Nobel prize to N. Bohr awarded in 1922 "for his investigation of the structure of atoms, and of the radiation emanating from them''
BOHR 1918
Bohr, N.; On the Quantum Theory of Line-Spectra
D. KGL. Danske Vidensk. Selsk. Skrifter, naturvidensk. og mathem. Afd. 8. Raekke, {\bf IV.1, 1-3} 1 (1918);
Reprinted in Sources of Quantum Mechanics. Ed. by B. L. van der Waerden, North-Holland, Amsterdam, (1967) 95.
Niels Bohr Collected Works, V.3, The Correspondence Principle. (1918-1923), ed. by J. Rud Nielsen, general editor L. Rosenfeld, North Holland, (1976) 67.
Introduction
In an attempt to develop certain outlines of a theory of line-spectra based on a suitable application of the fundamental ideas introduced by Planck in his theory of temperature-radiation to the theory of the nucleus atom of Sir Ernest Rutherford, the writer has shown that it is possible in this way to obtain a simple interpretation or some of the main laws governing the line-spectra of the elements, and especially to obtain a deduction of the well known Balmer formula for the hydrogen spectrum.
The theory in the form given allowed of a detailed discussion only, in the case of periodic systems, and obviously was not able to account in detail for the characteristic difference between the hydrogen spectrum and the spectra of other elements, or for the characteristic effects on the hydrogen spectrum of external electric and magnetic fields. Recently, however, a way out of this difficulty has been opened by Sommerfeld who, by introducing a suitable generalization of the theory to a simple type
of non-periodic motions and by taking the small variation of the mass of the electron with its velocity into account, obtained an explanation of the fine-structure of the hydrogen lines which was found to be in brilliant conformity with the measurements. Already in his first paper on this subject, Sommerfeld pointed out that his theory evidently offered a clue to the interpretation of the more intricate structure of the spectra of other elements. Briefly afterwards Epstein and Schwarzschild, independent
of each other, by adapting Sommerfeld's ideas to the treatment of a more extended class of non-periodic systems obtained a detailed explanation of the characteristic effect of an electric field on the hydrogen spectrum discovered by Stark. Subsequently Sommerfeld himself and Debye have on the same lines indicated an interpretation of the effect of a magnetic field on the hydrogen spectrum which, although no complete explanation of the observations was obtained, undoubtedly represents an important
step towards a detailed understanding of this phenomenon. In spite of the great progress involved in these investigations many difficulties of fundamental nature remained unsolved, not only as regards the limited applicability of the methods used in calculating the frequencies of the spectrum of a given system, but especially as regards the question of the polarization and intensity of the emitted spectral lines. These difficulties are intimately connected with the radical departure from the
ordinary ideas of mechanics and electrodynamics involved in the main principles of the quantum theory, and with the fact that it has not been possible hitherto to replace these ideas by others forming an equally consistent and developed structure. Also in this respect, however, great progress has recently been obtained by the work of Einstein and Ehrenfest. On this state of the theory it might therefore be of interest to make an attempt to discuss the different applications from a uniform point
of view, and especially to consider the underlying assumptions in their relations to ordinary mechanics and electrodynamics. Such an attempt has been made in the present paper, and it will be shown that it seems possible to throw some light on the outstanding difficulties by trying to trace the analogy between the quantum theory and the ordinary theory of radiation as closely as possible. The paper is divided into four parts. Part I contains a brief discussion of the general principles
of the theory and deals with the application of the general theory to periodic systems of one degree of freedom and to the class of non-periodic systems referred to above. Part II contains a detailed discussion of the theory of the hydrogen spectrum in order to illustrate the general considerations. Part III contains a discussion of the questions arising in connection with the explanation of the spectra or other elements. Part IV contains a general discussion of the theory of the constitution
of atoms and molecules based on the application of the quantum theory to the nucleus atom. .
Related references More (earlier) information appears in N. Bohr, Phil. Mag. 26 (1913) 1;
N. Bohr, Phil. Mag. 26 (1913) 476;
N. Bohr, Phil. Mag. 26 (1913) 857;
N. Bohr, Phil. Mag. 27 (1914) 506;
N. Bohr, Phil. Mag. 29 (1915) 332;
N. Bohr, Phil. Mag. 30 (1915) 394;
See also M. Planck, Annalen der Physik. Leipzig 50 (1916) 385;
K. Schaposchnikov, Phys.Zeitschr. 15 (1914) 454;
M. Planck, Verh. d. D. Phys. Ges. 17 (1915) 407;
M. Planck, Verh. d. D. Phys. Ges. 17 (1915) 438;
W. Wilson, Phil. Mag. 31 (1916) 156;
W. Wilson, Phil. Mag. 29 (1915) 795;
E. C. Kemble, Phys. Rev. 8 (1916) 701;
Analyse data from A. Sommerfeld, Annalen der Physik. Leipzig 51 (1916) 1;
A. Sommerfeld, Ber. Akad. München (1915) 425;
K. Schwarzschild, Ber. Akad. Berlin (1916) 548;
P. Debye, Wolfskehl-Vor. Göttingen (1913);
P. Debye, Nachr. K. Ges. d. Wiss. Göttingen. (1916);
P. Debye, Phys.Zeitschr. 17 (1916) 507;
A. Einstein, Verh. d. D. Phys. Ges. 18 (1916);
P. Ehrenfest, Proc. Acad. Amsterdam 16 (1914) 591;
P. Ehrenfest, Phys.Zeitschr. 15 (1914) 657;
P. Ehrenfest, Phys.Zeitschr. 15 (1914) 660;
P. Ehrenfest, Annalen der Physik. Leipzig 51 (1916) 327;
P. Ehrenfest, Phil. Mag. 33 (1917) 500;
A. Einstein, Phys.Zeitschr. 18 (1917) 121;
J. M. Burgers, Versl. Akad. Amsterdam 25 (1917) 849;
J. M. Burgers, Versl. Akad. Amsterdam 25 (1917) 918;
J. M. Burgers, Versl. Akad. Amsterdam 25 (1917) 1055;
J. M. Burgers, Annalen der Physik. Leipzig 52 (1917) 195;
J. M. Burgers, Phil. Mag. 33 (1917) 514;
P. S. Epstein, Annalen der Physik. Leipzig 51 (1916) 168;
P. S. Epstein, Annalen der Physik. Leipzig 50 (1916) 489;
P. S. Epstein, Phys.Zeitschr. 17 (1916) 148;
A. Sommerfeld, Ber. Akad. München (1917) 83;
A. Sommerfeld, Ber. Akad. München (1916) 131;
A. Sommerfeld, Ber. Akad. München (1915) 459;
A. Sommerfeld, Phys.Zeitschr. 17 (1916) 491;
Record comments
Bohr's invention of correspondence principle.