Page:Popular Science Monthly Volume 14.djvu/620

1. Des étoiles très-brillantes où nous ne voyons que l'hydrogène en quantité énorme, et le magnésium;

2. Des étoiles plus froides, comma notre soleil, où nous trouvons:

	Hydrogène ${\displaystyle +}$ Magnésium ${\displaystyle +}$ Sodium
	Hydrogène ${\displaystyle +}$ Magnesium ${\displaystyle +}$ Sodium ${\displaystyle +}$ Calcium ${\displaystyle +}$ Fer, . . .;

dans ces étoiles, pas de métalloïdes;

3. Des étoiles plus froides encore, dans lesquelles tous les éléments métalliques sont associés, où leurs lignes ne sont plus visibles, et où nous n'avons que les spectres des métalloïdes et des composés.

4. Plus une étoile est âgée, plus l'hydrogène libte disparaît; sur la terre, nous ne trouvons plus d'hydrogène en liberté.

Il me semble que ces faits sont les preuves de plusieurs idées émises par vous. J'ai pensé que nous pouvions imaginer une "dissociation céleste," qui continue le travail de nos fourneaux, et que le métalloïdes sont des composés qui sont dissociés par la température solaire, pendant que les éléments métalliques monatomiques, dont les poids atomiques sont les moindres, sont précisément ceux qui resistent même à la température des étoiles les plus chaudes.

Before I proceed further I should state that, while observations of the sun have since shown that calcium should be introduced between hydrogen and magnesium for that luminary, Dr. Huggins's photographs have demonstrated the same fact for the stars, so that in the present state of our knowledge, independent of all hypotheses, the facts may be represented as follows:

Hottest Stars		${\displaystyle \scriptstyle {\left.{\begin{matrix}\ \\\\\ \ \end{matrix}}\right\}\,}}$	Lines[1] of		${\displaystyle \scriptstyle {\left\{{\begin{matrix}\ \\\\\ \ \end{matrix}}\right.}}$	H ${\displaystyle +}$ Ca ${\displaystyle +}$ Mg
Sun						H ${\displaystyle +}$ Ca ${\displaystyle +}$ Mg ${\displaystyle +}$ Na ${\displaystyle +}$ Fe
Cooler Stars						— — Mg ${\displaystyle +}$ Na ${\displaystyle +}$ Fe ${\displaystyle +}$ Bi ${\displaystyle +}$ Hg
Coolest . Fluted bands of  — — — — — —							${\displaystyle \scriptstyle {\left\{{\begin{matrix}\ \\\\\ \ \end{matrix}}\right.}}$	Fluted Spectra of Metals and Metalloids.

I have no hesitation in stating my opinion that in this line of facts we have the most important outcome of solar work during the last ten years; and if there were none others in support of them, the conclusion would still stare us in the face that the running down of temperature in a mass of matter which is eventually to form a star is accompanied by a gradually increasing complexity of chemical forms.

This, then, is the result of one branch of the inquiry, which has consisted in a careful chronicling of the spectroscopic phenomena presented to our study by the various stars.

Experimentalists have observed the spectrum of hydrogen, of calcium, etc., in their laboratories, and have compared the bright lines visible in the spectra with the dark ones in the stars, and on this ground they have announced the discovery of calcium in the sun or of hydrogen in Sirius.

1. Symbols are used here to save space. H ${\displaystyle -}$ Hydrogen, Ca ${\displaystyle =}$ Calcium, Mg ${\displaystyle =}$ Magnesium, Na ${\displaystyle =}$ Sodium, Fe ${\displaystyle =}$ Iron, Bi ${\displaystyle =}$ Bismuth, Hg ${\displaystyle =}$ Mercury.