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ZODIACAL LIGHT
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ZODIACAL See also:LIGHT , a faint See also:illumination of the See also:sky, surrounding the See also:sun and elongated in the direction of the See also:ecliptic on each See also:side of the sun. It is lenticular in See also:form, brightest near the sun, and shades off by imperceptible gradations, generally becoming invisible at a distance of 9o° from the sun. Until a See also:recent See also:time it was never observed except in or near the See also:zodiac; hence its designation. Its breadth varies with the time and See also:place of observation, depending upon the position of the ecliptic with respect to the See also:horizon. In the tropics, where the ecliptic is nearly perpendicular to the horizon, it may be seen after the end of See also:twilight on every clear evening, and before ' See also:Schlegel, Ur. See also:Chin., p. 561; Pettigrew, Journ. See also:Arch. See also:Soc., viii. 21. 2 See also:Fox See also:Talbot, Trans. Soc. Bibl. Archaeol. iv. 260. ° Menard, La Mythologic dans l'See also:Art, p. 388. ' See also:Fowler, Archaeologia, xliv. 172. See also:Viollet-le-Duc, Dict. de l'Arch. Francaise, ix. 551; Le Gentil, Mein. de l'Acad., See also:Paris, 1785, p. 20. ° Fowler, Archaeologia, xliv. 150. 7 Ibid., p. 175. 8 Viollet-le-Duc, Dict. de l'Arch., ix. 551.
' See also: See also: The point of the wedge is quite indefinite, the extremely diffuse light gradually fading into invisibility at a height which may range from 5o° to 70° or even more, according to the keenness of the observer's See also:vision. The boundary everywhere is See also:ill defined so that no exact statement of the extent of the light can be made. The brightness is at its maximum along its central See also:line, called the See also:axis of the light. Along this axis the brightness continually increases as the sun is approached. Owing to the softness of the outline, it is not possible to See also:fix the position of the axis with precision; but, so far as observations have been made, it is found that it lies near the ecliptic, though deviating from it by a quite sensible amount. Having this position, the conditions of visibility will be best when the ecliptic, and therefore the axis of the light, are nearly perpendicular to the horizon, and, as the See also:angle between the ecliptic and horizon becomes acute, will deteriorate, slowly at first, more and more rapidly afterwards, owing to the increasing effect of atmospheric absorption. This effect is enhanced by the light being brighter as we approach the sun. More and more of the brighter regions of the light will then be near the horizon the more acute the angle. The result is that the light can be only indistinctly seen when the angle with the horizon is less than 450, unless in a region where the See also:atmosphere is unusually clear. From this statement of the conditions it will be seen that the tropical See also:zone is the most favourable for observation, and that the most favourable See also:hour of the See also:day at which the light can be seen must always be the earliest after sunset and the last before sunrise. Practically this is when twilight is first ended in the evening, and about to begin in the morning. At these See also:hours the angle of the ecliptic with the horizon varies with the See also:season. At the See also:close of evening twilight the angle is greatest about three See also:weeks before the vernal See also:equinox. The months of See also:February and See also: Previously to this, E. E. See also:Barnard had observed the same phenomenon at See also:Chicago. The only source of doubt as to the validity of the conclusion that this is really the zodiacal light arises from the possibility that, after the close of the ordinarily recognized twilight, there may be a faint illumination arising from the reflection of light by the very rare upper atmosphere, shown by the phenomena of meteors to extend some See also:hundred See also:miles or more above the earth's See also:surface. The problem of
separating a possible effect produced in this way from the zodiacal light proper may seem to offer some difficulty. But the few observations made show that, after See also:ordinary twilight has ended in the evening, the northern base of the zodiacal light extends more and more toward the north as the hours pass until, towards midnight, it merges into the light of the sky described by the two observers mentioned. Yet more conclusive are the observations of See also:Maxwell See also: He found it to be best seen during the months of See also:October, November and May.
Intimately connected with this band and with the zodiacal light is the See also:Gegenschein, or See also:counter-glow, a faint illumination of the sky in the region opposite the sun, which may generally be seen by a trained See also:eye when all the conditions are favourable. Unfavourable conditions are moonlight, nearness to the Milky Way, and See also:elevation of the light above the horizon (and there-fore a depression of the sun below the horizon) of less than 20°, and the presence in the region of any See also:bright planet. The Milky Way renders the See also:object invisible during the months of See also:June, See also:July, See also:December and January. Its light is so faint and diffuse that it is impossible to assign dimensions to it, except to say it covers a region of several degrees in extent. Barnard, the most successful observer, assigns diameters of 5° or even 1o° or more. From what has been said of its position it is evident that the zodiacal band, when seen across the sky, must include it. It may therefore be regarded as an intensification of this band, possibly produced by the increased intensity of the light when reflected nearly back toward the sun, and therefore toward the earth. From the description given of the zodiacal band and the Gegenschein, it is clear that these See also:objects should be best seen at the highest elevation, especially within the tropics. But the only well-authenticated observations we have of this See also:kind show anomalies which have never been cleared up. This is especially the See also:case with those of See also:Chaplain See also:George See also: One See also:anomaly of his observations is his description of the arch as sometimes so bright as to resemble the Milky Way, a See also:condition which would make it easily visible at ordinary altitudes. Another anomaly is that he never saw the Gegenschein, but describes the band as equally bright in all its parts, except near the horizon. We are there-fore forced to the conclusion that either he must have been a quite untrustworthy observer, or that there are anomalies in the phenomena which are yet to be explained. The latter possibility is also suggested by the curious fact that the visibility of the light does not seem to be proportionalto the transparency of the atmosphere. Barnard reports it as sometimes best seen when the sky is slightly milky, while during the observations already mentioned from the Rothorn the Gegenschein was scarcely, if at all, visible, though the conditions were exceptionally favourable. It has even been said that observers at great elevations have failed to see the zodiacal light; but it is scarcely credible that this failure could arise from any other cause than not knowing what it was or where to look for it. Moreover, it has been well seen by Hansky from the See also:observatory on the See also:summit of Mont See also:Blanc. In studying the causes of the phenomenon we must clearly distinguish between the apparent form as seen from the earth, and the real form of the lenticular-shaped cloud. The former refers to the earth, which is continually changing the point of view of the observer as he is carried around the sun, while the latter relates to the invariable position of the See also:matter which reflects the light. First in importance is the question of the position of the See also:principal See also:plane, passing through the sun, and containing the circumferential regions of the cloud. This plane must be near, but not coincident with, that of the ecliptic. It has therefore a See also:node and a certain inclination to the ecliptic. The determination of these elements requires that, at some point within the tropics where the atmosphere is clear, observations of the position of the axis of the light among the stars should be made from time to time through an entire See also:year. In view of the simplicity of the necessary appliances, and of the small amount of labour that would be required, we find a singular paucity of such observations. The most elaborate See also:attempt in the required direction was made by the See also:American chaplain, George Jones; during a voyage of the "See also:Mississippi " in the Pacific Ocean, in 1852-54. Owing to the varying latitude of the See also:ship, and the fact that the observer attempted to draw curves of equal brilliancy instead of the central line, the required conclusions cannot be See also:drawn with certainty from these observations. More recently Maxwell Hall in Jamaica made a satisfactory determination during the months from January to March, July and October, and carefully discussed his results. But the observations do not extend continuously throughout the year, and do not include a sufficient length of the central line on each evening to enable us to distinguish certainly the See also:heliocentric latitude of the central line, as distinct from its apparent See also:geocentric position. Yet his observations are of the first importance as showing the smallness of the deviation of the central line from the ecliptic. When smoothed out, the maximum latitude is less than 3°, which seems to preclude the coincidence of the central plane of the light with that of the sun's See also:equator. Hall also reaches the interesting conclusion that the plane in question seems to See also:lie near the invariable plane of the See also:solar See also:system, a result which might be expected if the light proceeded from a swarm of See also:independent meteoric particles moving around the sun. Chaplain Jones concluded, from his observations at Quito, that the central line of the arch made an angle of 3° 20' with the ecliptic, the ascending node being in Taurus, near See also:longitude 62°. This is about 40° from the ascending node of the invariable plane, so that there is a well-marked deviation of his results from those of Hall. Yet more divergent are the conclusions of See also:Francis J. Bayldon, R.N.R., who made many observations while on voyages through the Pacific Ocean between See also:Australia and the See also:west See also:coast of North See also:America. He places the ascending node at the vernal equinox, and assigns an inclination of 4°. He found that as the observer moved to the north or See also:south the axis of the light appeared to be displaced in the direction of the See also:motion, which is the opposite of the effect due to See also:parallax, but in the same sense as the effect of the greater atmospheric absorption of the light on the side nearest the horizon. He also describes the moon as adding to the zodiacal light during her first and last quarters, a result so difficult to explain that it needs See also:confirmation. It is noteworthy that he could see the zodiacal band across the entire sky during the whole of every very clear moonless See also:night in tropical regions. If we accept the general conclusion already drawn as to the t.,9t,t soft and d/f,t, Brighter "•. *Sun Region ,,.. f See also:colt and diffuse form and boundary of the region from which the light emanates, the next question is that of the matter sending it forth. The most plausible view is that we have to do with sunlight reflected from meteoric particles moving See also:round the sun within the region of the lens. The polariscope and the spectroscope are the only See also:instruments by the aid of which the nature of the matter can be inferred. The See also:evidence afforded by these instruments is not, however, altogether accordant. In 1867, See also:Angstrom, observing at See also:Upsala in March, obtained the bright auroral line (W.L. 5567), and concluded that in the zodiacal light there was the same material as is found in the See also:aurora and in the solar See also:corona, and probably through all space. Upsala, however, is a place where the auroral spectrum can often be observed in the sky, even when no aurora is visible, and it has generally been believed that what Angstrom really saw was an auroral and not a zodiacal spectrum. See also:Professor A. W. See also:Wright, of New Haven, also made careful cbservations leading to the conclusion that the spectrum differs from sunlight only in intensity. Some evidence has also been found by the same observer of polarization, showing that a considerable portion of the light must be reflected sunlight. The observations of Maxwell Hall also embraced some made with the spectroscope. He was unable to see any marked deviation of the spectrum from that of the sun; but it does not appear that either he or any other of the observers distinctly saw the dark lines of the solar spectrum. See also:Direct See also:proof that we have to do with reflected sunlight is therefore still incomplete. The question whether the Gegenschein can be accounted for by the reflection of light from the same matter as the zodiacal band is still unsettled. Taking the general consensus of the observations it would seem that its light must be so much brighter than that of the band as to imply the See also:action of some different cause. In this connexion may he mentioned the ingenious See also:suggestion of S. See also:Arrhenius, that the phenomenon is due to corpuscles sent off by the earth and repelled by the sun in the same way that they are sent off from a See also:comet and form its tail. in other words, the light may be an exceedingly tenuous cometary tail to the earth, visible only because seen through its very great length. The view that no cause intervenes additional to that producing the zodiacal band is strengthened, though not proved, by a theorem due to F. R. See also:Moulton of Chicago. He shows that, supposing the cloud of particles to move around the sun in nearly circular orbits immediately outside the earth, the perturbations by the earth in the motion of the particles will result in their retardation in that See also:part of the orbit nearest the earth, and therefore in their always being more numerous in a given space in this part of the orbit than in any other. This view certainly accounts for some intensification of the light, to which may be added the intensification produced by the vertical reflection of the sunlight. A new interest was given to the subject by the investigations of H. H. Seeliger, published in r906, who showed that the observed excess of motion of the See also:perihelion of See also:Mercury may be accounted for by the action of that portion of the matter reflecting the zodiacal light which lies nearest to the sun. Plausible though his result is, the subject still requires investigation. It seems not unlikely that the final conclusion will be that instead of the reflecting matter being composed of solid particles it is an exceedingly tenuous gaseous envelope surrounding the sun and revolving on an axis the mean position of which is between that of the sun's equator and that of the invariable plane of the solar system. Astron. Nachr., lxxiii. p. 19; See also:Jacob, See also:Memoirs R.A.S., See also:xxviii. p. 119; G. Jones, in See also:Gould, No. 84, Monthly Notices R.A.S., xvi. p. 18, Amer. Journ. of See also:Science, See also:Series II., vol. 24, p. 274, and in U.S. Exploring Expedition Narrative, vol. iii. (1856); See also:Humboldt, Monatsber, d. k. preuss. A_kad. d. Wiss. (July 1855), M. Not. R.A.S., xvi. p. 16; C. P. See also:Smyth, Trans. R.S.E., xx. p. 489 (1852), M. Not. R.A.S., xvii. p. 204, xxxii. p. 277; T. W. Backhouse, M. Not. R.A.S., See also:xxxvi. p. 1 and xli. p. 333; Tupman, M. Not. R.A.S., xxxii. p. 74; Liais, See also:Corn pies Rendus, lxiv. p. 262 (January 1872); 4. W. Wright, Amer. Jour. of Science, cvii. p. 451 and cviii. p. 39; Angstrom, Pogg. Annal., cxxxvii. p. 162; See also:Arthur Searle, Proc. Amer. Acad., xix. p. 146, vol. xi. p. 135, and See also:Annals of the Harvard Observatory, vol. xix. ; Trouvelot, Proc. Amer. Acad., xiii. p. 183 (1877); Barnard, Popular See also:Astronomy, vii. (1899) p. 171; Bayldon, Pub. See also:Ast. Soc. of the Pacific, vol. xii. (1900) ; Maxwell Hall, U.S. Monthly See also:Weather See also:Review (March 1906); Newcomb, Astrophysical Journal (1905) ii. (S. Additional information and CommentsThere are no comments yet for this article.
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