also:

• COMBINATION (Lat. combinare, to combine)

combination of experimental science with theory has elevated our presumption of the rationality of all natural processes, so far as we can apprehend them at all, into See also:

• PRACTICAL

practical certainty; so that, though the mode of presentation of the results may vary from See also:

• AGE (Fr. age, through late Lat. aetaticum, from aetas)

age to age, it is hardly conceivable that the essentials of the method are not of permanent validity . Atomic Structure of Matter.—The greatest obstacle to such a search for the fundamental medium is the illimitable complexity of matter, as contrasted with the theoretical simplicity and uniformity of the physical agencies which connect together its different parts . It has been maintained since the times of the early See also:

• GREEK
• GREEK, ETRUSCAN AND

Greek philosophers, and possibly even more remote ages, that matter is constituted of independent indestructible See also:

• UNITS, DIMENSIONS OF
• UNITS, PHYSICAL

units, which cannot ever become divided by means of any mutual actions they can exert . Since the See also:

• PERIOD
• PERIOD (Gr. irepioSos, a going or way round, circuit, aepi, round, and &Sis, way, road)

period, a century ago, when See also:

• DALTON
• DALTON, JOHN (1766-1844)

Dalton and his contemporaries constructed from this idea a scientific basis for See also:

• CHEMISTRY
• CHEMISTRY (formerly "chymistry"; Gr. xvµela; for derivation see ALCHEMY)

chemistry, the progress of that subject has been wonderful beyond any conception that could previously have been entertained; and the atomic theory in some form appears to be an indispensable part of the framework of physical science . Now this doctrine of material atoms is an almost necessary corollary to the doctrine of a universal aether . For if we held that matter is continuous, one of two alternatives would be open . We might consider that matter and aether can co-exist in the same space; this would involve the co-existence and interaction pf a See also:

• DOUBLE
• DOUBLE (from the Mid. Eng. duble, the form which gives the present pronunciation, through the Old Er. duble, from Lat. duplus, twice as much)

double set of properties, introducing great complication, which would See also:

• PLACE (through Fr. from Lat. platea, street; Gr. IrAar6s, wide)

place any coherent scheme of physical action probably beyond the See also:

• POWERS, HIRAM (1805-1873)

powers of human See also:

• ANALYSIS (Gr. avci and Meta, to break up into parts)

analysis .

Or we might consider that aether exists only where matter is not, thus making it a very rare and subtle and elastic kind of matter; then we should have to assign these very properties to the matter itself where it replaces aether, in addition to its more See also:

• FAMILIAR (through the Fr. familier, from Lat. familiaris, of or belonging to the familia, family)

familiar properties, and the complication would remain . The other course is to consider matter as formed of ultimate atoms, each the See also:

• NUCLEUS (Lat. for the kernal of a nut, nux, the stone of fruit)

nucleus or core of an See also:

• INTRINSIC (through Fr. intrinsique, from Lat. intrinsecus, inwardly; inter, within, secus, following, from root of sequi, to follow)

intrinsic modification impressed on the surrounding region of the aether; this might conceivably be of the nature of vortical motion of a liquid See also:

• ROUND (O. Fr. rond, Lat. rotundus, the Fr. is the source also of Du. rond; Ger., Swed., Dan. and Nor. rond)

round a ring-core, thus giving a vortex See also:

• ATOM (Gr. &rows, indivisible, from a- privative, and TE,aPfw, to cut)

atom, or of an intrinsic See also:

• STRAIN (through O. Fr. straindre, estraindre, mod. i treindre, from Lat. stringere, to draw tight, related to stress, stretch, string, &c.)

strain of some sort radiating from a core, which would give an electric atom . We recognize an atom only through its physical activities, as manifested in its interactions with other atoms at a distance from it; this field of physical activity would be identical with the surrounding field of aethereal motion or strain that is inseparably associated with the nucleus, afld is carried on along with it as it moves . Here then we have the basis of a view in which there are not two media to be considered, but one medium, homogeneous in essence and differentiated as regards its parts only by the presence of nuclei of intrinsic strain or motion—in which the physical activities of matter are identified with those arising from the atmospheres of modified aether which thus belong to its atoms . As regards laws of See also:

• GENERAL
• GENERAL (Lat. generalis, of or relating to a genus, kind or class)

general physical interactions, the atom is fully represented by the constitution of this atmosphere, and its nucleus may be See also:

• LEFT

left out of our discussions; but in the problems of See also:

• BIOLOGY (Gr. Qios, life)

biology great tracts of invariable correlations have to be dealt with, which seem hopelessly more complex than any known or humanly possible physical scheme . To make See also:

• ROOM

room for these we have to remember that the atomic nucleus has remained entirely undefined and beyond our problem; so that what may occur, say when two molecules come into See also:

• CLOSE
• CLOSE (from Lat. clausum, shut)
• CLOSE, MAXWELL HENRY (1822-1903)

close relations, is outside physical science—not, however, altogether outside, for we know that when the vital nexus in any portion of matter is dissolved, the atoms will remain, in their number, and their atmospheres, and all inorganic relations, as they were before vitality supervened . Nature of Properties of Material Bodies.—It thus appears that the doctrine of atomic material constitution and the doctrine of a universal aether stand to each other in a relation of mutual support; if the scheme of physical laws is to be as precise as observation and measurement appear to make it, both doctrines are required in our efforts towards synthesis . Our direct know-ledge of matter can, however, never be more than a rough knowledge of the general See also:

• AVERAGE

average behaviour of its molecules; for the smallest material speck that is sensible to our coarse perceptions contains myriads of atoms . The properties of themost minute portion of matter which we can examine are thus of the nature of averages . We may gradually invent means of tracing more and more closely the average drifts of See also:

• TRANSLATION

translation or See also:

• ORIENTATION

orientation, or of changes of arrangement, of the atoms; but there will always remain an unaveraged See also:

• RESIDUE (through the French, from the Lat. residuum, a remainder, from residere, to remain)

residue devoid of any recognized regularity, which we can only estimate by its total amount . Thus, if we are treating of energy, we can See also:

• SEPARATE

separate out mechanical and electric and other constituents in it; and there will be a residue of which we know nothing except its quantity, and which we See also:

• CALL (from Anglo-Saxon ceallian, a common Teutonic word, cf. Dutch kallen, to talk or chatter)

call thermal . This merely thermal energy—which is gradually but very slowly being restricted in amount as new subsidiary organized types become recognized in it—though transmutable in See also:

• EQUIVALENT

equivalent quantities with the other kinds, yet is so only to a limited extent; the tracing out of the laws of this See also:

• LIMITATION, STATUTES OF

limitation belongs to the science of See also:

• THERMODYNAMICS (from Gr. Bepµos, hot, Siva trs, force)

thermodynamics .

It is the business of that science to find out what is the greatest amount of thermal energy that can possibly be recoverable into organized kinds under given circumstances . The discovery of definite laws in this region might at first sight seem hopeless; but the argument rests on an implied postulate of stability and continuity of constitution of material substances, so that after a See also:

• CYCLE
• CYCLE (Gr. KUK)^os, a circle)

cycle of transformations we expect to recover them again as they were originally—on the postulate, in fact, that we do not expect them to melt out of organized existence in our hands . The laws of thermodynamics, including the fundamental principle that a physical property, called temperature, can be defined, which tends towards uniformity, are thus relations between the properties of types of material bodies that can exist permanently in presence of each other; why they so maintain themselves remains unknown, but the fact gives the point d'appui . The fundamental See also:

• CHARACTER (Gr. xapareri7p, from xap&crew, to scratch)

character of energy in material systems here comes into view; if there were any other independent scalar entity, besides See also:

• MASS (O.E. maesse; Fr. messe; Ger. Messe; Ital. messa; from eccl. Lat. missa)
• MASS, IN

mass and energy, that pervaded them with relations of equivalence, we should expect the existence of yet another set of qualities analogous to those connected with temperature . (See See also:

• ENERGETICS

ENERGETICS.) . Returning now to the aether, on our present point of view no such complications there arise; it must be regarded as a continuous See also:

• UNIFORM

uniform medium See also:

• FREE

free from any complexities of atomic See also:

• AGGREGATION (from the Lat. ad, to, gregare, to collect together)

aggregation, whose function is confined to the transmission of the various types of physical effect between the portions of matter . The problem of its constitution is thus one which can be attacked and continually approximated to, and which may possibly be definitely resolved . It has to be competent to transmit the transverse waves of light and See also:

• ELECTRICITY

electricity, and the other known radiant and electric actions; the way in which this is done is now in the See also:

• MAIN (from the Aryan root which appears in " may " and " might," and Lat. magnus, great)
• MAIN (Lat. Moenus)

main known, though there are still questions as to the mode of expression and formulation of our knowledge, and also as regards points of detail . This great advance, which is the result of the See also:

• GRADUAL (Med. Lat. gradualis, of or belonging to steps or degrees; gradus, step)

gradual focussing of a century's See also:

• WORK

work in the minute exploration of the exact laws of See also:

• OPTICAL

optical and electric phenomena, clearly carries with it deeper insight into the physical nature of matter itself and its modes of inanimate interaction . If we rest on the synthesis here described, the energy of. the matter, even the thermal part, appears largely as potential energy of strain in the aether which interacts with the kinetic energy associated with disturbances involving finite velocity of matter . It may, however, be maintained that an ultimate analysis would go deeper, and resolve all phenomena of elastic resilience into consequences of the kinetic stability of steady motional states, so that only motions, but not strains, would remain . On such a view the aether might conceivably be a perfect fluid, its fundamental property of elastic reaction arising (as at one time suggested by Kelvin and G .

F . See also:

• FITZGERALD
• FITZGERALD, EDWARD (1809–1883)
• FITZGERALD, LORD E
• FITZGERALD, LORD EDWARD (1763-1798)
• FITZGERALD, LORD THOMAS (loth earl of Kildare), (1513-1537)
• FITZGERALD, RAYMOND, or REDMOND (d. ca. 1182)

FitzGerald) from a structure of tangled or interlaced vortex filaments pervading its substance, which might conceivably arrange themselves into a See also:

• STABLE

stable configuration and so resist deformation . This raises the further question as to whether the transmission of gravitation can be definitely recognized among the properties of an ultimate medium; if so, we know that it must be associated with some feature, perhaps very deep-seated, or on the other hand perhaps depending simply on incompressibility, which is not sensibly implicated in the electric and optical activities . With reference to all such further refinements of theory, it is to be See also:

• BORNE, KARL LUDWIG (1786–1837)

borne in mind that the perfect fluid of hydrodynamic analysis is not a merely passive inert plenum; it is also a continuum with the property that no finite See also:

• INTERNAL

internal slip or discontinuity of motion can ever arise in it through any kind of disturbance; and this property must be postulated, as it cannot be explained . Motion of Material Atoms through the Aether.—An important question arises whether, when a material body is moved through the aether, the nucleus of each atom carries some of the surrounding aether along with it; or whether it practically only carries on its strain-form or physical atmosphere, which is transferred from one portion of aether to another after the manner of a See also:

• SHADOW (0. Eng. Schadewe, sceadu; a form of " shade "; connected with Gr. 6-Ore's, darkness)

shadow, or rather like a loose See also:

• KNOT
• KNOT (O.E. cnotta, from a Teutonic stem knutt; cf. " knit," and Ger. knoten)

knot which can slip along a rope without the rope being required to go with it . We can obtain a pertinent See also:

• ILLUSTRATION

illustration from the motion of a vortex ring in a fluid; if the circular core of the ring is thin compared with its diameter, and the vorticity is not very great, it is the vortical See also:

• STATE
• STATE, GREAT OFFICERS OF

state of motion that travels across the fluid without transporting the latter bodily with it except to a slight extent very close to the core . We might thus examine a structure formed of an aggregation of very thin vortex rings, which would move across the fluid without sensibly disturbing it; on the other hand, if formed of stronger vortices, it may transport the portion of the fluid that is within, or adjacent to, its own structure along with it as if it were a solid mass, and therefore also push aside the surrounding fluid as it passes . The motion of the well-known steady spherical vortex is an example of the latter case . Convection of Optical Waves.—The nature of the motion, if any, that is produced in the surrounding regions of the aether by the translation of matter through it can be investigated by optical experiment . The obvious body to take in the first instance is the earth itself, which on account of its See also:

• ANNUAL

annual orbital motion is travelling through space at the See also:

• RATE

rate of about 18 See also:

• MILES, NELSON APPLETON (1839— )

miles per second . If the surrounding aether is thereby disturbed, the waves of light arriving from the stars will partake of its See also:

• MOVEMENT

movement; the ascertained phenomena of the astronomical See also:

• ABERRATION (Lat. ab, from or away, errare,, to wander)

aberration of light show that the rays travel to the observer, across this disturbed aether near the earth, in straight lines . Again, we may split a narrow See also:

• BEAM
• BEAM (from the O. Eng. beam, cf. Ger. Baum, a tree, to which sense may be referred the use of " beam " as meaning the rood or crucifix, and the survival in certain names of trees, as horn-beam)

beam of light by partial reflexion from a transparent See also:

• PLATE

plate, and recombine the constituent beams after they have traversed different circuits of nearly equivalent lengths, so as to obtain interference fringes .

The position of these fringes will depend on the total retardation in time of the one beam with respect to the other; and thus it might be expected to vary with the direction of the earth's motion relative to the apparatus . But it is found not to vary at all, even up to the second order of the ratio of the earth's velocity to that of light . It has in fact been found, with the very great precision of which optical experiment is capable, that all terrestrial optical phenomenareflexion, See also:

• REFRACTION
• REFRACTION (Lat. refringere, to break open or apart)

refraction, polarization linear and circular, diffraction —are entirely unaffected by the direction of the earth's motion, while the same result has recently been extended to electrostatic forces; and this is our main experimental See also:

• CLUE

clue . We pass on now to the theory . We shall make the natural supposition that motion of the aether, say with velocity (u,v,w) at the point (x,y,z), is simply superposed on the velocity V of the optical undulations through that medium, the latter not being intrinsically altered . Now the direction and phase of the light are those of the See also:

• RAY (Lat. raia)
• RAY (or WRAY, as he wrote his name till 1670), JOHN (1628-1705)

ray which reaches the See also:

• EYE
• EYE (O. Eng. edge, Ger. Auge; derived from an Indo-European root also seen in Lat. oc-ulus, the organ of vision (q.v.)

eye; and by See also:

• FERMAT, PIERRE DE (1601-1665)

Fermat's principle, established by Huygens for undulatory motion, the path of a ray is that track along which the disturbance travels in least time, in the restricted sense that any alteration of any See also:

• SHORT, FRANCIS JOB (1857– )

short reach of the path will increase the time . Thus the path of the ray when the aether is at rest is the See also:

• CURVE (Lat. curvus, bent)

curve which makes fds/V least; but when it is in motion it is the curve which makes fds/(V+lu+mv+nw) least, where (l,m,n) is the direction vector of Ss . The latter integral becomes, on expanding in a See also:

• SERIES (a Latin word from serere, to join)

series, fds/V f(udx+vdy+wdz)/V2+f(udx+vdy+wdz)2/V'ds+..., since lds = dx . If the path is to be unaltered by the motion of the aether, as the law of astronomical aberration suggests, this must differ from fds/V by terms not depending on the path—that is, by terms involving only the beginning and end of it . In the case of the free aether V is See also:

• CONSTANT, BENJAMIN (1845-1902)

constant; thus, if we neglect squares like (u/V)2, the condition is that udx +vdy+wdz be the exact See also:

• DIFFERENTIAL

differential of some function cp . If this relation is true along all paths, the velocity of the aether must be of irrotational type, like that of frictionless fluid . Moreover, this is precisely the condition for the absence of interference between the component of a split beam; because, the time of passage being to the first order fds/V f(udx+vdy+wdz)V2, the second See also:

• TERM

term will then be independent of the path (ck being a single valued function) and therefore the same for the paths of both the interfering beams .

If therefore the aether can be put into motion, we conclude (with See also:

• STOKES, SIR G
• STOKES, SIR GEORGE GABRIEL, BART
• STOKES, WHITLEY (1830-1909)

Stokes) that such motion, in free space, must be of strictly irrotational type . But our experimental data are not confined to free space . If c is the velocity of radiation in free space and ,u the refractive See also:

• INDEX

index of a transparent body, V= dig; thus it is the expression c 2f,u2(u'dx+v'dy+w'dz) that is to be integrable explicitly, where now (u',v',w') is what is added to V owing to the velocity (u,v,w) of the medium . As, however, our terrestrial optical apparatus is now all- in motion along with the matter, we must See also:

• DEAL

deal with the rays relative to the moving See also:

• SYSTEM

system, and to these also Fermat's principle clearly applies; thus V+ (lu'+mv'+nw') is here the velocity of radiation in the direction of the ray, but relative to the moving material system . Now the expression above given cannot be integrable exactly, under all circumstances and whatever be the axes of co-ordinates, unless (µ2u'„u2vi,,u2w') is the gradient of a continuous function . In the simplest case, that of uniform translation, these components of the gradient will each be constant throughout the region; at a distant place in free aether where there is no motion, they must thus be equal to -u,-v,-w, as they refer to axes moving with the matter . Hence the paths and times of passage of all rays relative to the material system will not be altered by a uniform motion of the system, provided the velocity of radiation relative to the system, in material of index jc, is diminished by p-2 times the velocity of the system in the direction of the radiation, that is, provided the See also:

• ABSOLUTE (Lat. absolvere, to loose, set free)

absolute velocity of radiation is increased by 1-µ-2 times the velocity of the material system; this involves that the free aether for whichµ is unity shall remain at rest . This statement constitutes the famous hypothesis of Fresnel, which thus ensures that all phenomena of ray-path and refraction, and all those depending on phase, shall be unaffected by uniform convection of the material medium, in accordance with the results of experiment . Is the Aether Stationary or See also:

• MOBILE

Mobile?—This theory secures that the times of passage of the rays shall be independent of the motion of the system, only up to the first order of the ratio of its velocity to that of radiation . But a classical experiment of A . A . Michelson, in which the ray-path was wholly in See also:

• AIR (from an Indo-European root meaning " breathe," " blow ")
• AIR, or ASBEN

air, showed that the See also:

• INDEPENDENCE
• INDEPENDENCE, DECLARATION OF
• INDEPENDENCE, WAR OF

independence extends to higher orders .

This result is inconsistent with the aether remaining at rest, unless we assume that the dimensions of the moving system depend, though to an extent so small as to be not otherwise detectable, on its orientation with regard to the aether that is streaming through it . It is, however, in complete accordance with a view that would make the aether near the earth fully partake in its orbital motion—a view which the null effect of convection on all terrestrial optical and electrical phenomena also strongly suggests . But the aether at a great distance must in any case be at rest; while the facts of astronomical aberration require that the motion of that medium must be irrotational . These conditions cannot be consistent with sensible convection of the aether near the earth without involving discontinuity in its motion at some intermediate distance, so that we are thrown back on the previous theory . Another powerful reason for taking the aether to be stationary is afforded by the character of the equations of electrodynamics; they are all of linear type, and superposition of effects is possible . Now the See also:

• KINETICS (from Gr. taveiv, to move)

kinetics of a medium in which the parts can have finite relative motions will See also:

• LEAD
• LEAD (pronounced iced)

lead to equations which are not linear—as, for example, those of See also:

• HYDRODYNAMICS (Gr. Scot)

hydrodynamics—and the phenomena will be far more complexly involved . It is true that the theory of vortex rings in hydrodynamics is of a simpler type; but electric currents cannot be likened to permanent vortex rings, because their circuits can be broken and the See also:

• ELEMENT (Lat. elementum)

element of cyclic steadiness on which the simplicity depends is thereby destroyed . Dynamical Theories of the Aether.—The See also:

• ANALYTICAL

analytical equations which represent the propagation of light in free aether, and also in aether modified by the presence of matter, were originally See also:

• DEVELOPED

developed on the See also:

• ANALOGY (Gr. avaXo-yLa, proportion)

analogy of the equations of propagation of elastic effects in solid media . Various types of elastic solid medium have thus been invented to represent the aether, without complete success in any case . In T . See also:

• MACCULLAGH, JAMES (1809-1847)

MacCullagh's hands the correct equations were derived from a single energy See also:

• FORMULA
• FORMULA (Lat. diminutive of forma, shape, pattern, &c., especially used of rules of judicial procedure)

formula by the principle of least action; and while the validity of this dynamical method was maintained, it was frankly admitted that no mechanical analogy was forthcoming . When Clerk Maxwell pointed out the way to the See also:

• COMMON

common origin of optical and electrical phenomena, these equations naturally came to repose on an electric basis, the connexion having been first definitely exhibited by FitzGerald in 1878; and according as the independent variable was one or other of the vectors which represent electric force, magnetic force or electric See also:

• POLARITY (Lat. polaris, poles, pole)

polarity, they took the form appropriate to one or other of the elastic theories above mentioned .

In this place it must suffice to indicate the gist of the more See also:

• RECENT

recent developments of the electro-optical theory, which involve the dynamical verification of Fresnel's hypothesis regarding optical convection and the other relations above described . The aether is taken to be at rest; and the strain-forms belonging to the atoms are the electric See also:

• FIELDS, JAMES THOMAS (1817-1881)

fields of the intrinsic charges, or electrones, involved in their constitution . When the atoms are in motion these strain-forms produce straining and unstraining in the nether as they pass across it, which in its motional or kinetic aspect constitutes the resulting magnetic field; as the strains are slight the coefficient of ultimate inertia here involved must be great . True electric current arises solely from convection of the atomic charges or electrons; this current is there-fore not restricted as to form in any way . But when the rate of change of aethereal strain—that is, of (f,g,h) specified as Max-well's electric displacement in free aether—is added to it, an analytically convenient vector (u,v,w) is obtained which possesses the characteristic property of being circuital like the flow of an incompressible fluid, and has therefore been made fundamental in the theory by Maxwell under the name of the total electric current . As already mentioned, all efforts to assimilate optical propagation to transmission of waves in an ordinary solid medium have failed; and though the idea of regions of intrinsic strain, as for example in unannealed glass, is familiar in physics, yet on account of the absence of mobility of the strain no attempt had been made to employ them to illustrate the electric fields of atomic charges . The idea of MacCullagh's aether, and its property of purely rotational elasticity which had been ex-pounded objectively by W . J . M . See also:

• RANKINE, WILLIAM JOHN MACQUORN (182o-1872)

Rankine, was therefore much vivified by Lord Kelvin's See also:

• SPECIFICATION (from Med. Lat. specificatio, specificare, to enumerate or mention in detail)

specification (Comptes Rendus, 1889) of a material gyrostatically constituted medium which would aossess this character . More recently a way has been pointed out in which a mobile permanent field of electric force could exist in such a medium so as to travel freely in See also:

• COMPANY

company with its nucleus or intrinsic See also:

• CHARGE
• CHARGE (through the Fr. from the Late Lat. carricare, to load in a carrus or wagon; cf. " cargo ")

charge—the nature of the mobility of the latter, as well as its intimate constitution, remaining unknown . A See also:

• DIELECTRIC

dielectric substance is electrically polarized by a field of electric force, the atomic poles being made up of the displaced positive and negative intrinsic charges in the atom: the polarization per unit See also:

• VOLUME

volume (f',g',h') may be defined on the analogy of magnetism, and d/dt(f',g',h') thus constitutes true electric current of polarization, i.e. of electric separation in the molecules, specified per unit volume .

The convection of a medium thus polarized involves electric disturbance, and therefore must See also:

• CON

con-See also:

• TRIBUTE (Lat. tributurn, a stated payment, contribution)

tribute to the true electric current; the determination of this(f',g',h') 4 c(P,Q,R), because any change of the dielectric constant K arising from the convection of the material through the aether must be independent of the sign of v and therefore be of the second order . Now the electric force (P,Q,R) is the force acting on the electrons of the medium moving with velocity v; consequently by Faraday's electrodynamic law (P,Q,R) = (P',Q' — vc, R'+vb) where (P',Q',R') is the force that would See also:

• ACT (Lat. actus, actum)

act on electrons at rest, and (a,b,c) is the magnetic See also:

• INDUCTION (from Lat. inducere, to lead into; cf. Gr. ilrayu yli)

induction . The latter force is, by Maxwell's hypothesis or by the dynamical theory of an aether pervaded by electrons, the same as that which strair s the aether, and may be called the aethereal force; it thereby produces an aethereal electric displacement, say (f,g,h), according to the relation (f,g,h) _ (4rc2) in which c is a constant belonging to the aether, which turns out to be the velocity of light . The current of aethereal displacement d/dt(f,g,h) is what adds on to the true electric current to produce the total circuital current of Maxwell . We have now to substitute these data in the universally valid circuital relations—namely, (i) See also:

• LINE

line integral of magnetic force round a See also:

• CIRCUIT (Lat. circuitus, from circum, round, and ire, to go)

circuit is equal to 47 times the current through its See also:

• APERTURE (from Lat. aperire, to open)

aperture, which may be regarded as a See also:

• DEFINITION (Lat. definitio, from de-finire, to set limits to, describe)

definition of the constitution of the aether and its relation to the electrons involved in it; and (ii) line integral of the electric force belonging to any material circuit (i.e. acting on the electrons situated on it which move with the velocity of the, matter) is equal to minus the time-rate of change of the magnetic induction through that circuit as it moves with the matter, this being a dynamical consequence of the aethereal constitution assigned in (i) . We may now, as is somewhat the more natural course in the terrestrial application, take axes (x,y,z) which move with the matter; but the current must be invariably defined by the See also:

• FLUX (Lat. fluxus, a flowing; this being also the meaning of the English term in medicine, &c.)

flux across surfaces fixed in space, so that we may say that relation (i) refers to a circuit fixed in space, while (ii) refers to one moving with the matter . These circuital relations, when expressed analytically, are then for a dielectric medium of types d-y ay de -dz_ -4au, where (u,v,w) = (+ d( f dR da dy dz dt .. ' ' See H . A . Lorentz, loc. cit. infra; J . Larmor, Aether and Matter, p . 262 and passim .

constituent of the current is the most delicate point in the investigation . The usual definition of the component current in any direction, as the See also:

• NET

net amount of electrons which crosses, towards the positive See also:

• SIDE
• SIDE (mod. Eski Adalia)

side, an element of surface fixed in space at right angles to that direction, per unit See also:

• AREA

area per unit time, here gives no definite result . The See also:

• ESTABLISHMENT (0. Fr. establissement, Fr. etablissement, late Norm. Fr. establishement, from O. Fr. establir, Fr. etablir, Lat. stabilire, to make stable)

establishment and convection of a single polar atom constitutes in fact a quasi-magnetization, in addition to the polarization current as above defined, the negative poles completing the current circuits of the positive ones . But in the transition from molecular theory to the electrodynamics of extended media, all magnetism has to be replaced by a See also:

• DISTRIBUTION (Lat. distribuere, to deal out)

distribution of current; the latter being now specified by volume as well as by flow so that (u,v,w) Sr is the current in the element of volume Sr . In the present case the total dielectric contribution to this current See also:

• WORKS

works out to be the change per unit time in the electric separation in the molecules of the element of volume, as it moves uniformly with the matter, all other effects being compensated molecularly without affecting the propagation.' On subtracting from this total the current of establishment of polarization d/dt/(f',g',h') as formulated above, there remains vd/dx(f',g',h') as the current of convection of polarization when the convection is taken for simplicity to be in the direction of the See also:

• AXIS (Lat. for " axle ")

axis of x with velocity v . The polarization itself is determined from the electric force (P,Q,R) by the usual statical formula of linear type which becomes for an isotropic medium and where, when magnetic quality is inoperative, the magnetic induction (a,b,c) is identical with the magnetic force (a,(3,y) . These equations determine all the phenomena . They take this simple form, however, only when the movement of the matter is one of translation . If u varies with respect to locality, or if there is a velocity of convection (p,q,r) variable with respect to direction and position, and analytical expression of the relation (ii) assumes a more complex form; we thus derive the most general equations of electrodynamic propagation for matter treated as continuous, anyhow distributed and moving in any manner . For the simplest case of polarized waves travelling parallel to the axis of x, with the magnetic oscillation y along z and the electric oscillation Q along y, all the quantities are functions of x and t alone; the total current is along y and given with respect to our moving axes by v=(d- 4-lx) Q+irc2 4 +dt d(K 4 ac1 -1) Q dt ' also the circuital relations here reduce to dy _ dQ Ti - 4-, dx dt ' _ dv dx2—4 R d2Q (c2.-v2) d Q ° KdQ 2dxdt For a simple wave-train, Q varies as See also:

• SIN
• SIN (O. Eng. syn: a common Teutonic word, cf. Dutch zonde, Ger. Siinde)

sin m(x-Vt), leading on substitution to the velocity of propagation V relative to the moving material, by means of the See also:

• EQUATION (from Lat. aequatio, aequare, to equalize)

equation KV2 + 2tV=c2-v2; this gives, to the first order of v/c, V = c/Ki - v/K, which is in accordance with Fresnel's law . Trains of waves nearly but not quite homogeneous as regards wave-length will as usual be propagated as wave-See also:

• GROUPS
• GROUPS, THEORY

groups travelling with the slightly different velocity d(VA-1)/dX-I, the value of K occurring in V being a function of X determined by the law of optical See also:

• DISPERSION
• DISPERSION (from Lat. dispergere, to scatter)

dispersion of the medium . For purposes of theoretical discussions relating to moving radiators and reflectors, it is important to remember that the See also:

• DYNAMICS
• DYNAMICS (from Gr. bbvayts, strength)

dynamics of all this theory of electrons involves the neglect of terms of the order (v/c)2, not merely in the value of K but throughout .

Recent Experimental Developments.—The modification of the spectrum of a radiating See also:

• GAS

gas by a magnetic field, such as would result from the hypothesis that the radiators are the system of revolving or oscillating electrons in the See also:

• MOLECULE (from mod. Lat. molecula, the diminutive of moles, a mass)

molecule, was detected by P . Zeeman in 1896, and worked up, in See also:

• CONJUNCTION (from Lat. conjungere, to join together)

conjunction with H . A . Lorentz, on the general lines suggested by the See also:

• ELECTRON

electron-theory of molecular constitution . While it cannot be said that the full significance of this very definite phenomenon, consisting of the splitting of the spectral line into a number of polarized components, has yet been made out, a wide field of correlation with optical theory, especially in the neighbourhood of absorption bands, has been developed by Zeeman himself, by A . H . See also:

• BECQUEREL

Becquerel, by D . Macaluso and O . M . Corbino, and by other workers . The most fundamental experimental See also:

• CONFIRMATION (Lat. confirmatio, from confirmare, to establish, make firm)

confirmation that the theory of the aether has received on the optical side- in recent years has been the verification of Maxwell's proposition that radiation exerts mechanical force on a material system, on which it falls, which may be represented in all cases as the resultant of pressures operating along the rays, and of intensity equal at each point of free space to the density of radiant energy . A high vacuum is needed for the detection of the minute forces here concerned; but just in that case the indirect See also:

• RADIOMETER

radiometer-effect of the See also:

• HEATING

heating of the residual gas masks the effect .

P . N . Lebedew in 1900 succeeded, by operating on metallic vanes so thin that the exposed and averted faces were practically at the same temperature, in satisfactorily verifying the relation for metals; and very soon after, E . F . See also:

• NICHOLS, JOHN (1745–1826)

Nichols and G . F . See also:

• HULL
• HULL (in O.Eng. hulu, from helan, to cover, cf. Ger. Hiille, covering)
• HULL (officially KINGSTON-UPON-HULL)
• HULL, ISAAC (1775-1843)

Hull published accounts of an exact and extensive See also:

• RESEARCH (O. Fr. recerche, from recercher, re- and cercer, mod. chercher, to search; Late Lat. circare, to go round in a circle, to explore)

research, in which the principle had been fully and precisely confirmed as regardsboth transparent and opaque bodies . The experiment of J . H . Poynting may also be mentioned, in which the tangential component of the thrust of obliquely incident radiation is separately put in evidence, by the torsion produced in an arrangement which is not sensitive to the normal component or to the radiometer-pressure of the residual gas . (See RADIOMETER.) Next to these researches on the pressure of radiation, which, by forming the mechanical See also:

• LINK

link between radiation and matter, are fundamental for the thermodynamics of radiant energy, the most striking recent result has been the discovery of H . See also:

• RUBENS, PETER PAUL (1577-164o)

Rubens and E .

See also:

• HAGEN
• HAGEN, FRIEDRICH HEINRICH VON DER (178o-1856)

Hagen that for dark heat rays of only about ten times the wave-length of luminous radiation, the properties of metals are determined by their electric resistance alone, which then masks all resonance due to periods of free vibration of the molecules; and, moreover, that the resistance for such alternations is practically the same as the ohmic resistance for ordinary steady cur-rents . They found that the absorbing powers of the metals, and therefore, by the principle of exchanges, their radiating powers also, are proportional to the square roots of their electric conductivities . Maxwell had himself, at an early See also:

• STAGE (Fr. 6/age; from Lat. stare, to stand)

stage of his theory, tested the absorbing See also:

• POWER [WILLIAM GRATTAN] TYRONE (1797-1841)

power of See also:

• GOLD
• GOLD [symbol Au, atomic weight 195.7(H = 1),197.2(0 =16)]

gold-See also:

• LEAF (O. Eng. leaf, cf. Dutch loof, Ger. Laub, Swed. lof, &c.; possibly to be referred to the root seen in Gr. Ma-eta, to peel, strip)

leaf for light, and found that the effective conductivity for luminous vibrations must be very much greater than its steady ohmic value; it is, in fact, there a case of incipient conductivity, which is continually being undone on account of the rapid See also:

• ALTERNATION (from Lat. alternare, to do by turns)

alternation of force before it is fully established . That, however, complete See also:

• CONDUCTION, ELECTRIC

conduction should arrive with alternations only ten times slower than light was an unexpected and remarkable fact, which verifies the presumption that the process of conduction is one in which the dynamic activities of the molecules do not come into play . The corollary, that the electric resistance of a See also:

• METAL
• METAL (through Fr. from Lat. metallum, mine, quarry, adapted from Gr. µATaXAov, in the same sense, probably connected with ,ueraAAdv, to search after, explore, µeTa, after, aAAos, other)

metal can be determined in absolute units by experiments on the reflexion of heat-rays from its surface, is a striking illustration of the unification of the various branches of physical science, which has come in the train of the development of the theory of the aether . (See RADIATION.) Finally, reference should be made to the phenomena of radio-activity, whether excited by the electric See also:

• DISCHARGE (adapted from the O. Fr. discharge, modern decharge, from a med. Lat. discargare, to unload, dis- and earn care, to load, cf. " charge ")

discharge in vacuum tubes, foreshadowed in part by Sir Wm . See also:

• CROOKES, SIR WILLIAM (1832– )

Crookes and G . G . Stokes, and later by A . Schuster and others, but first fully developed with astonishing results including the experimental discovery of the free electron by J . J . See also:

• THOMSON, JAMES (1822-1892)
• THOMSON, JAMES (1834-1882)
• THOMSON, JAMES (r700-1748)
• THOMSON, JOHN (1778-184o)
• THOMSON, JOSEPH (1858-1895)
• THOMSON, SIR CHARLES WYVILLE (1830-1882)
• THOMSON, THOMAS (1773-1852)
• THOMSON, WILLIAM (1819-189o)

Thomson, or the correlated phenomena occurring spontaneously in radio-active bodies as discovered by H .

Becquerel and by M. and Mme See also:

• CURIE, PIERRE (1859-1906)

Curie, and investigated by them and by E . See also:

• RUTHERFORD, MARK
• RUTHERFORD, WILLIAM GUNION (1853–1907)

Rutherford and others . These results constitute a far-reaching development of the modern or electrodynamic theory of the aether, of which the issue can hardly yet be foreseen .