Chapter
1 II | are moving! This stifling heat, penetrating through the
2 III | The gas gave sufficient heat for the culinary apparatus,
3 III | will receive light and heat. It economizes the gas,
4 V | no air, there is no more heat than diffused light; and
5 V | And why not?”~“Because the heat and cold would be equalized
6 V | it would have undergone a heat 28,000 times greater than
7 V | that of summer. But this heat, which is sufficient to
8 V | of the aphelion and the heat of the perihelion.”~“At
9 V | produce both light and heat in the universe.”~They now
10 VI | Barbicane. “It is known now that heat is only a modification of
11 VI | warmed— that is to say, when heat is added to it—its particles
12 VI | every phenomenon of caloric. Heat is but the motion of atoms,
13 VI | It is transformed into heat, and the brake becomes hot.
14 VI | their heating, because this heat would be generated by the
15 VI | my motion is changed into heat.”~Barbicane could not help
16 VI | motion which is turned into heat. Consequently I affirm that,
17 VI | checked would have raised a heat great enough to turn it
18 VI | the fall would develop a heat equal to that produced by
19 VI | globe.”~“Good additional heat for the sun,” replied Michel
20 VI | suddenly stopped produces heat. And this theory allows
21 VI | allows us to infer that the heat of the solar disc is fed
22 VI | the sun ought to produce a heat equal to that of 4,000 masses
23 VI | And what is the solar heat?” asked Michel.~“It is equal
24 VI | forty-seven miles.”~“And that heat——”~“Would be able to boil
25 VI | four-tenths of the solar heat; besides, the quantity of
26 VI | besides, the quantity of heat intercepted by the earth
27 VI | the same length; and as heat is restored by radiation,
28 VII | the soup liquefied by the heat of the gas; nothing better
29 VII | taps, and regulated the heat of the gas by the pyrometer.
30 XIII | transition from cold to heat, the temperature falling
31 XIV | compensated by the insupportable heat which the light brings with
32 XIV | is evidently deprived of heat. But the invisible face
33 XIV | still more searched by the heat than the visible face. I
34 XIV | the same time light and heat from the sun, it is because
35 XIV | to 400,000 miles, and the heat which she receives must
36 XIV | and thus it was losing the heat stored up in its walls by
37 XIV | its walls by degrees. This heat was rapidly evaporating
38 XIV | also obliged to beg for heat. The projectile’s low temperature
39 XIV | light and saturated with heat, like the Indians of the
40 XIV | that of iron at a white heat; for whether the heat leaves
41 XIV | white heat; for whether the heat leaves our bodies briskly
42 XIV | lost by radiation all the heat which fifteen days of sun
43 XV | light, but not without its heat. Fortunately the caloric
44 XV | studies. It proved that all heat had not yet disappeared
45 XV | of this globe; and where heat exists, who can affirm that
46 XV | asteroid heated to a white heat. If thought was not destroyed
47 XVII | With its light it also sent heat, which soon pierced the
48 XVII | Nicholl, “these rays of heat are good. With what impatience
49 XVII | brilliant ether, light and heat, all life is contained in
50 XVIII| excessive cold to intense heat. Nature was thus preparing
51 XVIII| alternations of cold and heat, her days and nights of
52 XVIII| air, water, light, solar heat, and central heat, vegetation
53 XVIII| solar heat, and central heat, vegetation took possession
54 XVIII| nocturnal radiation. Light, like heat, can diffuse itself in the
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