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Encyclopedia Britannica - Main :: A10-ADA |
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ABSORPTION OF LIGHT . The term " absorption " (from Lat. absorbere) means literally " sucking up " or " swallowing," and thus a total incorporation in something, literally or figuratively ; it is technically used in animal physiology for the function
If a luminous body
aether
bright towards sunset. On the other hand, light can penetrate some distance into all substances, even the most opaque, the absorption being, however, extremely rapid in the latter case.The nature of the surface of a body
The question of absorption may be considered from either of two points of view. We may treat it as a superficial effect, especially in the case of bodies which are opaque enough or thick enough to prevent all transmission of light, and we may investigate how much is reflected at the surface and how much is absorbed; or, on the other hand, we may confine our attention to the light which enters the body and inquire into the relation between the decay of intensity and the depth of penetration. We shall take these two cases separately. Absorptive Power.When none of the radiations which fall on a body penetrates through its substance, then the ratio of the amount of radiation of a given wave-length which is absorbed to the total amount received is called the " absorptive power " of the body for that wave-length. Thus if the body absorbed half the incident radiation its absorptive power would be 2, and if it absorbed all the incident radiation its absorptive power would be r. A body which absorbs all radiations of all wave-lengths would be called a " perfectly black body." No such body actually exists, but such substances as lamp-black and platinum-black approximately fulfil the condition . The fraction of the incident radiation which is not absorbed by a body gives a measure of its reflecting power, with which we are not here concerned. Most bodies exhibit a selective action on light, that is to say, they readily absorb light of particular wave-lengths, light of other wave-lengths not being largely absorbed. All bodies when heated emit the same kind of radiations which they absorban important principle known as the principle of the equality of radiating and absorbing powers. Thus black sub-stances such as charcoal are very luminous when heated. A tile of white porcelain
bright on a darker ground. On the other hand, those substances which either are good reflectors orgood transmitters, are not so luminous at the same temperature; for instance, melted silver, which reflects well, is not so luminous as carbon at the same temperature, and common salt, which is very transparent for most kinds of radiation, when poured in a fused condition out of a bright red-hot crucible, looks almost like water, showing only a faint red glow for a moment or two. But all such bodies appear to lose their distinctive properties when heated in a vessel which nearly encloses them, for in that case those radiations which they do not emit are either transmitted through them from the walls of the vessel behind, or else reflected from their surface. This fact may be expressed by saying that the radiation within a heated enclosure is the same as that of a perfectly black body.Coefficient of Absorption, and Law of Absorption.The law which governs the rate of decay of light intensity in passing through any medium may be readily obtained. If Io represents the intensity of the light which enters the surface, I1 the intensity after passing through 1 centimetre, I2 the intensity after passing through 2 centimetres, and so on; then we should expect that whatever fraction of lo is absorbed in the first centimetre, the same fraction of I1 will be absorbed in the second. That is, if an amount jIo is absorbed in the first centimetre, jI1 is absorbed in the second, and so on. We have then I,=Io(1 9) I2 =11(1-i) = Io(1 J)2 Is = 12(1-i) = l0(1 7)3 and so on, so that if I is the intensity after passing through a thickness t in centimetres = le (1 J)` (1). We might call
formula
I = fpeke (2) where e is the base of Napierian logarithms, and k is a constant which is practically the same as j for bodies which do ndt absorb very rapidly. There is another coefficient of absorption (K) which occurs in Helmholtz's theory of dispersion (see DISPERSION). It is closely related to the coefficient k which we have just defined, the equation connecting the two being k=47rK/X,X being the wave-length of the incident light. The law of absorption expressed by the formula
If white light is allowed to fall on some coloured solutions, the transmitted light is of one colour when the thickness of the solution is small, and of quite another colour if the thickness is great
For the molecular theory of absorption, see SPECTROSCOPY. REFERENCES.A. Schuster's Theory of Optics (1904); P. K. L. Drude's Theory of Optics (Eng. trans., 1902); F. H. Wtillner's Lehrbuch der Experimentalphysik, Bd. iv. (1899). (J. R. C.) End of Article: ABSORPTION OF LIGHT If you wish, you can link directly to this article.
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