. This is so near to the values obtained in the laboratory that it seems permissible, in the absence of further precise data, to assume an atomic life of
, as a working hypothesis, for all atoms. The same value is unlikely to obtain for all atoms; in particular it may be expected to differ for atoms in different states of ionization. But here astrophysics must be entirely dependent on further laboratory work for the determination of a quantity that is of fundamental importance.
[TABLE IV]
| Atom | Life | Authority | Reference |
|---|---|---|---|
| Wien | An. d. Phys., 60, 597, 1919 | ||
| Ibid. | Ibid. | ||
| Ibid. | Ibid. | ||
| Ibid. | Ibid. | ||
| Dempster | Phys. Rev., 15, 138, 1920 | ||
| Wood | Proc. Roy. Soc., 99A, 362, 1921 | ||
| g | Franck and Grotian | Zeit. f. Phys., 4, 89, 1921 | |
| , | Mie | An. d. Phys., 66, 237, 1921 | |
| , | Wien | An. d. Phys., 66, 232, 1921 | |
| bands | Ibid. | Ibid. | |
| , | Ibid. | An. d. Phys., 73, 483, 1924 | |
| Ibid. | Ibid. | ||
| Ibid. | Ibid. | ||
| Ibid. | Ibid. | ||
| Turner | Phys. Rev., 23, 464, 1924 | ||
| Webb | Phys. Rev., 21, 464, 1923 |
RELATIVE PROBABILITIES OF ATOMIC STATES
The relative intensities of lines in a spectrum must depend fundamentally upon the relative tendencies of the atom to be in the corresponding states. To a subject which, like astrophysics, depends for its data largely upon the relative intensities of spectral lines, the theory of the relative probabilities of atomic states is of extreme importance. The question is obviously destined to become an important branch of spectrum theory. It has been discussed, from various aspects, by Füchtbauer and Hoffmann,[21] Einstein,[22] Füchtbauer,[23] Kramers,[24] Coster,[25] Fermi,[26] and Sommerfeld.[27] The comparison with observation has been made, up to the present, only for a few elements. The relative intensities of the fine-structure components of the Balmer series of hydrogen were examined by Sommerfeld,[28] and exhaustive work with the calcium spectrum has recently been carried out by Dorgelo.[29] The astrophysical application of the data bearing on relative intensities of lines in the spectrum of one and the same atom, while an essential branch of the subject, is a refinement which belongs to the future rather than to the present.
EFFECT ON THE SPECTRUM OF CONDITIONS AT THE SOURCE
(a) Temperature Class.—It is found experimentally that the relative intensities of the lines in the spectrum of a substance are altered when the temperature is changed. Some lines, notably the ultimate lines mentioned in a previous paragraph, predominate at low temperature. Other lines, which are weak under these conditions, become stronger if the temperature is raised, and lines which are the characteristic feature of the spectrum at the highest temperatures that can be attained in the furnace are often imperceptible at the outset. The effects are more conspicuous, and have been most widely studied, in the spectra of the metals, which are rich in lines and are amenable to furnace conditions. The results of such experiments, which are chiefly the work of A. S. King, are expressed by the assignment of a “temperature class,” ranging from I to V, to each line; Class I represents the lines characteristic of the lowest temperatures, and Class V denotes the lines that require the greatest stimulation.
The temperature class of a line is intimately connected with the amount of energy required to excite the line. It may, indeed, be used as a rough criterion of excitation potential, high temperature class indicating high excitation energy. The temperature class is therefore useful in assigning series relations to unclassified lines, and is of value to the astrophysicist chiefly in this capacity of a classification criterion. King’s work on silicon shows, for instance, that 3906 is of Class II, and is therefore not an ultimate line—a fact which has considerable significance in studying the astrophysical behavior of the line.