Advertisement

Superconducting Compounds

  • E. M. Savitskii
  • V. V. Baron
  • Yu. V. Efimov
  • M. I. Bychkova
  • L. F. Myzenkova
Chapter
Part of the The International Cryogenics Monograph Series book series (INCMS)

Abstract

At the present time there are more than a thousand known superconducting compounds with various crystal structures and a multitude of their alloys [1], The critical superconducting temperature of the various metallic compounds lies between 0.012 (SnTe) and 20.98°K [Nb0.79 (Al0.75Ge0.25)0.21] [1, 2, 2a,2b] Certain metallic compounds have the highest critical magnetic fields and critical superconducting temperatures of all known superconductors [3].

Keywords

Critical Temperature Lave Phase Sigma Phase Critical Magnetic Field High Critical Temperature 
These keywords were added by machine and not by the authors. This process is experimental and the keywords may be updated as the learning algorithm improves.

Preview

Unable to display preview. Download preview PDF.

Unable to display preview. Download preview PDF.

Literature Cited

  1. 1.
    B. W. Roberts, in: New Materials and Methods of Studying Metals and Alloys [Russian translation], Izd. Metallurgiya, Moscow (1966), p. 9.Google Scholar
  2. 2.
    R. A. Hein, Phys. Letts., 23: 435 (1966).Google Scholar
  3. 2a.
    B. T. Matthias, T. H. Geballe, L. D. Longinott, E.Corenzwit, G. W. Hull, R. H. Willens, and J. P. Maita, Science 156 (3775): 645 (1967).Google Scholar
  4. 2b.
    S. Foner, E. J. McNiff, B. T. Matthias, and E. Corenzwit, J. Appl. Phys., 40 (2): 2010 (1969).Google Scholar
  5. 2c.
    B. T. Matthias, Science, 168 (3927): 103 (1970).Google Scholar
  6. 3.
    E. M. Savitskii and V. V. Baron, Izv. Akad. Nauk SSSR, Metallurgiya i Gornoe Delo, No. 5, p. 3 (1963).Google Scholar
  7. 4.
    M. Laue, Ann. Phys., 6: 40 (1948).Google Scholar
  8. 5.
    J. Daunt, Progr. Low-Temperature Phys., 2: 194 (1957).Google Scholar
  9. 6.
    I. B. Borovskii, Collected Works of the Institute of Metallurgy, No. 15, Izd. AN SSSR, Moscow (1963), p. 79.Google Scholar
  10. 7.
    I. B. Borovskii, Collected Works of the Institute of Metallurgy, No. 6, Izd. AN SSSR, Moscow (1960), p. 41.Google Scholar
  11. 8.
    B. T. Matthias, T. H. Geballe, and V. B. Compton, Rev. Mod. Phys., 35 (1): 1 (1963).Google Scholar
  12. 9.
    B. T. Matthias, Progr. Low-Temperature Phys., 2: 138 (1957).Google Scholar
  13. 10.
    B. Boren, Arkiv Kemi, Mineral., Geol., No. 10, 11 (1933).Google Scholar
  14. 11.
    G. B. Bokii, Introduction to Crystal Chemistry, Izd. MGU (1954).Google Scholar
  15. 12.
    H. Hartmann, F. Ebert, and O. Bretschneider, Z. Anorg. und Allgemein. Chem., 198: 116 (1931).Google Scholar
  16. 13.
    A. J. Hegedus, T. Millner, J. Neugebauer, and K. Sasvari, Z. Anorg. und Allgemein. Chem., 281: 64 (1955).Google Scholar
  17. 14.
    T. Millner, A. J. Hegedus, K. Sasvari, and J. Neugebauer, Z. Anorg. und Allgemein. Chem., 289: 288 (1957).Google Scholar
  18. 15.
    J. Neugebauer, A. J. Hegedus, and T. Millner, Z. Anorg. und Allgemein. Chem., 293: 241 (1958).Google Scholar
  19. 16.
    G. Hagg and N. Schonberg, Acta Crystallogr., 7: 351 (1954).Google Scholar
  20. 17.
    F. Laves, Theory of Phases in Alloys [Russian translation], Metallurgizdat, Moscow (1961), p. 111.Google Scholar
  21. 18.
    L. Kihlborg, Acta Chem. Scand., 16: 2458 (1962).Google Scholar
  22. 19.
    N. Schonberg, Acta Chem. Scand., 8: 221 (1954).Google Scholar
  23. 20.
    H. von Philipsborn, Mischsysteme von Verbindungen des Cr3Si Typs under deren Polimorphia-Erscheinungen, Juris Verlag, Zurich (1964).Google Scholar
  24. 21.
    K. Schubert, Kristallstrukturen zweikomponentiger Phasen, Springer-Verlag, Berlin (1964).Google Scholar
  25. 22.
    P. Greenfield and P. A. Beck, Trans. AIME, 206: 265 (1956).Google Scholar
  26. 23.
    T. Miliner, Z. Anorg. und Allgemein. Chem., 292: 25 (1957).Google Scholar
  27. 24.
    S. Geller, Acta Crystallogr., 9: 885 (1956).Google Scholar
  28. 25.
    S. Geller, Acta Crystallogr., 10: 380 (1957).Google Scholar
  29. 26.
    S. Geller, Acta Crystallogr., 10: 678 (1957).Google Scholar
  30. 27.
    L. Pauling, Acta Crystallogr., 10: 374 (1957).Google Scholar
  31. 28.
    L. Pauling, Acta Crystallogr., 10: 685 (1957).Google Scholar
  32. 29.
    M. V. Nevitt, Trans. AIME, 212: 350 (1958).Google Scholar
  33. 30.
    H. J. Wallbaum, Z. Metallkunde, 31: 362 (1939).Google Scholar
  34. 31.
    H. J. Wallbaum, Naturwissenschaften, 32: 76 (1944).Google Scholar
  35. 32.
    D. H. Tempieton and C. H. Dauber, Acta Crystallogr., 3: 261 (1950).Google Scholar
  36. 33.
    E. Raub and P. Walter, Heraeus Festschrift, p. 124 (1951).Google Scholar
  37. 34.
    P. Duwez, Trans. AIME, 191: 564 (1951).Google Scholar
  38. 35.
    P. Duwez and C. B. Jordan, Acta Crystallogr., 5: 213 (1952).Google Scholar
  39. 36.
    W. Rostoker and A. Yamamoto, Trans. ASM, 46: 1136 (1954).Google Scholar
  40. 37.
    E. M. Savitskii, V. V. Baron, and Yu. V. Efimov, Dokl. Akad. Nauk SSSR, Tekh. Fiz., 171 (2): 84 (1967).Google Scholar
  41. 38.
    E. Teatum, K. Gschneider, and J. Waber, Los Alamos Scient. Lab. Rept., No. 23, p. 45 (1960).Google Scholar
  42. 39.
    J. B. Darby, D. J. Lam, L. J. Norton, and J. W. Downey, J. Less-Common Metals, 7 (4): 558 (1962).Google Scholar
  43. 40.
    J. B. Darby and S. T. Zegler, J. Phys. Chem. Solids, 23: 1825 (1962).Google Scholar
  44. 41.
    K. Schubert, T. R. Anantharaman, H. O. K. Ata, H. C. Meissner, M. Potzschke, W. Rossteutsc her, and E. Stolz, Naturwissenschaften, 47: 512 (1960).Google Scholar
  45. 42.
    R. M. Watersfrat and E. C. van Reuth, Trans. Metallurg. Soc. AIME, 236 (8): 1232 (1966).Google Scholar
  46. 43.
    D. H. Killpatrick, J. Phys. Chem. Solids, 25 (1): 1213 (1964).Google Scholar
  47. 44.
    New Scientist, 31:512, 556 (1966).Google Scholar
  48. 45.
    S. Rosen, J. Goebel, and J. A. Mullins, J. Less-Common Metals, 12 (6): 510 (1967).Google Scholar
  49. 46.
    H. Holleck, H. Nowotny, and F. Benesovsky, Monatsh. Chem., 94 (2): 473 (1963).Google Scholar
  50. 47.
    M. V. Nevitt, Electronic Structure and Alloy Chemistry of the Transition Elements, New York (1963), p. 101.Google Scholar
  51. 48.
    T. Millner, Zh. Neorg. Khim., 3 (4): 946 (1958).Google Scholar
  52. 49.
    D. H. Killpatrick, J. Metals, 16: 98 (1964).Google Scholar
  53. 50.
    M. D. Banus, T. B. Reed, and H. C. Gatos, J. Phys. Chem. Solids, 23: 971 (1962).Google Scholar
  54. 50a.
    H. L. Luo, E. Vielhaber, and E. Corenzwit, Z. Phys., 230 (5): 443 (1970).Google Scholar
  55. 50b.
    Yu. V. Efimov, in: Phase Diagrams of Metallic Systems, Izd. Nauka, Moscow (1968), p. 12.Google Scholar
  56. 50c.
    H. Holleck, H. Nowotny, and F. Benesovsky, Mh. Chem., 94 (2): 473 (1963).Google Scholar
  57. 50d.
    V. I. Surikov, M. K. Borzhitskaya, A. K. Shtolts, V. L. Zagryazhskii, and P. V. Gel’d, Fiz. Met. Metallov, 30 (6): 1167 (1970).Google Scholar
  58. 50e.
    T. Asada, T. Horiuchi, and M. Uchida, Japan J. Appl. Phys., 8 (7): 958 (1969).Google Scholar
  59. 50f.
    A. Müller, Z. Naturforsch., 24a (7): 1134 (1969).Google Scholar
  60. 51.
    Y. L. Yao, Trans. AIME 224: 1146 (1962).Google Scholar
  61. 52.
    Yu. V. Efimov, Izv. Akad. Nauk SSSR, Neorgan. Mat., 2 (4): 598 (1966).Google Scholar
  62. 53.
    I. I. Hauser and H. C. Theurerer, Phys. Rev., 129 (1): 103 (1963).Google Scholar
  63. 54.
    E. M. Savitskii, P. I. Kripyakevich, V. V. Baron, Yu. V. Efimov, Izv. Akad. Nauk SSSR, Neorgan. Mat., 3 (1): 45 (1967).Google Scholar
  64. 55.
    E. Raub and E. Roschel, Z. Metallkunde, 57 (6): 470 (1966).Google Scholar
  65. 56.
    V. B. Compton, Phys. Rev., 123: 1567 (1961).Google Scholar
  66. 57.
    G. F. Hardy and J. K. Hülm, Phys. Rev., 89: 884 (1953).Google Scholar
  67. 58.
    G. F. Hardy and J. K. Hülm, Phys. Rev., 93: 1004 (1954).Google Scholar
  68. 59.
    B. T. Matthias, Phys. Rev., 97: 74 (1955).Google Scholar
  69. 60.
    B. T. Matthias, E. A. Wood, E. Corenzwit, and V. B. Bala, J. Phys. Chem. Solids, 17 (1): 188 (1956).Google Scholar
  70. 61.
    S. T. Zegler, Phys. Rev., 137 (5A): 1437 (1965).Google Scholar
  71. 62.
    B. W. Roberts, Intermetallic Compounds (J. H. Westbrook, Ed.), John Wiley and Sons, New York-London-Sydney (1966), p. 581.Google Scholar
  72. 63.
    T. H. Courtney, G. W. Pearsall, and J. Wulff, J. Appl. Phys., 36 (10): 3256 (1965).Google Scholar
  73. 64.
    V. Sadagopan, H. C. Gatos, and B. C. Giessen, J. Phys. Chem. Solids. 26 (11): 1687 (1965).Google Scholar
  74. 64a.
    G. Meyer, Naturwissenschaften, 54 (18): 489 (1967).Google Scholar
  75. 64b.
    E. C. Reuth, R. M. Waterstrat, R. D. Blaugher, R. A. Hein, and J. E. Cox, Transactions of the Tenth International Conference on Low-Temperature Physics, Izd. VINITI, Moscow (1967), Vol. 2B, p. 137.Google Scholar
  76. 64c.
    B. W. Roberts, Superconductive Materials and Some of Their Properties, Note 408 (1967).Google Scholar
  77. 64d.
    H. L. Luo, E. Vielhaber, and E. Corenzwit, Z. Phys., 230: 443 (1970).Google Scholar
  78. 64e.
    E. M. Savitskii, V. V. Baron, and Yu. V. Efimov, Fiz. Met. Metallov., 25 (6): 1126 (1968).Google Scholar
  79. 65.
    B. W. Batterman and C. S. Barrett, Phys. Rev. Lett., 13: 390 (1964).Google Scholar
  80. 65a.
    S. A. Medvedov, K. V. Kiseleva, and V. V. Mikhailov, Fiz. Tverd. Tela, 10 (3): 746 (1968).Google Scholar
  81. 65b.
    H. W. King, F. H. Cocks, and J. T. A. Pollock, Phys. Lett., A26 (2): 77 (1967).Google Scholar
  82. 65c.
    L. J. Vieland, R. W. Cohen, and W. Rehwald, Phys. Rev. Lett., 26 (7): 373 (1971).Google Scholar
  83. 65d.
    E. Nembach, K. Tachikawa, and S. Takano, Phil. Mag., 21 (172): 869 (1970).Google Scholar
  84. 66.
    M. J. Goringe and U. Valdre, Phys. Rev. Lett., 14: 823 (1965).Google Scholar
  85. 67.
    J. E. Kunzler, J. P. Maita, E. J. Ryder, and H. J. Levinstein, Phys. Rev., 143: 390 (1966).Google Scholar
  86. 68.
    J. J. Hauser, Phys. Rev. Lett., 13: 470 (1964).Google Scholar
  87. 69.
    J. J. Hauser, Phys. Rev. Lett., 14: 422 (1965).Google Scholar
  88. 69a.
    J. C. F. Brook, Solid-State Communs., 7 (24): 1789 (1969).Google Scholar
  89. 70.
    P. W. Anderson and E. I. Blount, Phys. Rev. Lett., 14: 217 (1965).Google Scholar
  90. 71.
    A. P. Lev any uk and R. A. Suris, Uspekhi Fiz. Nauk, 91 (1): 113 (1967).Google Scholar
  91. 72.
    G. Otto and E. Saur, Z. Naturforsch., 20a (7): 975 (1965).Google Scholar
  92. 72a.
    L. J. Vieland, J. Phys. Chem. Solids, 31: 1449 (1970).Google Scholar
  93. 73.
    M. Weger, Rev. Mod. Phys., 36: 175 (1964).Google Scholar
  94. 74.
    A. M. Clogston, A. C. Gassard, V. Jaccarino, andY. Yafet, Rev. Mod. Phys., 36: 170 (1964).Google Scholar
  95. 75.
    H. J. Williams and R. C. Sherwood, Bull. Amer. Phys. Soc., 5: 430 (1960).Google Scholar
  96. 76.
    J. S. Shier and R. D. Taylor, Solid-State Communs., 5 (2): 147 (1967).Google Scholar
  97. 76a.
    H. Krebs, Z. Naturforsch., 23a (2): 332 (1968).Google Scholar
  98. 77.
    E. A. Wood, V. B. Compton, B. T. Matthias, and E. Corenzwit, Acta Crystallogr., 11: 604 (1958).Google Scholar
  99. 78.
    E. Corenzwit, J. Phys. Chem. Solids, 20 (9): 9–8 (1959).Google Scholar
  100. 79.
    K. Raetz and E. Z. Saur, Physik, 169: 315 (1962).Google Scholar
  101. 80.
    P. S. Swartz, Phys. Rev. Lett., 9: 448 (1962).Google Scholar
  102. 81.
    N. E. Alekseevskii, E. M. Savitskii, V. V. Baron, and Yu. V. Efimov, Dokl. Akad. Nauk SSSR, 145 (1): 82 (1962).Google Scholar
  103. 82.
    J. K. Hülm and R. D. Blaugher, Phys. Rev., 123 (5): 1569 (1961).Google Scholar
  104. 83.
    B. T. Matthias, J. Phys. Chem. Solids, 20 (10): 342 (1959).Google Scholar
  105. 84.
    R. M. Bozorth, A. J. Williams, and D. D. Davis, Phys. Rev. Lett., 5: 148 (1960).Google Scholar
  106. 85.
    J. E. Kunzler, E. Buchler, F. S. L. Hsu, and J. H. Wernick, Phys. Rev. Lett., 6: 89 (1961).Google Scholar
  107. 86.
    V. D. Arp, R. H. Kropschot, J. H. Wilson, W. F. Love, and R. Phelan, Phys. Rev. Lett., 6: 452 (1961).Google Scholar
  108. 87.
    J. O. Betterton, R. W. Boom, G. D. Kneip, and R. E. Worsham, Phys. Rev. Lett., 6: 532 (1961).Google Scholar
  109. 88.
    F. J. Morin, J. P. Maita, H. J. Williams, R. C. Sherwood, J. H. Wernick, and J. E. Kunzler, Phys. Rev. Lett., 8: 275 (1962).Google Scholar
  110. 88a.
    Yasukochi Ko, Akihama Ryozo, and Usui Nobumitsu, Japan J. Appl. Fiz., 9 (7): 845 (1970).Google Scholar
  111. 89.
    E. Saur and H. Wizgall, Les Champs Magnetiques Intenses, Colloque Internat., Grenoble (1966), p. 223.Google Scholar
  112. 89a.
    K. Hechler, E. Saur, and H. Wizgall, Z. Phys., 205 (4): 400 (1967).Google Scholar
  113. 90.
    D. B. Montgomery, Bull. Amer. Phys. Soc., 10 (3): 359 (1965).Google Scholar
  114. 91.
    H. R. Hart, J. Jacobs, C. L. Kolbe, and P. E. Lawrence, High Magnetic Fields, New York (1962), p. 584.Google Scholar
  115. 92.
    J. Wernick, in: Superconducting Materials, Izd. Mir, Moscow (1965), p. 64.Google Scholar
  116. 93.
    J. H. Wernick, F. J. Morin, F. S. L. Hsu, D. Dorsi, J. R. Maita, and J. E. Kunzler, High Magnetic Fields, Technol. Press, New York-London-Cambridge (Mass.) (1962), p. 609.Google Scholar
  117. 94.
    Chemical Week, 89(20):175 (1963).Google Scholar
  118. 95.
    C. B. Chandraseker, Appl. Phys. Lett., 1: 7 (1962).Google Scholar
  119. 96.
    D. B. Montgomery and H. Wizgall, Phys. Letts., 22 (1): 48 (1966).Google Scholar
  120. 97.
    J. J. Hauser, D. D. Bacon, and W. H. Haemmerle, Phys. Rev., 151 (1): 296 (1966).Google Scholar
  121. 98.
    J. J. Hauser, Transactions of the Tenth International Conference on Low-Temperature Physics, Izv. VINITI, Moscow (1967), p. 111.Google Scholar
  122. 99.
    H. J. Levinstein and J. E. Kunzler, Phys. Letts., 20 (6): 581 (1966).Google Scholar
  123. 100.
    Asayama Kunisuke and Yamagata Hidekim, J. Phys. ’Soc. Japan, 22(1):347 (1967). 100a. A. G. Shepelev, Uspekhi Fiz. Nauk, 96 (2): 217 (1968).Google Scholar
  124. 101.
    G. V. Samsonov, in: Metallography and Metallurgy of Superconductors, Izd. Nauka, Moscow (1965), p. 65.Google Scholar
  125. 102.
    O. I. Shulishova, Superconductivity of Carbides and Nitrides of Transition Metals and Their Solid Solutions with the NaCl Structure, Authors abstract of Dissertation, Inst. Metallofiz. Akad. Nauk Ukr. SSR, Kiev (1966).Google Scholar
  126. 103.
    O. I. Shulishova and I. A. Shcherbak, Izv. Akad. Nauk SSSR, Neorgan. Mat., 3 (8): 1495 (1967).Google Scholar
  127. 104.
    A. L. Giorgi and E. G. Szklarz, J. Less-Common Metals, 11 (6): 455 (1966).Google Scholar
  128. 104a.
    A; L. Giorgi, E. G. Szklartz, M. C. Krupka, T. C. Wallace, and N. H. Krikorian, J. Less-Common Metals, 14 (2): 247 (1968).Google Scholar
  129. 105.
    V. Sadagapan and H. C. Gatos, J. Phys. Chem. Solids, 27 (2): 235 (1966).Google Scholar
  130. 105a.
    A. L. Giorgi, E. G. Szklarz, M. C. Krupka, T. C. Wallace, and N. H. Krikorian, J. Less-Common Metals, 14 (2): 247 (1968).Google Scholar
  131. 106.
    G. Dorfman and I. K. Kikoin, Physics of Metals, GTTI (1934), p. 405.Google Scholar
  132. 107.
    H. J. Fink, A. C. Therson, E. Parker, V. F. Zackay, and L. Toth, Phys. Rev., 138 (4A): 1170 (1955).Google Scholar
  133. 108.
    N. Pessall, C. K. Jones, H. A. Johansen, and J. K. Hülm, Appi. Phys. Lett., 7: 38 (1965).Google Scholar
  134. 109.
    G. V. Samsonov and Ya. S. Umanskii, Hard Compounds of Refractory Metals, Metallurgizdat, Moscow (1957).Google Scholar
  135. 110.
    A. Giorgi, E. Szklarz, E. Storms, A. Bowman, and B. Matthias, Phys. Rev., 125: 837 (1962).Google Scholar
  136. 111.
    N. E. Alekseevskii, G. V. Samsonov, and O. I. Shulishova, Zh. Éksp. Teor. Fiz., 44: 1413 (1963).Google Scholar
  137. 112.
    J. S. Rajput and A. K. Gupta, J. Phys. Soc. Japan, 21 (10): 2075 (1966).Google Scholar
  138. 113.
    T. H. Geballe, B. T. Matthias, J. P. Remeika, A. M. Clogston, V. B. Compton, J. P. Maita, and H. J. Williams, Physics, 2 (6): 293 (1966).Google Scholar
  139. 114.
    T. Z. Jurrianse, Z. Kristallogr., 90: 322 (1935).Google Scholar
  140. 115.
    T. H. Geballe, Transactions of the Tenth International Conference on Low- Temperature Physics, Izd. VINITI, Moscow (1967), p. 196.Google Scholar
  141. 116.
    L. Gold, Phys. Stat. Solidi, 4: 261 (1964).Google Scholar
  142. 117.
    H. Nowotny, Freiberger Forschung., 123: 7 (1967).Google Scholar
  143. 117a.
    A. L. Giorgi et al., J. Less-Common Metals, 17 (1): 121 (1969).Google Scholar
  144. 117b.
    H. C. Krupka et al., J. Less-Common Metals, 17 (1): 91 (1969).Google Scholar
  145. 117c.
    M. C. Krupka and M. G. Bowman, Colloq. Int. CNRS, 188: 409 (1970).Google Scholar
  146. 117d.
    R. E. Intra et al., J. Less-Common Metals, 22: 149 (1970).Google Scholar
  147. 117e.
    M. C. Krupka et al., J. Less-Common Metals, 19 (2): 113 (1969).Google Scholar
  148. 117f.
    A. L. Giorgi et al., J. Less-Common Metals, 22 (1): 131 (1970).Google Scholar
  149. 118.
    G. Hagg, Z. Phys. Chem., 12: 33 (1931).Google Scholar
  150. 119.
    T. V. Massal’skii, in: Theory of Phases in Alloys, Metallurgizdat, Moscow (1961), p. 49.Google Scholar
  151. 120.
    H. Nowotny, W. Jeitschko, and F. Benesovsky, Planseeber. Pulvermetallurgie, 12: 31 (1964).Google Scholar
  152. 121.
    L. E. Toth, W. Jeitschko, and C. M. Yen, J. Less-Common Metals, 10 (1): 29 (1966).Google Scholar
  153. 121a.
    N. B. Hannag, T. H. Geballe, B. T. Matthias, K. Andres, P. Schmidt, and D. MacNair, Phys. Rev. Lett., 14: 225 (1965).Google Scholar
  154. 121b.
    B. T. Matthias, Trans, of the Tenth Internat. Conf. on Low-Temperature Physics [Russian translation], Izd. VINITI, Moscow (1967), Vol. 2B, p. 77.Google Scholar
  155. 122.
    Ch. J. Raub, V. B. Compton, T. H. Geballe, B. T. Matthias, J. P. Maita, and G. W. Hull, J. Phys. Chem. Solids, 26 (12): 2051 (1965).Google Scholar
  156. 123.
    R. D. Blaugher, J. K. Hülm, and P. N. Yocom, J. Phys. Chem. Solids, 26 (12): 2037 (1965).Google Scholar
  157. 124.
    G. L. Guthrie and R. L. Palmer, Phys. Rev., 141 (1): 346 (1966).Google Scholar
  158. 125.
    M. H. Maaren and G. M. Schaeffer, Phys. Letts., 20 (2): 131 (1966).Google Scholar
  159. 126.
    V. P. Zhuze, S. S. Shalyt, V. A. Noskin, and V. M. Sergeeva, ZhETF, Pis. Red., 3 (5): 217 (1966).Google Scholar
  160. 127.
    R. M. Bozorth, F. Holtzberg, and S. Methfessel, Phys. Rev. Lett., 14: 952 (1965).Google Scholar
  161. 128.
    T. A. Bither, C. T. Prewitt, J. L. Gillson, P. E. Bierstedt, R. B. Flippen, and H. S. Young, Solid State Communs., 4 (10): 533 (1966).Google Scholar
  162. 129.
    P. E. Zeiden and F. Goltsberg, Transactions of the Tenth International Conference on Low-Temperature Physics [Russian translation], Izd. VINITI, Moscow (1967).Google Scholar
  163. 130.
    J. Bardeen, L. N. Cooper, and J. R. Schrieffer, Phys. Rev., 108: 1175 (1957).Google Scholar
  164. 131.
    B. Reiss and H. Wagini, Z. Naturforsch., 21a (ll): 2008 (1966).Google Scholar
  165. 132.
    B. T. Matthias and J. K. Hülm, Phys. Rev., 87: 799 (1952).Google Scholar
  166. 133.
    M. D. Banus, L. B. Farrell, and A. J. Stauss, Solid State Res. Lincoln Lab. MIT, 27(4):33 (1964/1965).Google Scholar
  167. 134.
    B. B. Goodman and S. G. Marcucci, Suomalais. Tiedeakat. Tiomituks, Sar. AVI, 210: 86 (1966).Google Scholar
  168. 135.
    L. Finegold, Phys. Rev. Lett., 13: 233 (1964).Google Scholar
  169. 136.
    S. Geller, A. Jagaraman, and G. W. Hull, Appl. Phys. Lett., 4: 35 (1964).Google Scholar
  170. 137.
    S. Geller and G. W. Hull, Phys. Rev. Lett., 13: 127 (1964).Google Scholar
  171. 138.
    J. K. Hülm, C. K. Jones, R. Mazelsky, R. C. Miller, R. A. Hein, and J. W. Gibson, Low-Temperature Physics, LT-9, Part A, Plenum Press, New York (1965), p. 600.Google Scholar
  172. 139.
    K. Andres, N. A. Kuebler, and M. B. Robin, J. Phys. Chem. Solids, 27 (11–12): 1747 (1966).Google Scholar
  173. 140.
    H. P. R. Frederikes, J. E. Schooley, W. R. Thurber, E. Pfeiffer, and W. R. Hosier, Phys. Rev. Lett., 16 (13): 579 (1966).Google Scholar
  174. 141.
    E. Ambler, J. H. Colwell, W. R. Hosier, and J. E. Schooley, Phys. Rev., 148 (1): 280 (1966).Google Scholar
  175. 142.
    P. E. Bierstedt, T. A. Bither, and F. J. Darnell, Solid State Communs., 4 (1): 25 (1966).Google Scholar
  176. 143.
    A. R. Sweedler, J. K. Hülm, B. T. Matthias, and T. H. Geballe, Phys. Letts., 19 (2): 82 (1965).Google Scholar
  177. 143a.
    M. Robin, K. Andres, T. H. Geballe, N. A. Kuebler, and D. B. McWhan, Phys. Rev. Lett., 17: 917 (1966).Google Scholar
  178. 143b.
    N. M. Builova and V. B. Sandomirskii, Uspekhi Fiz. Nauk, 97 (1): 119 (1969).Google Scholar
  179. 144.
    C. W. Tucker, Science, 112: 448 (1950).Google Scholar
  180. 145.
    G. J. Dickins, A. M. Douglas, and W. H. Taylor, J. Iron Steel Inst., 167: 27 (1951).Google Scholar
  181. 146.
    J. Thewliss, Acta Crystallogr., No. 7, p. 323 (1954).Google Scholar
  182. 147.
    P. Duwez, in: Theory of Phases in Alloys [Russian translation], Metallurgizdat, Moscow (1961), p. 225.Google Scholar
  183. 148.
    D. S. Bloom and N. J. Grant, Trans. AIME, 197: 88 (1953).Google Scholar
  184. 149.
    E. Bucher, F. Heiniger, and J. Muller, Phys. Kondensierten Materie, 2 (3): 210 (1964).Google Scholar
  185. 150.
    P. Greenfield and P. A. Beck, Trans. AIME, 200: 253 (1954).Google Scholar
  186. 151.
    A. J. Lena, Metal Progr., 66: 122 (1954).Google Scholar
  187. 152.
    R. D. Blaugher and J. K. Hülm, J. Phys. Chem. Solids, 19 (1–2): 134 (1961).Google Scholar
  188. 153.
    S. H. Autler, J. K. Hülm, and R. S. Kemper, Phys. Rev., 140A: 1117 (1965).Google Scholar
  189. 154.
    V. Sadagopan and H. C. Gatos, Phys. Stat. Solidi, 13 (2): 423 (1966).Google Scholar
  190. 154a.
    E. M. Savitskii and O. Kh. Khamidov, Izv. Akad. Nauk SSSR, Metally, 5: 51 (1969).Google Scholar
  191. 155.
    F. Laves and H. Witte, Metallwirtschaft, 14: 645 (1935).Google Scholar
  192. 156.
    R. L. Berry and G. V. Raynor, Acta Crystallogr., 6: 178 (1953).Google Scholar
  193. 157.
    H. Witte, Zur Struktur und Materia des Festkörper, Springer Verlag, Berlin (1952).Google Scholar
  194. 158.
    H. Klee and H. Witte, Z. Phys. Chem., 202: 352 (1954).Google Scholar
  195. 159.
    H. Wuhe, Z. Phys., 197 (3): 276 (1966).Google Scholar
  196. 160.
    R. L. Falge and R. A. Hein, Phys. Rev., 148 (2): 940 (1966).Google Scholar
  197. 161.
    D. C. Hamilton, Ch. I. Raub, and B. T. Matthias, J. Phys. Chem. Solids, 26 (3): 665 (1965).Google Scholar
  198. 161a.
    Rapp Osten, J. Less-Common Metals, 21(1):27 (1970). 161b. B. Hillenbrand and M. Wilhelm, Phys. Lett., A33 (2): 61 (1970).Google Scholar
  199. 162.
    A. Scharri, Phys. Letts., 20 (6): 619 (1966).Google Scholar
  200. 163.
    J. S. Kasper, Acta Metallurgica, 2: 456 (1954).Google Scholar
  201. 164.
    D. K. Das, S. P. Rideout, and P. A. Beck, Trans. AIME, 194: 1071 (1952).Google Scholar
  202. 165.
    N. E. Alekseevskii and N. N. Mikhailov, Zh. £ksp. Teor. Fiz., 43 (6): 2110 (1962).Google Scholar
  203. 166.
    E. M. Savitskii, M. A. Tylkina, and K. B. Povarova, Rhenium Alloys, Izd. Nauka, Moscow (1965), pp. 158, 245.Google Scholar
  204. 167.
    O. Kh. Khamidov, Physicochemical Interaction of Rhenium with Transition Metals of Groups III-VI in the Periodic System, Author’s abstract of Dissertation, IMET, Moscow (1967).Google Scholar
  205. 167a.
    T. Claeson, Phys. Stat. Solidi, 25 (2): K95 (1968).Google Scholar
  206. 168.
    E. M. Savitskii, V. V. Baron, and Yu. V. Efimov, Izv. Akad. Nauk SSSR, Neorgan. Mat., 12: 2170 (1967).Google Scholar
  207. 169.
    J. Muller, E. Bucher, R. Burton, F. Heiniger, and G. Zambelli, Transactions of the Tenth International Conference on Low -Temperature Physics [Russian translation], VINITI, Moscow (1967), p. 211.Google Scholar
  208. 170.
    E. Bucher, F. Heiniger, J. Muller, and P. Spitzli, Phys. Letts., 19 (4): 263 (1965).Google Scholar
  209. 171.
    V. M. Pan, V. V. Pet’kov, and O. G. Kulik, in: Metallography, Physical Chemistry, and Metal Physics of Superconductors, Izd. Nauka, Moscow (1967), p. 161.Google Scholar
  210. 172.
    E. M. Savitskii, in: Metallography and Metal Physics of Superconductors, Izd. Nauka, Moscow (1965), p. 3.Google Scholar
  211. 173.
    E. M. Savitskii, Vestnik Akad. Nauk SSSR, No. 3 (1966).Google Scholar
  212. 174.
    Yu. V. Efimov, V. V. Baron, E. M. Savitskii, and E. I. Gladyshevskii, in: Metallography and Metal Physics of Superconductors, Izd. Nauka, Moscow (1965), p. 91.Google Scholar
  213. 175.
    Yu. V. Efimov, V. V. Baron, and E. M. Savitskii, in: Physical Chemistry, Metallography, and Metal Physics of Superconducting Materials, Izd. Nauka, Moscow (1968), p. 108.Google Scholar
  214. 176.
    J-76. N. E. Alekseevskii, N. V. Ageev, and V. F. Shamrai, Izv. Akad. Nauk SSSR, Neorgan. Mat., 2 (12): 2150 (1966).Google Scholar
  215. 177.
    R. Hagner, Z. Phys., 177 (1): 10 (1964).Google Scholar
  216. 177a.
    E. Ronald, J. Appl. Phys., 37 (13): 4880 (1966).Google Scholar
  217. 178.
    N. R. Alekseevskii, I. I. Kornilov, N. M. Matveeva, and Yu. A. Maksimov, Dokl. Akad. Nauk SSSR, 173 (3): 553 (1967).Google Scholar
  218. 179.
    M. Hansen and K. Anderko, Constitution of Binary Alloys [Russian translation], Metallurgizdat, Moscow (1962).Google Scholar
  219. 180.
    H. Nowotny, R. Maschenschalk, H. Kieffer, and F. Benesovsky, Monatsch. Chem., 85: 241 (1954).Google Scholar
  220. 181.
    E. M. Savitskii, V. V. Baron, Yu. V. Efimov, and E. I. Gladyshevskii, Zh. Neorgan. Khim., 9 (7): 1655 (1964).Google Scholar
  221. 182.
    W. B. Pearson, Handbook of Lattice Spacings and Structures of Metals and Alloys, Pergamon Press, London (1958), p. 1.Google Scholar
  222. 183.
    E. M. Savitskii, V. V. Baron, Yu. V. Efimov, and E. I. Gladyshevskii, Trudy Inst. Met., 12, 166 (1962).Google Scholar
  223. 184.
    E. Bucher, F. Laves, J. Muller, and H. von Philipsborn, Phys. Letts., 8: 27 (1964).Google Scholar
  224. 185.
    C. D. Cody, I. J. Hanak, G. T. McConville, and F. D. Rosi, Rev. RCA, 25 (3): 338 (1964).Google Scholar
  225. 185a.
    R. Flukiger, Phys. Lett., A29 (7): 407 (1969).Google Scholar
  226. 186.
    E. A. Wood and B. T. Matthias, Acta Crystallogr., 9: 534 (1956).Google Scholar
  227. 187.
    S. T. Zegler and J. W. Downey, Trans. AIME 227: 1407 (1963).Google Scholar
  228. 188.
    R. A. Oriani, Acta Metallurgica, 2: 343 (1954).Google Scholar
  229. 189.
    E. M. Savitskii, V. V. Baron, Yu. V. Efimov, V. R. Karasik, T. V. Vylegzhanina, and E. I. Gladyshevskii, Zh. Neorgan. Khim., 9 (8): 2045 (1964).Google Scholar
  230. 190.
    E. M. Savitskii, V. V. Baron, Yu. V. Efimov, and E. I. Gladyshevskii, Izv. Akad. Nauk SSSR, Neorgan. Mat., 1 (2): 208 (1965).Google Scholar
  231. 191.
    E. M. Savitskii, V. V. Baron, and Yu. V. Efimov, Izv. Akad. Nauk SSSR, Neorgan. Mat., 2 (8): 1444 (1966).Google Scholar
  232. 191a.
    C. Susz, R. Flukiger, and J. Muller, Helv. Phys. Acta, 43 (5): 476 (1970).Google Scholar
  233. 192.
    T. B. Reed, H. C. Gatos, W.-J. La Fleur, and G. T. Goddy, Metallurgy of Advanced Electronic Materials, 19: 71 (1963).Google Scholar
  234. 192a.
    R. Blaugher, N. Ressall, and A. Patterson, J. Appl. Phys., 40 (5): 2000 (1969).Google Scholar
  235. 193.
    H. Holleck, F. Benesovsky, and H. Nowotny, Monatsh. Chem., 93: 996 (1962).Google Scholar
  236. 194.
    F. Rothwarf, J. A. Schwitz, C. C. Dickson, R. C. Thiel, H. Boiler, and E. Parth, Phys. Rev., 152 (1): 341 (1966).Google Scholar
  237. 195.
    Sci. News, 91 (20): 475 (1967).Google Scholar
  238. 196.
    R. Hagner and E. Saur, Naturwissenschaften, 49: 444 (1962).Google Scholar
  239. 197.
    F. Rothwarf, C. C. Dickson, E. Parthe, and H. Boiler, Bull. Amer. Phys. Soc., 7: 322 (1962).Google Scholar
  240. 197a.
    H. Otto, Z. Phys., 215 (4): 323 (1968).Google Scholar
  241. 197b.
    E. M. Savitskii, V. V. Baron, M. I. Bychkova, S. D. Gindina, Yu. V. Efimov, N. D. Kozlova, L. F. Martynova, B. P. Mikhailov, L. F. Myzenkova, and V. A. Frolov, Summaries of Contributions to the Sixteenth All-Union Conference on Low-Temperature Physics, Leningrad (1970), p. 198.Google Scholar
  242. 198.
    E. M. Savitskii, New Metallic Alloys, Izd. Znanie, Moscow (1967).Google Scholar
  243. 198a.
    E. M. Savitskii and G. S. Burkhanov, Metallography of Refractory Metals and Alloys, Izd. Nauka, Moscow (1967).Google Scholar
  244. 199.
    J. H. N. Van Vucht, H. A. C. M. Brunning, H. C. Donkersloot, and A. H. Gomes de Mesquito, Philips Res. Rpts., 19 (5): 407 (1964).Google Scholar
  245. 200.
    H. J. Levinstein, J. H. Wernick, and C. D. Capio, J. Phys. Chem. Solids, 26 (7): 1111 (1965).Google Scholar
  246. 201.
    E. A. Linton, Superconductivity [Russian translation], Izd. Mir, Moscow (1964).Google Scholar
  247. 202.
    H. von Philipsbom and F. Laves, Acta Crystallogr., 17: 213 (1964).Google Scholar
  248. 203.
    A. Kjekshus, F. Gronvold, and J. Thorbjornsen, Acta Chem. Scand., 16: 1493 (1962).Google Scholar
  249. 204.
    H. von Philipsborn, Tafeln zum Bestimmen der Minerale nach äusseren Kennzeichen, Stuttgart (1953).Google Scholar
  250. 204a.
    P. R. Sahm, Phys. Lett., A26 (10): 459 (1968).Google Scholar
  251. 204b.
    J. B. Vetrano, G. L. Guthrie, and H. E. Kissinger, Phys. Lett., A26 (l): 45 (1967).Google Scholar
  252. 205.
    M. W. Williams, K. M. Ralls, and M. R. Pickus, J. Phys. Chem. Solids, 28 (2): 333 (1967).Google Scholar
  253. 206.
    G. K. Gaulé, J. T. Breslin, R. L. Ross, J. R. Pastore, and J. R. Shappirio, Low Temperature Physics, LT-9, Part A, Plenum Press, New York (1965), p. 612. Press, New York (1965), p. 612.Google Scholar
  254. 207.
    B. T. Matthias and J. K. Hülm, Phys. Rev., 92: 874 (1953).Google Scholar
  255. 208.
    F. J. Darnell, P. E. Bierstedt, W. O. Forshey, and R. K. Waring, Phys. Rev., 140 (5A): 1581 (1965).Google Scholar
  256. 209.
    L. E. Toth, C. M. Yen, L. G. Rosner, and D. E. Anderson, J. Phys. Chem. Solids, 27 (11–12): 1815 (1966).Google Scholar
  257. 210.
    N. E. Alekseevskii, G. V. Samsonov, and O. I. Shulishova, Izv. Akad. Nauk SSSR, Neorgan. Mat., 3 (1): 61 (1967).Google Scholar
  258. 211.
    H. Bilz, Z. Phys., 153: 338 (1958).Google Scholar
  259. 212.
    G. Lautz and D. Schneider, Z. Naturforsch., 172A: 54 (1962).Google Scholar
  260. 213.
    R. M. Bozorth, B. T. Matthias, and D. D. Davis, Transactions of the Seventh International Conference on Low-Temperature Physics (Canada 1960), Univ. Toronto Press (1961), p. 385.Google Scholar
  261. 214.
    B. T. Matthias, V. B. Compton, and E. Corenzwit, J. Phys. Chem. Solids, 19: 130 (1961).Google Scholar
  262. 214a.
    N. E. Alekseevskii, L. N. Guseva, and N. M. Matveeva, Dokl. Akad. Nauk SSSR, 178 (5): 1047 (1968).Google Scholar
  263. 214b.
    M. B. Maple, Phys. Lett., A26 (10): 513 (1968).Google Scholar
  264. 215.
    N. N. Zhuravlev, G. S. Zhdanov, and E. M. Smimova, Fiz. Met. Metallov., 13 (1): 62 (1962).Google Scholar
  265. 216.
    G. G. Hanak and G. R. Gody, High Magnetic Fields, New York (1961), p. 592.Google Scholar
  266. 217.
    R. Eustrom, F. Courtney, and G. Pears all, Metallurgy of Advanced Electronic Materials, Vol. 19, New York (1963), p. 60.Google Scholar
  267. 218.
    W. A. Rachinger, J. Austral. Inst. Metals, 1 (4): 231 (1966).Google Scholar
  268. 219.
    H. G. Jansen and E. J. Saur, Transactions of the Seventh International Conference on Low-Temperature Physics (Canada 1960), Univ. Toronto Press (1961), p. 185.Google Scholar
  269. 220.
    J. J. Hanak, G. D. Cody, J. L. Cooper, and M. Rayl, Transactions of the Eighth International Conference on Low-Temperature Physics (London, 1962), Washington (1963), p. 353.Google Scholar
  270. 221.
    V. N. Svechnikov, V. M. Pan, and Yu. I. Beletskii, in: Metallography, Physical Chemistry, and Metal Physics of Superconductors, Izd. Nauka, Moscow (1967), p. 100.Google Scholar
  271. 222.
    W. Kunz and E. Saur, Z. Phys., 189 (4): 401 (1966).Google Scholar
  272. 223.
    M. Tanenbaum and W. V. Wright (eds.), Superconductors, New York (1962), p. 143.Google Scholar
  273. 224.
    W. S. Kogan, A. I. Krivko, B. G. Lazarev, L. S. Lazareva, A. A. Matsakova, and O. N. Ovcharenko, in: Metallography and Metal Physics of Superconductors, Izd. Nauka, Moscow (1965), p. 76.Google Scholar
  274. 225.
    R. Enstrom, T. Courtney, G. Pearsall, and J. Wulff, Metallurgy of Advanced Electronic Materials, Vol. 19, Interscience, New York (1962), p. 121.Google Scholar
  275. 226.
    R. E. Enstrom, N. Y. Pearsall, G. W. Pearsall, and J. Wulff, J. Metals, 16: 97 (1964).Google Scholar
  276. 227.
    J. J. Hanak, G. D. Cody, P. R. Aron, and H. C. Hitchcock, High Magnetic Fields, Technol. Press, New York-London-Cambridge (Mass.) (1962), p. 592.Google Scholar
  277. 228.
    T. H. Courtney, G. W. Pearsall, and J. Wulff, Trans. Metallurg. Soc. of AIME, 233 (1): 212 (1965).Google Scholar
  278. 229.
    E. Buchler, J. H. Wernick, K. M. Olsen, F. S. L. Hsu, and J. E. Kunzler, Metallurgy of Advanced Electronic Materials, Vol. 19, Interscience, New York (1963), p. 105.Google Scholar
  279. 230.
    N. M. Matveeva and T. O. Malakhova, in Metallography, Physical Chemistry, and Metal Physics of Superconductors, Izd. Nauka, Moscow (1968), p. 141.Google Scholar
  280. 231.
    B. G. Lazarev, L. S. Lazareva, A. A. Matsakova, and O. N. Ovcharenko, in Metallography and Metal Physics of Superconductors, Izd. Nauka, Moscow (1965), p. 89.Google Scholar
  281. 232.
    V. R. Karasik, Physics and Techniques of Strong Magnetic Fields, Izd. Nauka, Moscow (1964).Google Scholar
  282. 232a.
    Ko Yasukochi, Ryozo Akihama, and Nobumitsu Usui, Japan J. Appl. Phys. 9 (7): 845 (1970).Google Scholar
  283. 233.
    L. S. Kan, B. G. Lazarev, and V. I. Makarov, Éksp. Teor. Fiz., 40: 457 (1961).Google Scholar
  284. 234.
    B. G. Lazarev, L. S. Lazareva, O. N. Ovcharenko, and A. A. Matsakova, Zh. Éksp. Teor. Fiz., 43: 2309 (1962).Google Scholar
  285. 235.
    E. S. Itskevich, M. A. Il’ina, and V. A. Sukhoparov, Zh. Éksp. Teor. Fiz., 45: 1378 (1963).Google Scholar
  286. 235a.
    J. P. McEvey, Colloq. Int. CNRS, No. 188, p. 101 (1970).Google Scholar
  287. 235b.
    H. Neubauer, Z. Phys., 226: 211 (1969).Google Scholar
  288. 236.
    M. Weger, B. G. Silbernagel, and E. S. Greiner, Phys. Rev. Lett., 13: 521 (1964).Google Scholar
  289. 237.
    L. R. Testardi, T. B. Bateman, W. A. Reed, and V. G. Chirba, Phys. Rev. Lett., 15: 250 (1965).Google Scholar
  290. 238.
    K. R. Kieler and D. D. Hanak, Transactions of the Tenth International Conference on Low-Temperature Physics [Russian translation], Izd. VINITI, Moscow (1967), p. 391.Google Scholar
  291. 239.
    J. R. Patel and B. W. Batterman, Phys. Rev., 148 (2): 662 (1966).Google Scholar
  292. 240.
    C. B. Muller and E. L. Saur, Rev. Mod. Phys., 36: 103 (1964).Google Scholar
  293. 241.
    J. R. Patel and B. W. Batterman, J. Appi. Phys., 37(9):3347 (1966). 241a. T. F. Smith, Phys. Rev. Lett., 25 (21): 1483 (1971).Google Scholar
  294. 242.
    D. B. McWhan, V. B. Compton, M. S. Silverman, and J. R. Soulen, J. Less-Common Metals, 12 (1): 75 (1967).Google Scholar
  295. 243.
    D. B. McWhan and M. Marezio, J. Chem. Phys., 45 (7): 2508 (1966).Google Scholar
  296. 244.
    S. Minomura, B. Okai, Y. Onoda, and S. Tanuma, Phys. Letts., 23 (11): 641 (1966).Google Scholar
  297. 245.
    J. P. McEvoy, R. F. Decell, and R. L. Novak, Appi. Phys. Lett., 4: 43 (1964).Google Scholar
  298. 246.
    P. S. Swartz, H. R. Hart, and R. R. Fleischer, Appi. Phys. Letts., 4: 71 (1964).Google Scholar
  299. 247.
    E. L. Keller, H. T. Coffey, A. Patterson, and S. H. Autler, Trans. Amer. Nucl. Soc., 9 (1): 55 (1966).Google Scholar
  300. 248.
    V. F. Shamrai, Superconductivity of the Beta Phase in the Nb—Sn—Al—Ge System, Authors abstract of Dissertation, A. A. Baikov Inst. Metallurgy (1966).Google Scholar
  301. 249.
    L. F. Mattheis, Phys. Rev., 138: A112 (1965).Google Scholar
  302. 249a.
    S. A. Nemnonov, t. Z. Kurmaev, and V. P. Belash, Phys. Stat. Sol., 39: 39 (1970).Google Scholar
  303. 250.
    S. A. Nemnonov and E. Z. Kurmaev, Phys. Stat. Solidi, 24: K43 (1967).Google Scholar
  304. 250a.
    S. A. Nemnonov, t. Z. Kurmaev, V. I. Minin, V. G. Zyryanov, and I. A. Brytov, Fiz. Met. Metallov., 30 (3): 659 (1970).Google Scholar
  305. 251.
    C. B. Muller and E. J. Saur, Rev. Mod. Phys., 36: 103 (1964).Google Scholar
  306. 252.
    E. M. Savitskii, Yu. V. Devingtal, and V. B. Gribulya, Dokl. Akad. Nauk SSSR, 183 (5): 11 (1968).Google Scholar
  307. 253.
    E. M. Savitskii and V. B. Gribulya, Izv. Akad. Nauk SSSR, Neorgan. Mat., 7 (7): 1097 (1971).Google Scholar
  308. 254.
    E. M. Savitskii, Yu. V. Devingtal’, and V. B. Gribulya, Dokl. Akad. Nauk SSSR, 185: 561 (1969).Google Scholar
  309. 255.
    E. M. Savitskii, Yu. V. Devingtal’, and V. B. Gribulya, in: Problems of Superconducting Materials, Izd. Nauka, Moscow (1970), p. 39.Google Scholar

Copyright information

© Plenum Press, New York 1973

Authors and Affiliations

  • E. M. Savitskii
    • 1
  • V. V. Baron
    • 1
  • Yu. V. Efimov
    • 1
  • M. I. Bychkova
    • 1
  • L. F. Myzenkova
    • 1
  1. 1.A. A. Baikov Institute of MetallurgyAcademy of Sciences of the USSRMoscowUSSR

Personalised recommendations