to the vis viva of the absorbed rays."},{"_id":"360733","quote":"Let a body which satisfies these conditions be surrounded by an enclosure, having the same temperature [and kept constant], through which no heat rays can penetrate... The body sends out heat rays and is encountered by... heat rays... in part... from the enclosure, in part... thrown back... by reflection from it, absorbing a part of them. Its temperature must thus remain the same, unless heat is withdrawn from it or communicated to it as follows on the principle from which Carnot's law results. For this reason the vis viva of the rays, which it sends out in a certain time, must equal the vis viva of the rays which it absorbs in the same time."},{"_id":"360734","quote":"This investigation will be... simplified if we imagine the enclosure... composed... of bodies which, for infinitely small thickness, completely absorb all rays which fall upon them. I... call such bodies perfectly black, or more briefly, black."},{"_id":"360735","quote":"A ... must have the same as the medium... then there will be no reflection at its surface, and all incident rays... wholly absorbed."},{"_id":"360736","quote":"[R]adiation in empty space will be investigated..⇒ the [associated] black bodies must have a refracted index which differs infinitely little from 1."},{"_id":"360737","quote":"[I]t will be assumed that perfectly diathermanous bodies are conceivable, that is, such which will absorb none of the incident heat rays of whatever nature these may be, and finally, that a perfect mirror is conceivable, i.e., a body which reflects completely all heat rays."},{"_id":"360738","quote":"A perfect mirror, like every diathermanous body, can itself send out no rays; for if it did (confined in an enclosure of like temperature) it would warm this enclosure... and cool itself more and more."},{"_id":"360744","quote":"Under these conditions the following law holds : The ratio between the emissive and the absorptive power is the same for all bodies at the same temperature."},{"_id":"360745","quote":"This law will be proven, first, for the case where only black bodies are compared with each other, that is, those whose absorptic power = 1; i.e., it will be shown that the radiating power of all black bodies is the same at the same temperature."},{"_id":"360746","quote":"The proof of this special law is similar to that of the general law, but simpler; it will therefore facilitate the understanding of the latter. Moreover, conclusions which are drawn from the special law will be used in the proof of the common law."},{"_id":"360747","quote":"Another result of this law... When a space is surrounded by bodies of the same temperature, and no rays can penetrate through these bodies, every pencil in the interior of the space is so constituted, with respect to its quality and intensity, as if it proceeded from a perfectly black body of the same temperature, and is therefore independent of the nature and form of the bodies, and only determined by the temperature. The truth... is evident if we consider that a pencil of rays, which has the same form, but the reverse direction to that chosen, is completely absorbed by the infinite number of reflections which it successively experiences at the assumed bodies. In the interior of an opaque glowing hollow body of given temperature there is, consequently, always the same brightness whatever its nature may be in other respects."},{"_id":"360748","quote":"Why do you want to come into physics? All is done and understood."},{"_id":"360749","quote":"We owe to Kirchhoff..., the first rigorous proof of the celebrated law (...Kirchhoff's law) of the emission and absorption of light and heat, and the application of the same by both Kirchhoff and Bunsen to Spectrum Analysis. The radiation of solids and liquids and gases follows the law exactly when the conditions upon which he founded it are rigorously fulfilled, namely, the complete

Gustav Kirchhoff

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