- Autor(in)
- Referenz
-
10 Kostarev, A. I., Sh. eksp. teor. Fis. 11 (1941) 60;
11 Kozlenkov, A. I., Iswest. Akad. Nauk SSSR. Ser. fis. 25 (1961) 957.
12 Kozlenkov, A. I., Iswest. Akad. Nauk SSSR. Ser. fis. 27 (1963) 364.
13 Kozlenkov, A. I., Iswest. Akad. Nauk SSSR. Ser. fis. 28 (1964) 885
14 Arvikin, A. V., I. B. Borovskii, A. I. Kozlenkov, Iswest. Akad. Nauk. SSSR. Ser. fis. 31 (1967) 1016.
15 Izraileva, L. K., Dokl. Akad. Nauk SSSR 168 (1966) 777.
16 Izraileva, L. K., Dokl. Akad. Nauk SSSR 168 (1966) 1044.
17 Sawada, M., K. Tsutsumi u. A. Hayase, J. Phys. Soc. Japan 12 (1957) 628.
18 Azaroff, L. V., Rev. Mod. Phys. 35 (1963) 1012.
19 Brümmer, O., G. Dräger u. H. Baum, Z. Naturf. 18 a (1963) 1102.
1 Kronig, R. De, L., Z. Phys. 75 (1932) 191;
20 Brümmer, O., u. G. Dräger, Vorträge Intern. Symp. über Röntgenspektren und chemische Bindung, Leipzig 1966, S. 35;
21 Weber, W. M., Physica 27 (1962) 689;
22 Alexander, E., S. Feller, B. S. Fraenkel u. J. Perel, Nuovo Cim. 35 (1965) 311.
23 Weber, W. M., Physics Letters 25 A (1967) 590.
24 van Nordstrand, R. A., Non-Cristalline Solids, New York-London 1960, p. 168.
25 Brümmer, O., u. G. Dräger, Phys. status solidi 27 (1968) 513.
26 Sommerfeld, A., u. H. Bethe, Handbuch der Physik, Hrsg. Geiger-Scheel, Bd. 24, 2, Berlin 1933, S. 385.
27 Herman, F., Zusammenfassende Darstellung in Rev. Mod. Phys. 30 (1958) 102.
28 Hayasi, T., S. Okada, Sci. Repts. Tohoku Univ. 37 (1953) 331;
29 Veldcamp, J., Physica 2 (1935) 25;
2 Kurylenko, C., Bull. Soc. roy. Sci. Liége 5 (1946) 6;
30 Shiraiwa, T., T. Ishimiura u. M. Sawada, J. Phys. Soc. Japan 12 (1957) 788.
31 Nelson, W. F., J. Siegel u. R. W. Wagner, Phys. Rev. 127 (1962) 2025.
32 Sawada, M., u. a., Repts. Sci. Works Fak. Sci. Osaka Univ. 7 (1959) 1.
33 Kronig, R. De, L., Z. Phys. 75 (1932) 468.
34 Petersen, H., Z. Phys. 98 (1936) 569.
35 Loucks, T. L., Augmented Plane Wave Method, New York-Amsterdam 1967.
36 Synek, M., Phys. Rev. 133 A (1964) 961.
37 Pratt, G. W., Phys. Rev. 88 (1952) 1218.
38 Nemnonow, S. M., Sh. tech. Fis. 18 (1948) 239;
39 Albrecht, G., F. D. Dolnitz, K. Kleinstück u. M. Betzl, Phys. status solidi 3 (1963) K 249.
3 Hayasi, T., Sci. Repts. Tohoku Univ. 33 (1949) 123,
40 Siota, Y., Sci. Repts. Tohoku Univ. 42 (1958) 173.
41 Dräger, G., Dissertation, Halle 1967.
42 Batyrev, V. A., Iswest. Akad. Nauk SSSR. Ser. fis. 28 (1964) 497.
43 Nagasima, N., Sci. Repts. Tohoku Univ. 49 (1966) 49.
44 Shiraiwa, T., T. Ishimura u. M. Sawada, J. Phys. Soc. Japan 12 (1957) 788.
45 Kawaharada, H., Sci. Repts. Tohoku Univ. 45 (1961) 176.
46 Schmidt, W. W., Iswest. Akad. Nauk SSSR. Ser. fis. 27 (1963) 384.
47 Schmidt, W. W., Iswest. Akad. Nauk SSSR. Ser. fis. 25 (1961) 977.
48 Boster, T. A., u. J. E. Edwards, Phys. Rev. 170 (1968) 13.
49 Ferrell, R. A., Bull. Amer. Phys. Soc. 10 (1965) 1218;
4 Hayasi, T., Sci. Repts. Tohoku Univ. 44 (1960) 87.
5 Shiraiwa, T., T. Ishimura u. M. Sawada, J. Phys. Soc. Japan 13 (1958) 847.
6 Shiraiwa, T., J. Phys. Soc. Japan 15 (1960) 240.
7 Vishnoi, A. N., B. K. Agarwal, Proc. Phys. Soc. 89 (1966) 799.
8 Lytle, F. W., Proc. Int. Conf. on Physics of Non-crystalline Solids, Delft 1964 (Amsterdam 1965).
9 Chivate, P., P. S. Damle, N. V. Joshi u. C. Mande, J. Phys. C (Proc. Phys. Soc.) 1 (1968) 1171.
Brouers, F., Phys. status solidi 22 (1967) 213.
Brümmer, O., G. Suwalski, Naturwissenschaften 46 (1959) 223.
Dissertation, Paris 1939.
Handbuch d. Physik, Hrsg. Geiger-Scheel, Bd. 24, 2, Berlin 1933, S. 290.
Hayasi, T., Sci. Repts. Tohoku Univ. 49 (1965) 13.
Phys. status solidi 14 (1966) K 175.
Physica 30 (1964) 2219.
Sandström, A., Nova Acta Soc. Scient. Upsaliensis IV. Ser. 9. 11 (1935).
Sci. Repts. Tohoku Univ. 33 (1949) 183.
Sh. eksp. teor. Fis. 19 (1949) 413;
Sh. eksp. teor. Fis. 20 (1950) 811.
- Seitenbereich
-
0200 - 0217
- Zusammenfsg.
-
A critical review about the existing theories of extended fine structure of the X-ray absorption spectra of polycrystalline and amorphous solids is given. The fine structure of the K-absorption has been calculated according to the HAYASI, SHIRAIWA and KOZLENKOV theory using different potential models for each time one representative of the simple lattice types (Cr for the bcc, CrH for the hex and Ge for the diamond lattice). In some cases the crystal potential has been approximated by the superposition of the HARTREE-FOCK potentials of the isolated atoms according to their arrangement in the crystal. A comparison of the calculated fine structure curves between each other as well as with the experiment shows that the short-range order theories reproduce the shape of the fine structure curves qualitatively and the positions of the fine structure extrema partially quantitatively. However, to be able to reproduce the experimental fine structure in all details, these theories have to be improved especially by a more detailed consideration of the interactions of the photoelectron with the neighbouring atoms and the conduction electrons.
- Artikel-Typen
- Forschungsartikel